Chemical
Science

REVIEW
Peptide cages: b
aYusuf Hamied Department of Chemistry

Cambridge, UK. E-mail: jrn34@cam.ac.uk
bChemical and Pharmaceutical Sciences D

Trieste, Italy. E-mail: smarchesan@units.it
cINSTM, University of Trieste, 34127 Trieste

Cite this: DOI: 10.1039/d5sc08607h

Received 5th November 2025
Accepted 17th February 2026

DOI: 10.1039/d5sc08607h

rsc.li/chemical-science

© 2026 The Author(s). Published b
ioinspired supramolecular
architectures for next-generation applications

Simone Adorinni, a Houyang Xu,a Jonathan R. Nitschke*a

and Silvia Marchesan *bc

This review examines the design and synthesis of peptide-based supramolecular cages, highlighting the

versatility and functional diversity achievable by incorporating small peptides as structural components.

Inspired by natural supramolecular architectures, synthetic peptide cages offer unique advantages,

including tunable chirality, structural predictability, biocompatibility, and ease of functionalisation. The

discussion focuses on two principal strategies. The first involves cages in which peptides constitute the

primary structural framework, with cage geometry dictated either by intrinsic backbone conformations

or by externally imposed directional interactions such as metal coordination. The second covers hybrid

systems in which peptides play a functional rather than framework-determining role and are integrated

with rigid aromatic or synthetic scaffolds that define the overall architecture. These approaches enable

precise control over cage geometry, cavity characteristics, and dynamic behaviour, facilitating

applications in biosensing, targeted drug delivery, molecular separation, and environmental remediation.

By bridging principles from natural assembly and synthetic supramolecular chemistry, peptide cages

represent a powerful platform for developing next-generation functional materials.
1. Introduction

Proteins have evolved to form complex topological structures,
spontaneously tying molecular knots,1 weaving molecular
chainmail,2 and creating interlocked architectures of remark-
able complexity.3 They fold and self-assemble into intricate
shapes beyond simple globular forms, including catenanes and
interlocked assemblies.4 The identication of over 2000 topo-
logically entangled proteins5 highlights nature's frequent use of
complex molecular architectures, such as the trefoil knots
found in methyltransferases and the molecular chainmail
structure in HK97 bacteriophage capsids, where cyclic proteins
interlock to form catenanes, providing mechanical strength.2,6

Additionally, living systems extensively employ protein
cages, hollow architectures assembled from multiple protein
subunits into dened geometric congurations. Ferritin exem-
plies such cages, spontaneously assembling 24 identical
subunits into octahedral structures to sequester and regulate
potentially harmful metal ions.7,8 Similarly, bacterial micro-
compartments create polyhedral shells from hexagonal protein
tiles, spatially isolating reactive metabolic intermediates.9,10

Vault particles further illustrate biological complexity, forming
, University of Cambridge, CB2 1EW

epartment, University of Trieste, 34127

, Italy

y the Royal Society of Chemistry
large barrel-shaped structures from 78 protein copies that
selectively facilitate molecular transport across cellular bound-
aries.11,12 Collectively, these examples underscore how nature
assembles proteins into capsular structures to solve biological
problems related to molecular organisation and compartmen-
talisation, beyond the capability of individual protein chains.

Mimicking the biological functions of proteins through
more accessible molecular scaffolds has become an appealing
strategy due to the synthetic challenges associated with
producing full-length proteins. Small peptides, ranging from 2–
20 amino acids in length, represent excellent minimalistic
motifs for protein-like functions, owing to their numerous
advantages, including structural predictability, tunability and
synthetic feasibility.13 Being essentially homologous to proteins,
peptides inherit their non-toxic nature and chirality, making
them promising for biological or medical applications.14

Rationally designed peptide sequences enable precise control
over supramolecular assemblies by leveraging specic amino
acid combinations to adopt dened conformations or
secondary structures, including a-helices,15–17 b-sheets,18–20 and
coiled coils.21–23 This control applies fundamental supramolec-
ular chemistry principles through collective non-covalent
interactions, including hydrogen bonding, hydrophobic
effects and electrostatic forces, producing adaptive materials
that respond dynamically to environmental stimuli while
preserving structural integrity.14,24 Recent computational
advances andmachine learningmethodologies further enhance
the rational engineering of peptide-based systems, enabling
Chem. Sci.

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Fig. 1 The central circular panel illustrates a generic short peptide (2–
20 amino acids) as a blue tubular strand, capable of adopting diverse
secondary structures that include an a-helix and a b-sheet, which can
serve as a modular subunit for cage design. Two distinct strategies for
its incorporation are highlighted. On the left, cages with peptides as
backbones are constructed from peptide-based building blocks,
where self-assembly is directed by the conformational preferences
and interaction motifs encoded in the sequence. On the right, cages
with peptides as auxiliary units integrate short peptides with rigid
aromatic scaffolds, where the peptide contributes additional recog-
nition or functional features outside the core. All structures shown are
schematic representations.

Chemical Science Review
targeted assembly into nanostructures with predetermined
functionalities.25

At the same time, the inherent ability of proteins to form
complex capsular structures, coupled with their intrinsic cavi-
ties and structural adaptability, has inspired the design of
synthetic counterparts.26,27 Supramolecular cages are discrete,
three-dimensional assemblies formed through cooperative self-
assembly of complementary building blocks, featuring well-
dened internal cavities ideal for selective guest encapsula-
tion.28 Their design requires careful selection of building blocks
to promote precise assembly of discrete structures. Notable
examples demonstrate how biological assemblies, such as viral
capsids and ferritin cages, have directly inspired synthetic cage
design.29,30 Conformationally adaptable metal–organic cages
exemplify this biomimetic approach by dynamically optimising
their cavity shapes and volumes, mirroring the induced-t
binding mechanisms observed in proteins.31–33 These
synthetic assemblies replicate key biological principles while
offering controllable mechanical properties and multi-
compartmental guest-binding functionalities.30,34

Synthetic cages have demonstrated sophisticated capabil-
ities in biomolecular encapsulation. Self-assembled porphyrin-
faced cubic cages can sequester and protect long peptides from
proteolytic degradation.35 Similarly, giant PdII coordination
cages have successfully encapsulated proteins such as ubiq-
uitin, highlighting the synthetic potential to achieve controlled
biomolecule protection and functional modulation.36,37

Despite these advances in purely articial supramolecular
cage systems, new applications call for enhanced features,
including adaptability and stereochemical control. Increased
interest is now focused on utilising peptides as structural
elements for cage construction rather than merely as guest
molecules.38 The integration of cage structural design principles
with peptide organisation strategies enables researchers to
develop peptide cages exhibiting biocompatibility, biodegrad-
ability, intrinsic chirality, programmable recognition motifs,
and structural exibility.39 Such exibility confers adaptive
cavity behaviour, enabling dynamic responses to guest mole-
cules. The modularity inherent in peptide sequences further
facilitates systematic property adjustments through amino acid
modications.

This review focuses on supramolecular cages incorporating
peptides, with particular emphasis on peptide involvement in
the framework, backbone conformation, and bonding strategy,
which together exert structural control within the assembly.
Two principal design approaches are discussed (Fig. 1). The rst
approach, which is the focus of Section 2, centres on peptides
that incorporate key structural motifs or predominantly
constitute the framework of resulting structures, enabling the
backbone to either adopt dened conformations reminiscent of
protein secondary structure elements, or to remain conforma-
tionally exible as other driving forces provide directional
control. In these systems, the peptide backbone functions as an
integral architectural component of the cage, actively contrib-
uting to geometry, connectivity, and internal organisation.
Metal coordination is frequently employed as a strong and
directional interaction to stabilise and reinforce peptide-
Chem. Sci.
encoded geometries, rather than to impose cage structure
independently.

The second approach, described in Section 3, encompasses
systems mostly based on amino acids or short peptides, which
play a framework-decorating role and do not encode cage
geometry through backbone conformation. These peptides are
linked to rigid, typically aromatic scaffolds that dene the
overall cage architecture, playing primarily a functional role.

These systems exploit the chemical diversity and reactivity of
amino acid side chains to introduce recognition elements,
responsiveness, or tuneable chemical properties. As a result,
this class includes cages assembled through a range of strate-
gies, including metal ligand coordination, covalent and
dynamic covalent chemistry, and hydrogen bonding
interactions.

We recognise that overlap exists between the concepts of
cages incorporating ‘framework’ and ‘peripheral’ peptides.
Several cases are highlighted below where peptides simulta-
neously contribute to both structural organisation and func-
tional modulation.

Finally, Section 4 discusses the practical applications of
peptide based supramolecular cages, illustrating how these
distinct design strategies translate into performance in bi-
osensing, drug delivery, molecular separation, and environ-
mental remediation, while also highlighting current limitations
related to stability, scalability, and functional robustness.

2. Cages with peptides as backbones

A key advantage of employing peptides as building blocks for
self-assembly is their versatility and, to some extent, predict-
ability of folding. To overcome the entropic penalty inherent in
© 2026 The Author(s). Published by the Royal Society of Chemistry



Review Chemical Science
self-assembly, conformational preorganisation of ligands is
oen necessary.40,41 Consequently, rigid ligands have been
employed in studies of supramolecular assemblies.41 When low-
symmetry and structurally complex architectures are required
to bind more intricate target molecules, peptide-based back-
bones in supramolecular assemblies have caught the attention
of researchers. The use of peptides effectively employs protein-
like folding characteristics for the formation of small-molecule
assemblies. A judicious choice of amino acids, according to the
specic ranges of f and j torsion angles, enables the rational
design of geometries between the building blocks, such as
angles between chelating sites,42 and the controlled twisting of
the peptide strands forming the ligands. Amino acidic side
chains, both natural and unnatural, also provide additional
connectivity options. These side chains may provide sites for
molecular recognition,43 form secondary structures integral to
the assembled architecture,44 or directly engage in metal
coordination.45–49 In this section, we discuss representative
examples highlighting the use of peptides in constructing self-
assembled capsular structures.
Fig. 2 Peptide-backbone cages and macrocycles from peptides fol-
ded under the direction of metal coordination. (a) The subcomponent
self-assembly of o-vanillin (1), dipeptide ligand 2 and NiII generates
[NiII6L4]

4+ helicate 3 when n-BuOH is used as solvent. Changing the
solvent to EtOH orMeOH generates [NiII9L6]

6+ triangular capsule 4 and
[NiII18L12]

12+ octahedron 5, respectively. The structures of these cages
are shown. (b) Visual comparison of the coordination modes between
NiII and the ligand generated from imine condensation of 1 and 2 in
structures 3–5; note the increase of the opening angle between each
pair of ligands. (c) The subcomponent self-assembly of 1, dipeptide
ligand 6 and NiII generates [NiII45L30] helicate 7 when a mixed MeOH/
H2O solvent is used. The chirality of 7 depends on the handedness of
the Val-residue of 6. The structure of L-7 is visualised. (d) Visualisation
of coordination between NiII and the imine ligand formed by 1 and 6 in
cage L-7. (e) The self-assembly of amine ligand 8 and NiII generates
[NiII4L4]

8+ macrocycle 9. (f) Visualisation of coordination between NiII

and 8 in macrocycle 9. All structures are single-crystal X-ray diffraction
(SCXRD) structures. Colour codes: C = light blue (basic side chains),
green (non-polar side chains) or grey (other moieties), N = blue, O =

red, Ni = green.
2.1 Metal-directed peptide cages

When peptides are too short or exible to adopt dened
conformations, non-covalent forces can guide their structural
organisation. This process is facilitated by adoption of poten-
tially preferred geometries50 and solvophobic effects51 that
further restrict conformations. A notable case is the [NiII3]–
dipeptide cluster motif developed by Kong et al.51,52 Imine
capping with o-vanillin (1) of the b-Ala–L-His (2) N-terminus
gives a multidentate ligand: the aldehyde residue, imine
nitrogen and b-Ala amide bind two NiII ions, while the C-
terminal carboxylate and His side chain can potentially
chelate two additional metals (Fig. 2a). Three NiII centres then
assemble two ligand strands into a head-to-head N-terminus
junction holding a NiII3 cluster together, and the cluster's
open coordination sites engage the C-termini of neighbouring
strands, forming a polyhedral network. Kong and co-workers
discovered that self-assembly in the presence of base in n-
butanol, ethanol, andmethanol led to the formation of [Ni6L4]

4+

helicate 3, [Ni9L6]
6+ triangle 4, and [Ni18L12]

12+ octahedron 5,
respectively, with increasing opening angles between edges and
increasing 4 (−172.36° to −131.90°) and j (−173.65° to
−158.20°) torsion angles of the peptides (Fig. 2a–d). This range
of linkage geometries demonstrates that the peptides retain
a degree of exibility even aer coordination to the NiII3 cluster.
Increased exibility, combined with solvophobic effects, can
thus lead to large capsular structures. Condensation of o-
vanillin and another dipeptide, Gly–L-Leu (L-6) or Gly–D-Leu (D-
6) results in a more compact, exible and hydrophobic NiII3
cluster motif, which self-assembles into a large [Ni45L30] cage 7,
as shown in Fig. 2c.51 The greater exibility of Gly allowed the
coordinated peptide to adopt multiple conformations within
the same structure (Fig. 2d), with 4 ranging from −87.3° to
−136.56° and J from −175.94° to 84.80°. The isobutyl side
chain of Leu tends to point inward due to solvophobic effects in
the polar MeOH/H2O solvent used for self-assembly, and side
© 2026 The Author(s). Published by the Royal Society of Chemistry
chain bulk was identied as a driving force for the formation of
the large capsular structure.

Vázquez et al. reported peptide-based helicate systems where
designed sequences encode structural information, with metal
coordination reinforcing the resulting geometry. Oligocationic
peptide ligands containing six bipyridine residues fold into
chiral three-stranded helicates in the presence of FeII or CoII

ions. Heterochiral b-turn sequences with L-Arg–L-Pro–D-Arg
encode stereoselective folding, directing assembly into LL- or
DD-helicates under thermodynamic control. Two isomers with
identical stereochemistry but different bipyridine connectivity
were identied through NMR spectroscopy. A CuII variant of
Chem. Sci.



Chemical Science Review
this system was subsequently developed, demonstrating the
structural versatility of this peptide scaffold.53,54

Another motif that demonstrates non-covalent templation of
peptide folding in self-assembly is Miyake et al.'s articial b-
oligopeptides bearing tridentate propanediamine side chains.
These peptides cyclise via NiII-mediated self-assembly into
macrocyclic clusters, with the rst report being the self-
assembly of b-dipeptide 8 into [NiII4L4]

8+ macrocycle 9, as
shown in Fig. 2e. In this structure, C- and N-terminal tridentate
donors each bind two NiII ions (Fig. 2f), engendering a macro-
cyclic structure with an internal cavity for guest inclusion.45,55
Fig. 3 Cage and interlocked structures with peptide backbones,
whose formation is directed by peptide folding and secondary inter-
actions with metal coordination. (a) The structure of amine ligand 10
and its sequence, and its various self-assembly reactions. The self-
assembly of 10 and NiII yields [NiII14L14]

28+ macrocycle 11 or
[NiII12L12]

24+ macrocycle 12 under different crystallisation conditions.
Using 2 equiv. of NiII and NaHCO3, or adding 1 equiv. of NiII and
NaHCO3 to 11 or 12, affords [NiII8L8]

16+ macrocycle 14. Using 1 equiv.
of NiII, 1 equiv. of CuII and NaHCO3 generates [NiII4Cu

II
4L8]

16+

macrocycle 13 instead. (b) Visualisation of coordination between NiII

and ligand 10 and hydrogen bonds in macrocycle 11. (c) The structures
of bis-pyridyl ligands 15–18, and their sequences. (d) The self-
assembly of ligand 15 and AgI to give torus knots 19 ([AgI7L7]

7+) and 20
([AgI8L8]

8+) as racemic mixtures. (e) Visualisation of coordination
between AgI and ligand 15 and secondary interactions in torus knot 19.
(f) The self-assembly of ligand 16 and AgI forms P-21, an enantiopure
[AgI8L8]

8+ analogue of 20, while the self-assembly of ligand 17 and AgI

forms amixture of P-22, an enantiopure [AgI8L8]
8+ analogue of 20, and

enantiopure [AgI9L9]
9+ torus knot P-23. (g) The self-assembly of ligand

18 and AgI forms P-24, an enantiopure [AgI21L14]
21+ barrel. (h) The

structure of bis-pyridyl ligand 25 with its sequence shown and its self-
assembly with ZnII to form ZnII6L6I12 b-barrel 26, with hydrogen bonds
visualised on its structure, and a minimal visualisation of its secondary
structure adapted from ref. 55, copyright © 2018 American Chemical
Society. (i) The structure of bis-pyridyl ligand 27 and its self-assembly
with AgI to form b-sheet [2]catenane 28, with hydrogen bonds
visualised on its structure, and a visualisation of its secondary structure,
as adapted from ref. 58, copyright © 2024 the author(s). Angew.
Chem., Int. Ed. published by Wiley-VCH GmbH. All structures shown
are SCXRD structures. Colour codes: C = light blue (basic side chains),
green (non-polar side chains) or grey (other moieties), N = blue, O =
red, Ni = green, Cu = brick red, Zn = yellow, Ag = silver, I = purple,
hydrogen bonds = black, aromatic stacking = brown, weak AgI/O
coordination = lime.
2.2 Metallomacrocycles and interlocked topologies from
interplay of coordination and peptide folding

In the formation of peptide-backboned self-assembled struc-
tures, metal coordination can not only independently guide
peptide conformation, but may also act synergistically with
intra- or inter-chain interactions, enhancing overall structural
control. This cooperativity extended Miyake's motif,45 providing
access to larger macrocyclic structures.46 Starting from the rst
[NiII4L4]

8+ macrocycle 9, changing the acetyl at the N-terminus
into a Gly residue provides another metal binding site for the
resulting b-tripeptide ligand 10. With NiII, a range of larger
exible macrocyclic structures can be formed, as shown in
Fig. 3a. Crystallisation under different conditions afforded
[NiII14L14]

28+ macrocycle 11 and [NiII12L12]
24+ macrocycle 12. In

both structures, intra-chain H-bonding and metal binding curl
the peptides into zig–zag shapes, organising the repeating units
of bent peptides and NiII centres into macrocyclic structures
(Fig. 3b). The amide groups in 10 can be deprotonated under
basic conditions to participate in coordination. Self-assembly
with a 1 : 1 mixture of NiII and CuII cations results in the
formation of [NiII4Cu

II
4L8]

16+ macrocycle 13, where CuII adopts
square planar tetra-coordination, with amides and b-alanines as
donors. The addition of excess NiII can also convert 11 to favour
tetra-coordination instead of 6-coordination for part of the NiII,
resulting in the formation of [NiII8L8]

16+ macrocycle 14,
a homometallic analogue of 13.56

Enhanced inter-chain interactions can also lead to the
formation of interlocked structures. As reported by the Fujita
group, [Ag7L7]

7+ knot 19 and [Ag8L16]
8+ link 20 self-assemble

from AgI and an extremely exible Gly3 peptide 15, with pyr-
idyl functionalisations at both termini for AgI coordination, as
shown in Fig. 3c and d.57 Fig. 3e shows the non-covalent inter-
actions identied as the driving forces for these interlocked
structures to form, including inter-chain H-bonding, aromatic
stacking between the pyridyls, as well as C]O/AgI coordina-
tion. These interactions cooperatively organise the exible tri-
glycine peptide into a single conformation in self-assembly,
where the three glycines show distinct 4 and J torsion angles
(Gly2: 4 ∼ −60°, J ∼ 180° vs. Gly3: 4 ∼ 60°, J ∼ −180°).48 Gly2
could be replaced with Ala, which can adopt similar torsion
angles. The chirality of Ala biases the helicity of the originally-
racemic links into an enantiopure form, as shown by the
formation of P-21 from the self-assembly of 16 and AgI

(Fig. 3f).48
Chem. Sci. © 2026 The Author(s). Published by the Royal Society of Chemistry



Fig. 4 Peptide-backboned interlocked cage structures from the
interplay of peptide folding with metal coordination. (a) The structures
of bis-pyridyl ligands 29–31 and their sequences. (b) The self-assembly
of ligand 29 and AgI to T2-type tetrahedral [AgI12L12]

12+ [4]catenane 32.
(c) Visualisation of coordination between AgI and ligand 29, and
secondary interactions in [4]catenane 32. (d) The structures of bis-
pyridyl ligands 33–36, and their sequences. (e) The self-assembly of
ligand 35 and AgI to three-crossed type [AgI12L12]

12+ [4]catenane 37. (f)
Visualisation of coordination between AgI and ligand 35 and secondary
interactions in [4]catenane 37. (g) The structure of bis-pyridyl ligand 38
and its self-assembly with AgI to form [2]catenane 39, with secondary
interactions visualised on its structure. (h) The structures of bis-pyridyl
ligands 40–48, and their sequences. (i) The self-assembly of ligand 40
and AgI to cubic [AgI24L24]

24+ [6]catenane 49. (j) Visualisation of
coordination between AgI and ligand 40 and secondary interactions in
[6]catenane 49. (k) The self-assembly of ligand 46 and CuI to give
icosahedral 60-crossing [CuI60L60]

60+ capsid 50. (l) Visualisation of
a trefoil knot structural unit in 50, with hydrogen bonds visualised on its
structure. All structures shown are SCXRD structures. Colour codes: C
= green (non-polar side chains) or grey (other moieties), N= blue, O=
red, Cu = brick red, Ag = silver, hydrogen bonds = black, aromatic
stacking = brown, weak AgI/O coordination = lime.

Review Chemical Science
In order to access knots and link structures with more
crossings, Sawada and Fujita et al. sought to introduce strain to
the Gly1 or Ala1 residue (in 15 and 16, respectively) by mutation
to amino acids with bulkier inward-pointing side chains. As
shown in Fig. 3f, the use of L-2-aminobutyric acid (Abu) in
ligand 17 extended the range of self-assembled structures
accessible, generating a mixture of 22, an 8-crossing link
analogue of 20, and 9-crossing [Ag9L9]

9+ knot 23. The use of
norvaline (Nva) or norleucine (Nle) gave rise to even larger
[Ag10L10]

10+ links and extended supercoil structures.58 Further-
more, as shown in Fig. 3g, Gly2 can also be replaced by chiral 4-
pyridylalanine (4pa) to generate ligand 18, which can access
similar torsion angles to form the [Ag7L14]

7+ torus link structure,
while the additional pyridyls can coordinate to 7 extra AgI

vertices in a linear manner, to form [Ag21L14]
21+ peptide nano-

tube 24.48

The promotion of inter-chain interactions by metal coordi-
nation can be further exploited to create secondary structures
similar to those of proteins. In 2018, Sawada, Fujita et al. re-
ported synthetic [Zn6

IIL6]
12+ b-barrel 26, in which secondary

structure folding was facilitated by metal coordination.44 As
illustrated in Fig. 3h, 26 self-assembled from peptidic chain 25,
comprising two Phe–Val–Phe–Val and Pro–Gly–Pro peptidic
chains, linked together by a 1,3-phenylene linker (x), function-
alized with 3-pyridyl at both termini. Self-assembly with ZnII

forms a [ZnIIL2]
4+ macrocycle, with two coordinating halide

counterions per vertex. The Phe–Val–Phe–Val sequence has an
intrinsic tendency to form a b-barrel, which was enhanced by
the geometry of ZnII coordination. The exible Gly adopts an
extended conformation (4 ∼ −100°, J ∼ −170°), forming an S-
shaped strand for the Pro–Gly–Pro moiety with more robust,
twisted Pro residues (4 ∼ −110 to −70°, J ∼ 120 to 180°),
complementing the extended Phe–Val–Phe–Val (4 ∼ −150 to
−70°, J ∼ 120 to 150°) to form the macrocyclic structure,
thereby allowing for the recognition among the Phe–Val–Phe–
Val side chains to generate the b-barrel.

Metal-directed folding also provided a pathway to access
other secondary structures, including double-stranded b-helices
(ds-b-helices)59 and b-sheets.47 By using pentapeptide 27 with
Boc protecting groups at the N-termini and methyl esters at the
C-termini, featuring 3-pyridylalanine (3pa), with the sequence
(Ala–D-3pa–Gly–3pa–Val), self-assembly with AgI results in the
formation of [Ag4L4]

4+ [2]catenane 28 (Fig. 3i).47 The coordina-
tion of 3pa with AgI generates macrocyclic components with the
two peptide strands separated to a sufficient degree to accom-
modate a strand from another macrocycle, and the b-sheet
recognition and metal coordination mutually result in the
catenation of 28.

Fujita and Sawada et al. have thus unveiled the entry to
a series of metal-peptide interwoven structures where folding is
key to structure formation.49,60–64 In 2016, they reported the self-
assembly of AgI with a peptidic bis-pyridyl ligand 29 (Fig. 4a),
with a sequence of Pro–Gly–Pro.60 The cooperative effect of the
robust Pro units and AgI coordination led to an U-loop confor-
mation, in which the two Pro exhibit typical torsion angles (4 ∼
−65°, J ∼ 150 or −30°) similar to the a-helix region, while Gly,
in contrast to the extended conguration adopted in 28, showed
© 2026 The Author(s). Published by the Royal Society of Chemistry
a harsher twist (4 ∼ −120°, J ∼ 180°). This conformation
eventually leads to the assembly of T2-type [AgI12L12]

12+ [4]cat-
enane 32 with 12 crossings (Fig. 4b and c). Assembly with ligand
30, in which Gly1 was replaced with azetidine-2-carboxylic acid
(Aze), a more robust, four-membered ring version of Pro,
resulted in the formation of another T2-type [AgI12L12]

12+ [4]
catenane analogue of 30. The use of 31, using six-membered
ring piperidine-2-carboxylic acid (Pip), did not form the same
Chem. Sci.



Chemical Science Review
structure, which indicates the importance of the rigidity of the
peptide in the folding and assembly process, allowing posi-
tioning of secondary interactions at the required locations.

Changing this sequence to Gly–Pro–Pro promotes the
formation of a near-linear PPII-helix conformation instead of an
U-loop, leading to the formation of an innite network.65

Mutation of the Gly to ligands 33 or 34 (shown in Fig. 4d) with
bulky Val or Ile regenerates the U-loop, forming [AgI12L12]

12+ [4]
catenanes with the same topology as 32. However, when smaller
Thr or Ala is used for a Ala–Pro–Pro (ligand 35) or Thr–Pro–Pro
(ligand 36) sequence, a different type of three-crossed
[AgI12L12]

12+ [4]12 catenane structure was found to self-
assemble, with the Ala-containing 37 shown in Fig. 4e and f,
featuring PPII-helices.62 For 34 (Ile–Pro–Pro), 35 (Ala–Pro–Pro) or
36 (Thr–Pro–Pro) (Fig. 4d), despite showing a similar range of
torsion angles (4 ∼ −120 to −60°, J ∼ 90–180°), the peptide
bond between the two Pro is cis (u= 0°) in 34, which formed the
PPI twist required for a similar U-loop as in 32, while this
peptide bond is trans (u = 180°) in the latter two, which retain
the PPII-helix structure. These PPII-helix containing peptides
thus form macrocyclic components that interweave in
a different way.

Tethering of two of these peptides together with a 1,3-
phenylene linker provides access to more types of interlocked
structures.61,63 For example, dipyridyl ligand 38 (Fig. 4g), with
a Pro–Gly–Pro–x–Gly–Pro–Pro sequence, curls upon binding AgI,
thus forming an U-loop of the Pro–Gly–Pro chain, while the
other half of the ligand complements it to generate a macro-
cycle. Two of these macrocycles were found to interlock to
generate [AgI2L4]

12+ [2]catenane 39 via aromatic stacking, with
the two Pro–Gly–Pro and Gly–Pro–Pro tripeptide stands showing
similar conformations as in their corresponding homomeric
structures.61 Compound 40, a shorter tethered bis-dipeptidic
ligand, with a Pro–Pro–x–Ala–Pro sequence, was found to
form a [AgI24L24]

24+ cubic [6]catenane 49 (Fig. 4h and i), which
contains six macrocyclic peptide tetramers.63 Each peptide
chain forms an S-shaped loop with a ∼90° turn, with each
residue showing a similar degree of PPII-helix-like twist (4 ∼
−60°, J ∼ 130–180°) As shown in Fig. 4j, each cube vertex is
stabilised by six sets of inter-chain hydrogen bonds across three
ligand strands, while on each edge, four sets of hydrogen bonds
were found among the amides from two peptide chains. The
cubic link structure of 49 can tolerate mutations at the Ala
residue to ligands 41 and 42 containing bulky Leu or Nva,49 or
polar functionality, such as 43 with Gln, but 44 with the overly
exible Gly or 45with rigid Pro did not result in the formation of
any discrete structure.

More drastic alternation in the formed structures happens
when the Ala in the Pro–Pro–x–Ala–Pro sequence is replaced
with the coordinating propargylglycine (Pra) of 46, which was
found to assemble with CuI to form gigantic Cu60L60 dodeca-
hedral link 50 (Fig. 4k).49 The Pra residue was essential for the
formation of 50 in the sense of both peptide folding and metal
coordination. It has the correct geometry to serve as an addi-
tional donor to the CuI cations, and it also closes the ligand
strands to form the trefoil knot subunits shown in Fig. 4l, which
was considered crucial to the formation of 50. The triangular
Chem. Sci.
edges of these knots join together to form the pentagonal
windows of the dodecahedral framework, instead of the square
windows for the cubic link, with only Pra replacing the Ala in
the peptide sequence. This result may be explained by Ram-
achandran plots of 43 and 45, which also revealed that instead
of adopting a typical helical twisted conformation in a PPII-
helix, the degree of twisting (4 ∼ −90°, J ∼ 110°) of the Pra
residue is more open, between a PPII-turn and an extended (b-
sheet-like) conformation. This difference may drive the forma-
tion of pentagonal instead of square windows. Elongation of the
Pra in 46 by one b-methylene to l-homopropargylglycine (Hpg)
in 47, or changing the propargyl to the non-coordinating b-
cyano-L-alanine (Cya) in 48, led to the formation of non-
interlocked structures.
2.3 Pre-organised oligoproline metallacages

As described above, metal-directed folding and self-assembly
proved to be an efficient approach to allow access to diverse
interlocked architectures. Another route to well-dened self-
assembled structures consists of using peptides with strong
conformational tendencies, and their bridging with non-
covalent interactions. This principle is highlighted by recent
work on oligoproline metallacages. McTernan et al. rst
demonstrated this approach, with Palma et al. subsequently
reporting related designs.66–68 Fig. 5a and b shows the design of
the oligo(L-proline) ligands reported by these groups. As it takes
approximately three residues for a full 360° turn to occur in
a PPII secondary structure, these groups designed ligands that
include 4, 7, 10, and 13 residues. Featuring similar designs, all
these ligands have the N-termini capped with a pivalic amide
structure and C-termini functionalised as amides, with trans-
hydroxyproline (Hyp) replacing Pro residues at both ends. As
shown in Fig. 5a, Palma et al. functionalised the hydroxy groups
with bare or dimethyl substituted pyridyls, obtaining ligands 51
and 52–55,67 whereas McTernan et al. prepared ligands 56–59.66

The self-assembly of 51 with PdII yielded a cis–trans mixture of
[PdIIL2]

2+ mononuclear complex 60 (Fig. 5c), with stereoisom-
erism generated by the orientation of the oligoproline strands.
The same stereochemistry resulted in four potential isomers
(‘all-up’ or CCCC, ‘two-up, two-down’ or CCNN, ‘one up, three
down’ or CNNN, and ‘one down, three up’ or CCCN) for the self-
assembly of 52 and 56–59. Each one generated lantern-shaped
[PdII2L4]

4+ 61 and 62–65, respectively (Fig. 5d and e), with
a model of 63 shown in Fig. 5f. Interestingly, 61 was found to
adopt CCCC stereochemistry for the peptidic orientations,
while 62–65, despite having distinct numbers of turns, all form
CCNN diastereomers. Mono-methylated ligands 53 and 54 were
observed to generate complex mixtures upon treatment with
PdII, while no PdII complexation to the bulkier lutidine-based 55
was found to take place at all.

Proceeding from the structure of bis-pyridyl ligand 58 (10 Pro
residues), McTernan et al. then added one extra 4-pyridyl
functionalisation to either the Pro7 or Pro3 as an extra donor
site, obtaining ligands 66–69.68 As shown in Fig. 5b, 66 and 67,
and 68 and 69, are prepared as pairs of diastereomers: the
handedness of all b-carbons is either kept as R-, as in 51, 52–55
© 2026 The Author(s). Published by the Royal Society of Chemistry



Fig. 5 Peptide-backboned cages from robust, highly preorganised
peptides. (a) The structures of bis-pyridyl oligoproline ligands 51–59.
(b) The structures of tris-pyridyl oligoproline ligands 66–69. (c) The
self-assembly of ligand 51 and PdII to [PdIIL2]

2+ mononuclear complex
60 as a mixture of cis- and trans-stereoisomers. (d) The self-assembly
of ligand 52 and PdII to give [PdII2L4]

4+ cage 61 as a ‘two-up, two-
down’ or CCNN stereoisomer, considering the orientations of the
peptide chains. (e) The self-assembly of ligand 56–59 and PdII to give
[PdII2L4]

4+ cages 62–65, respectively. 62–65 are prepared as the ‘two-
up, two-down’ or CCNN stereoisomer, regarding the orientations of
peptide chains. (f) A model of cage 63. (g) The self-assembly of ligand
66 and PdII to give [PdII3L4]

6+ cage 70 as a ‘two-up, two-down’ or
CCNN stereoisomer, regarding the orientations of the peptide chains.
(h) The self-assembly of ligand 69 and PdII to give cage 73 as a ‘all-up’
or CCCC stereoisomer, regarding the orientations of peptide chains. (i)
A model of cage 73. (j) The self-assembly of ligand 67 and PdII to give
[PdII6L8]

12+ structure 71, inferred to be a [2]catenane. (k) The self-
assembly of ligand 68 and PdII to give [PdII3L4]

6+ structure 72, as
a mixture of all possible diastereomers, considering the orientations of
peptide chains. (l) The structure of bis-pyridyl ligand 74, with a cyclic
recognition motif containing four Val-residues in its centre. (m) The
self-assembly of ligand 74 and PdII to give [2]catenane cage 75. Colour
codes for schematic drawings: main chains= grey, basic side chains=
blue, neutral, non-polar side chains = green, termini and other
moieties = black. Colour codes for rendered structures: C = light blue
(basic side chains), green (non-polar side chains) or grey (other
moieties), N = blue, O = red, Pd = teal.

Review Chemical Science
and 56–59, or inverted to S-. Four distinct scenarios were
observed for these two pairs of stereoisomers. The self-assembly
of 66, 68 and 69 yielded [PdII3L4]

6+ structures 70, 72 and 73,
respectively, with distinct stereochemistries. 70 was found to
maintain the CCNN stereochemistry observed for 62–65
(Fig. 5g), while 73 was found to exhibit the CCCC conguration,
as shown in Fig. 5h and i. In contrast, 72 was found to assemble
© 2026 The Author(s). Published by the Royal Society of Chemistry
as a complementary mixture, including all four potential
isomers (Fig. 5k). The stoichiometry of 71, the self-assembled
product from 67 and PdII, was identied as [PdII6L8]

12+

(Fig. 5j), which was inferred by McTernan et al. to be a [2]cate-
nane structure formed by two [PdII3L4]

6+ cages. The stereo-
chemistry of these cages could not be determined due to the
broad NMR spectra.

Peptide conformations can also be locked covalently before
assembly. A 2020 report by Clever et al. featured this approach
to create a recognition motif for the synthesis of interlocked
structures.43 Fig. 5l shows the C-shaped peptidic ligand 74
employed in this study, featuring two Val–Val strands, brought
together in a head-to-tail manner with a methylimidazole ring,
functionalised with pyridyl ligating units. As shown in Fig. 5m,
its self-assembly with PdII affords [Pd2L4]

4+ [2]catenane 75, in
which two gure-of-eight macrocycles, each formed by joining
two ligands together with a PdII vertex, interlock with each other
via aromatic stacking between pyridyl and phenylene moieties,
while other pyridyls reside in the cavities of the peptidic
macrocycles.
3. Cages with peptides as auxiliary
units

The integration of peptides with rigid aromatic scaffolds is an
alternative approach to address the entropic and exibility
challenges of making cages with only peptides as backbones.
Rigid aromatic platforms provide geometric preorganisation by
constraining spatial arrangements and minimising conforma-
tional freedom, facilitating assembly through metal coordina-
tion,69,70 covalent bond formation,71,72 dynamic covalent
chemistry,73,74 and hydrogen bonding networks.75,76 These scaf-
folds also provide chemically accessible sites for peptide
attachment, enabling systematic incorporation of amino acid
functionality without compromising structural integrity.

This section examines ve primary binding modes for
peptide-functionalised cages: metal coordination, covalent
assembly, dynamic covalent linkages, hydrogen bonding
networks, and hybrid approaches combining multiple interac-
tions. Each strategy offers distinct advantages for incorporating
biological functionality while maintaining structural control
through rigid aromatic preorganisation.
3.1 Metal-coordination cages

In pioneering work nearly two decades ago, Fujita and co-
workers exploited the directionality of the coordination bond
to synthesise a large [PdII12L24]

24+ cuboctahedral metal–organic
cage in which peptide moieties were appended to a bent bi-
s(pyridylethynyl)benzene ligand scaffold (Fig. 6a).69 The
aromatic ligand was functionalised via amide coupling at the
central aromatic core with different aliphatic amino acids and
peptides of up to four residues (76–84). These ligands assem-
bled into cages where all pendant groups were either Boc-
protected or acetylated at the N-terminus to prevent undesired
coordination to the metal centres. The resulting structures di-
splayed internal surfaces decorated with 24 to 96 amino acid
Chem. Sci.



Fig. 6 Peptide-decorated metal–organic cages assembled from
functionalised aromatic scaffolds. (a) Aromatic bent ligands based on
a bis(pyridylethynyl)benzene core were functionalised by esterification
at the central arene with aliphatic amino acids and short peptides (76–
84). Peptide residues ranged from single amino acids to tetrapeptides
and were N-terminally protected to prevent undesired coordination.
(b) The assembly of 12 equiv. of PdII and 24 equiv. of ligand bearing
Boc–L-Ala (76) yields a PdII12L24 cuboctahedral cage (85) displaying 24
amino acid residues on its interior surface. (c) Structures of hetero-
chiral tripeptide ligands 86–88, each incorporating two phenylalanine
residues and either cysteine or methionine, alongside the rigid tritopic
aromatic aldehyde 89 used in cage formation. Peptides were func-
tionalised with a p-aminobenzoyl (PABA) group at the N-terminus and
amidated at the C-terminus. (d) The subcomponent self-assembly of
12 equiv. of 86, 4 equiv. of aldehyde 89, and 4 equiv. of Fe(NTf2)2 in
acetonitrile yields FeII4L4 tetrahedral cage 90. Colour code for
rendered structures: Peptide backbone and aromatic scaffold =

grey, N = blue, O = red, S = yellow, Pd = teal, Fe = magenta.

Chemical Science Review
residues, generating conned chiral environments. The
[PdII12L24]

24+ cage 85 derived from Boc–L-Ala ligand 76 was
studied in detail to probe the transfer of stereochemical infor-
mation from peptide to cage framework (Fig. 6b). CD spec-
troscopy revealed a Cotton effect for cage 85 approximately 30
times stronger than that of the free ligand at equimolar
concentrations.

Notably, cages assembled from amino acid enantiomer 77
exhibited mirror-image Cotton effects, demonstrating that the
chirality of the amino acid residues effectively dictated the
handedness of the entire cage structure. This chiral signal
amplication was attributed to the collective twisting of the
ligand framework induced by the peptide stereocentres.77

Building on this design, the authors prepared mixed-ligand
cages incorporating Boc–L-Phe (78) and Boc–L-Pro (80) resi-
dues, to introduce additional functionality into the conned
space. The phenylalanine residues provided aromatic surfaces
capable of stacking interactions and enhanced hydrophobic
contacts, potentially improving guest-binding selectivity. In
contrast, the inclusion of proline residues was intended to
Chem. Sci.
confer organocatalytic activity. Interestingly, when the longer
peptide L-Ala–L-Val–L-Phe–L-Ala–L-Gly was introduced, cage
formation was no longer observed, likely due to steric hindrance
within the cavity. This result pointed to a volumetric threshold
of approximately 100 amino acid residues per cage, a value
comparable to the size of small proteins.

Further investigations revealed that cage 85 self-assembles
into hollow spherical aggregates of ∼38 nm radius through
electrostatic interactions and aromatic stacking.78 These
“blackberry” structures form when nitrate counterions reduce
intercage repulsion, leading to a monolayer morphology remi-
niscent of viral capsids.79,80

Liu and co-workers demonstrated that racemic mixtures of
76- and 77-based cages undergo chiral self-sorting into
enantiopure aggregates.81 Chiral counterions such as deproto-
nated Boc–D/L-Ala modulate assembly in an enantioselective
manner. Matched chirality pairs show weak interactions,
allowing efficient nitrate binding and aggregation. Amino acid
identity proved crucial, as Val- and Leu-functionalised cages
showed slower aggregation and reduced chiral discrimination
with hydrophobic counterions, suggesting a steric/hydrophobic
threshold where non-specic interactions dominate over
stereoselective contacts.82

In summary, this family of cages demonstrates the central
role that hydrophobic amino acid residues can play in func-
tional metal–organic cages. Their incorporation initially served
to determine the chirality of the metal–ligand framework, and
they proved to be essential in modulating higher-order
assembly processes too. The ability of these cages to form
hierarchical supramolecular structures, particularly those
reminiscent of viral capsids, points to fruitful avenues for bi-
oinspired materials development. Furthermore, the observation
that subtle changes in amino acid identity can control chiral
recognition provides a platform for probing fundamental
aspects of homochirality, with implications for both catalysis
and molecular evolution.

Ligands based on bent bis(pyridylethynyl)benzene deriva-
tives have enabled the construction of other discrete architec-
tures, such as PdII2L4 cages, due to predictable coordination
geometry and rigidity.83 The ligand scaffold is synthetically
accessible and modular, as the central aromatic core can be
readily functionalised through reactions such as palladium-
catalysed cross-coupling or amide coupling. This synthetic
exibility has enabled the introduction of various functional
groups, including bioactive peptides, while preserving the
coordination geometry required for cage formation.

Notably, several recent studies have employed this ligand
framework to prepare metallacages functionalised with
peptides that promote biological targeting, such as integrin-
binding84 and blood–brain barrier-penetrating sequences.85

These examples will be discussed in greater detail in the dedi-
cated section on applications below, where the use of peptide-
functionalised cages for biomedical purposes is examined
more thoroughly.

Minimalistic peptides are also attractive building blocks
thanks to their ability to form supramolecular nanostructures
and gels.86 Their ability to self-assemble under mild conditions
© 2026 The Author(s). Published by the Royal Society of Chemistry



Review Chemical Science
has enabled their application in areas ranging from catalysis87

to biomedicine.88,89 These peptides are not only synthetically
accessible and low-cost, but they can also be produced in both
solution and solid phases at gram scale, oen using green
coupling agents.90,91 Among minimalistic peptides, tripeptides
stand out as an optimal subclass because they retain a compact
structure while providing high binding specicity and remain-
ing relatively simple to synthesise. Their short length allows
them to achieve affinities close to the ideal binding free energy
proposed for biological recognition, striking a balance between
selectivity and structural economy. This versatility makes tri-
peptides appealing not only as recognition elements but also as
tuneable building blocks for supramolecular architectures.

Specic design motifs can be readily incorporated into tri-
peptide sequences to promote self-assembly. A prominent
example is the Phe–Phe motif, known for its strong tendency to
drive aggregation into a variety of nanostructures.92–94 In
parallel, chirality plays a key role in guiding the supramolecular
organisation. The alternation of L- and D-amino acids within
tripeptides promotes an amphiphilic b-strand-like conforma-
tion in which hydrophobic sidechains and polar backbone
elements are projected on opposite sides of the molecule,
enabling hierarchical assembly.18

These peptide design principles have recently been applied
to the construction of [FeII4L4]

8+ tetrahedral cages with hetero-
chiral tripeptides 86–88 appended at the vertices (Fig. 6c).70 The
three peptides selected for this study were designed to contain
two phenylalanine residues and one sulfur-containing amino
acid, either methionine or cysteine. The peptides were further
functionalised by amidation at the C-terminus, to avoid metal
coordination by the carboxylic acid group. They were also
functionalised by introducing a PABA group at the N-terminus
to facilitate imine bond formation.

The condensation of these tripeptides with rigid tritopic
aldehyde ligand 89 around FeII template ions in acetonitrile at
60 °C for 18 hours yielded well-dened [FeII4L4]

8+ cages. 1H
NMR analysis revealed that the cages exist in solution as
a mixture of two diastereomers with opposite handedness at the
FeII vertices, designated as D4 and L4 congurations.95 One
diastereomer formed preferentially, and the diastereomeric
excess was attributed to stereochemical induction by the
enantiopure peptide ligands, which transmit their handedness
to the metal centres during the subcomponent self-assembly
process.96,97 CD spectroscopy conrmed which diastereomer
predominated by revealing Cotton effects in both the near UV
(210 to 410 nm) and visible (490 to 630 nm) regions, corre-
sponding to p-to-p* and metal-to-ligand charge transfer
(MLCT) transitions, respectively. The sign of the MLCT Cotton
band correlated with the dominant metal handedness, with L-
handed cages observed for the LDL peptides. As expected,
inversion of the peptide chirality, DLD, led to opposite Cotton
effects.

Interestingly, differences in the near UV region of the CD
spectra, associated with the secondary structure of the peptide
arms, highlighted conformational differences between the
cages. Peptides containing two phenylalanine residues gave rise
to spectral features consistent with b-strand conformations.98 In
© 2026 The Author(s). Published by the Royal Society of Chemistry
contrast, the peptide containing methionine showed a distinct
signature suggestive of a PPII-like arrangement or a type I b-
turn.99 These structural variations inuenced the cages' ability
to form metallogels in the presence of a second metal ion,
a phenomenon discussed in Section 4 below.

Cyclic peptides offer an alternative scaffold for metal-
coordinated cage assembly. Kubik demonstrated that cyclic
tetrapeptides comprising L-proline and 3-amino-5-(pyridin-4-yl)
benzoic acid subunits assemble into discrete coordination
complexes with PdII. Depending on the metal precursor, either
a dimetallic Pd2L2 macrocycle or a trimetallic Pd3L6 cage
forms.100
3.2 Covalent cages

Covalent bonds offer a versatile platform for constructing
synthetic cages with high stability and structural denition.71 In
2012, Alfonso and co-workers reported a covalent strategy in
which tripodal pseudopeptidic building blocks 91–94, obtained
from aliphatic triamines functionalised with amino acid resi-
dues, react with symmetrical 1,3,5-tris(bromomethyl)benzenes
(95–97) via three consecutive SN2 reactions. The aromatic core
acts as a rigid cap that denes the cage structure (Fig. 7a). The
reaction, promoted by bromide anions, yields [1 + 1] pseudo-
peptidic cages (98) when the geometry of the macrocyclic
intermediate allows efficient intramolecular closure (Fig. 7b).
Molecular dynamics simulations revealed that the pseudo-
peptidic tripods adopt a preorganised concave conformation,
stabilised by hydrogen bonding between amide and ammo-
nium groups and the bromide ion itself. The geometry at the
nal SN2 substitution step governed the formation of either a [1
+ 1] pseudopeptidic cage or a [2 + 2] dimer. Selective [1 + 1] cage
formation occurs only when the N/CH2Br distance in the
macrocyclic intermediate is sufficiently short to favour intra-
molecular attack. This distance depends on the nature of the
central scaffold. Aliphatic scaffolds, such as tren, imposed the
geometric constraints required for efficient cyclisation.
Aromatic scaffolds do not preorganise the arms as effectively,
resulting in competing intermolecular pathways and insepa-
rable mixtures of [1 + 1] and [2 + 2] cages.

This strategy was extended to incorporate different amino
acid residues, revealing how side-chain properties inuence
structure and binding. A comparison between two Phe-based
cages (98 and 99) illustrates the key role of substituents at the
tripodal aromatic platform. SCXRD analysis of 98, derived from
95 (R2 = H) revealed a collapsed, less symmetric conformation
in which chloride is bound externally to the cavity, interacting
with ammonium and amide NH groups (Fig. 7c). By contrast,
99, derived from methyl-substituted 96 (R2 = Me), displays
a tightly encapsulated chloride, coordinated in an approxi-
mately tetrahedral arrangement by four ammonium groups and
positioned directly above the centroid of the aromatic core,
suggesting stabilisation through anion-p interactions (Fig. 7c).
The enhanced binding affinity observed for 99 was not attrib-
uted to stronger anion-p interactions, but to steric effects
reducing solvation of the ammonium groups, thereby
improving accessibility for chloride coordination.
Chem. Sci.



Fig. 7 Covalent peptide-based cages formed from tripodal scaffolds
andmodular aromatic linkers. (a) Structures of tripodal pseudopeptidic
building blocks (91–94), derived from triamines functionalised with
amino acid residues, and 1,3,5-tris(bromomethyl)benzene scaffolds
95–97 used to promote cage formation via SN2 substitution. (b)
Assembly of cage 99 through the reaction between 1 equiv. of 93 and 1
equiv. of 96. (c) SCXRD structures of cages 98–100, showing distinct
chloride binding modes influenced by scaffold geometry and side-
chain identity. Cage 98, derived from 95, exhibits a collapsed
conformation with externally bound chloride. Cage 99 features a well-
defined cavity with internally coordinated chloride. Cage 100, based
on Val-derived tripodal ligand 92, displays dual chloride binding with
one anion partially encapsulated and one bound externally. (d)
Covalent cages 104–106 formed from benzene tricarboxamide caps
(101) linked by peptide-based arms bearing Glu (102) or Pro (103)
residues through DAB linkers. Cage 104 adopts a C3-symmetric
conformation with a hydrophilic cavity. Cage 105 collapses in solution
but undergoes guest-induced expansion upon crystallisation with NaI,
yielding cage 106 with a hydrated sodium cluster bound within the re-
opened cavity. Colour code: peptide backbone and aromatic scaffold
= grey, N= blue, O= red, Cl= lime green, Na= violet purple, I= deep
purple, hydrogen bonds = dashed black.

Chemical Science Review
Cage 100, containing Val-derived tripodal ligand 92, exhibi-
ted a different behaviour, adopting a dual-binding mode. One
chloride ion is partially included at the cavity entrance, inter-
acting with two secondary and one tertiary ammonium groups.
A second chloride is bound externally via hydrogen bonds to
amide and ammonium NH groups (Fig. 7c). This dual mode
Chem. Sci.
reects the reduced encapsulation efficiency of aliphatic cages
and greater involvement of the hydrogen-bonding network in
guest recognition.

Solution-phase studies further conrmed the lower chloride
affinity of aromatic cages 98 and 99, in contrast to the ones
derived from aliphatic tripodal ligands (92, 93, or 94). The
decreased affinity in the Phe-based cages was attributed to steric
shielding by aromatic side chains, hindering access to key
binding functionalities. The more compact and accessible
environments of the aliphatic cages enhance anion recognition
by reducing steric interference.

These ndings demonstrate how peptide-derived building
blocks, when combined with suitably preorganised scaffolds,
can yield dened covalent cages that exhibit selective guest
binding. The approach offers excellent synthetic control but
also highlights inherent limitations. Small variations in scaffold
or side-chain geometry can result in unpredictable product
distributions or reduced binding performance. A key challenge
remains to dene general design rules that reliably translate
molecular components into desired three-dimensional
architectures.

An alternative approach, reported in 2025 by the Cai and Ke
groups, introduced covalent tripodal cages constructed from
rigid aromatic caps and modular peptide arms.72 Each cage
consists of two benzene tricarboxamide units, 101, that dene
the top and bottom planes of the structure. These are connected
by three arms each comprising two amino acid residues linked
through a central 1,3-diaminobenzene (DAB) unit (Fig. 7d). The
angular constraint imposed by the DAB is essential for macro-
cyclisation, promoting preorganisation and convergent align-
ment of the arms. This design offers dual modularity. The DAB
unit can be combined with a variety of amino acids, from
charged residues such as glutamic acid (102) to aliphatic ones
such as alanine and proline (103), providing control over
backbone rigidity, hydrophilicity and hydrogen bonding. In
addition, the DAB scaffold allows peripheral functionalisation.
The introduction of bulky dicyclohexyl substituents on the DAB
linkers increases steric pressure on the arms, enabling ne-
tuning of cavity shape, hydration state and guest accessibility.

Cage 104 adopts a C3-symmetric structure in solution, as
evidenced by sharp singlets in the 1H NMR spectrum. SCXRD
analysis revealed a well-dened cavity in which the opposing
101 caps are separated by 9.0 and 9.4 Å in the distinct solid-state
conformations. The side chains of 102 are engaged in hydrogen
bonding with water molecules. The three arms adopt slightly
different conformations, reecting minor variations in carbonyl
and amide orientations, consistent with dynamic averaging
observed in solution. These observations demonstrate how
a exible, hydrophilic residue supports the formation of
a compact, yet adaptive, cavity.

Replacement of glutamic acid with proline leads to
pronounced structural changes. Cage 105, incorporating rigid
residues of 103, shows desymmetrisation in solution. SCXRD of
105 shows a collapsed conformation, with 101 caps arranged
orthogonally and separated by only 4.8 Å. The cavity is occluded
by a hydrogen-bonded network of water molecules and stabi-
lised by intramolecular hydrogen bonds involving terminal
© 2026 The Author(s). Published by the Royal Society of Chemistry



Fig. 8 Peptide-derived cages constructed through dynamic covalent
strategies. (a) Dynamic-covalent cage assembly from benzene-1,3,5-
tricarbaldehyde (107) and a series of C2-symmetric bis(amidoamine)
linkers (108–111), each incorporating a trans-1,2-cyclohexane scaffold
and a distinct amino acid residue: valine (108), phenylalanine (109),
serine (110), or threonine (111). (b) Self-assembly of 1 equiv. of 107 and
1.5 equiv. of 108 under reversible imine formation followed by in situ
reduction yields cage 112. SCXRD of 112 reveals chair conformations
of the cyclohexane ring, with outward-projecting isopropyl groups. (c)
Aromatic tritopic building blocks of different sizes (113–115) and

Review Chemical Science
amines and backbone NH groups. Crystallisation in the pres-
ence of NaI induces a guest-dependent rearrangement. The
SCXRD structure 106 displays a symmetric conformation, with
101 caps aligned in parallel and separated by 6.7 Å, encapsu-
lating a hydrated sodium cluster coordinated by carbonyl and
water ligands. This behaviour demonstrates the ability of 105 to
undergo guest-induced conformational transitions between
collapsed and expanded states.

This modular approach demonstrates how peptide
sequence, linker geometry, and peripheral substitution can be
strategically combined to ne-tune the properties of covalent
cages. The capacity to modulate cavity shape, rigidity and
hydrophilicity through targeted chemical modications repre-
sents a strength of this design. At the same time, these systems
exemplify the inherent complexity of molecular engineering:
even small variations in side-chain polarity or hydrogen-
bonding potential can induce signicant changes in structure
and function. The sensitivity of cage assembly to these param-
eters underscores the importance of integrating detailed
experimental characterisation with rational design principles.

Overall, the systems developed by Alfonso and by Cai and Ke
illustrate two distinct but complementary strategies for con-
structing covalent peptide-based cages. The former exploits
intramolecular SN2 reactions and scaffold-guided preorganisa-
tion to promote efficient macrocyclisation. The latter employs
rigid aromatic platforms and bent linkers to generate struc-
turally diverse and tuneable architectures. Both approaches
highlight the potential of biologically inspired building blocks
for selective molecular recognition, but also expose the chal-
lenges of achieving precise conformational control and cavity
denition in aqueous environments. Addressing these chal-
lenges will require a deeper understanding of how scaffold
geometry, side-chain interactions and solvation collectively
govern the assembly and behaviour of peptide-derived cages.
bearing Cys moieties leads to D3-symmetric homoleptic cages via
direct oxidation in water at pH 8. (d) Dynamic disulphide exchange
strategy using 113 with 114 or 114 with 115 yields mixtures containing
both homodimeric (116–118) and heterodimeric cages (119–120). By
contrast, the pair 113 and 115 fails to form heterodimers due to
unfavourable geometry. Structures 116–120 are shown as cartoons,
where coloured triangles represent the shapes and relative sizes of the
aromatic platforms. (e) Assembly of cage 123 via dual dynamic cova-
lent reactions, acylhydrazone linkages between TPE-based aldehyde
121 and cysteine-hydrazide 122, along with disulphide bonds forma-
tion, yield a closed tetrapodal cage. The resulting restriction of TPE
rotation induces aggregation-induced emission. Cage 123 is repre-
sented as a schematic square reflecting the geometry of the tetratopic
core.
3.3 Dynamic-covalent cages

Although irreversible covalent bonds afford exceptionally stable
cages, their assembly typically requires lengthy multistep
syntheses, low overall yields, and the use of highly preorganised
ligands to suppress oligomer formation. To overcome these
limitations, dynamic covalent chemistry (DCC) provides an
alternative strategy, exploiting reversible bond formation under
thermodynamic control to enable self-correction and favour the
most stable product.

Simultaneously with their work on tripodal cages described
above, Alfonso and co-workers developed a complementary
strategy based on DCC to assemble pseudopeptidic cages
through reversible imine formation, followed by reduction to
amine linkages.73 In this approach, benzene-1,3,5-
tricarbaldehyde (107) generates both the top and bottom plat-
forms of the cage, while the three aldehyde groups are con-
nected by C2-symmetric bis(amidoamine) linkers (Fig. 8a). Each
linker incorporates an amino acid residue and either a rigid
trans-1,2-cyclohexane or a exible ethylene spacer. The confor-
mational constraints imposed by the cyclohexane moities
promote preorganisation, allowing the assembling system to
© 2026 The Author(s). Published by the Royal Society of Chemistry
self-correct through reversible imine exchange under thermo-
dynamic control, and afford a single D3-symmetric hexa-imine
intermediate. Subsequent in situ reduction using borane–pyri-
dine yields the corresponding pseudopeptidic amine cage in
overall yields ranging from 30 to 60%, depending on the steric
and electronic properties of the incorporated amino acid
(Fig. 8b).

SCXRD structure of cage 112, containing Val residues from
subcomponent 108, reveals that all three cyclohexane rings
Chem. Sci.



Chemical Science Review
adopt chair conformations, with each amide NH positioned anti
to the adjacent C–H (Fig. 8b).101 The isopropyl side chains adopt
pseudo-equatorial orientations and project outward from the
cage surface, while the cavity accommodates four perchlorate
anions. These anions form hydrogen bonds with both the
ammonium groups and the amide NH donors, reecting an
inherent affinity of this architecture for anions, and under-
scoring how side-chain disposition inuences cavity accessi-
bility and binding capacity.

In contrast, cages derived from exible ethylene-linked bi-
s(amidoamines) require benzene-1,3,5-tricarboxylate as
a template to form the same D3-symmetric architecture effi-
ciently.73 Modelling suggests that the template engages in
convergent hydrogen bonding with amide donors in the cavity,
aligning the arms and facilitating cage closure. In the absence
of the template, greater conformational freedom reduces the
yield and selectivity of cage formation, highlighting the critical
role of linker geometry and preorganisation in dynamic cova-
lent assembly.

This methodology accommodates a diverse range of amino
acids, including aliphatic, aromatic, and polar residues,
enabling ne tuning of the steric environment, hydrogen-
bonding landscape, and hydrophilicity of the cages.101,102 Vari-
ations in side-chain functionality allow modulation of comple-
mentarity and stereoselectivity, with serine (110) and threonine
(111) introducing additional hydrogen-bond donors that
enhance interactions with polar guests, such as dipeptides.
Aromatic residues expose their p-surface area within the cavity,
supporting favourable stacking interactions with aromatic
portions of guest molecules. This modularity establishes these
pseudopeptidic cages as an expandable library, in which back-
bone geometry and side-chain diversity can be systematically
exploited to tailor recognition properties.

This modular, self-correcting, and template-sensitive imine-
based approach allows systematic variation of cavity properties,
but binding affinities remain moderate in mixed organic
solvents, which could limit performance in fully aqueous or
competitive environments. The synthetic protocol requires
chromatographic purication and counterion exchange, adding
procedural complexity. The rigid D3 symmetry further
constrains the accessible guest space, favouring small anionic
or peptidic targets. Nevertheless, these pseudopeptidic cages
demonstrate how amino acid functionalities and aromatic
frameworks can be combined to tune cavity polarity, rigidity,
and selectivity.

Disulde exchange is another established dynamic covalent
strategy for synthesising a wide variety of supramolecular
architectures. A key study published in 2012 by Sanders and
Stefankiewicz demonstrated the creation of a dynamic combi-
natorial library (DCL) of cages based on disulde bonds.74 The
system used a tritopic building block derived from 1,3,5-
trisubstituted benzene bearing three cysteine units (113)
(Fig. 8c), combined with the ditopic bridging linker 3,5-di-
mercaptobenzoic acid. The system in water at pH 8 without any
template generated a mixture of cyclic trimers, tetramers, and
a dimeric cage. Upon addition of protonated polyamines, the
library distribution was amplied towards specic
Chem. Sci.
multicomponent cages depending on the nature of the tem-
plating polyamine. Linear polyamines bearing multiple
ammonium groups, such as spermine and tri-
ethylenetetramine, most effectively promoted the formation of
larger, dened cages. The distribution of amplied species was
determined by the length, exibility and charge density of the
polyamines.

While this approach enabled the generation of structurally
complex architectures, it suffered from intrinsic limitations.
The DCL could not be amplied towards a single dominant
species, and the resulting mixtures were challenging to purify.

In 2021, Stefankiewicz expanded the disulde cage strategy
by incorporating larger aromatic platforms into the same
framework (Fig. 8c).103 The original tritopic building block (113)
was retained, but additional aromatic units were introduced
into compounds 114 and 115, to incrementally increase the size
of the rigid platform. The cysteine residues served a dual role,
providing both disulde-forming thiols, and terminal carbox-
ylate groups that ensured water solubility. In this system, no
ditopic linker was employed, and direct oxidation at pH 8 in
water yielded exclusively homoleptic cages with D3 symmetry.
While no X-ray crystal structures were obtained, 1H NMR
spectra showed upeld shis for aromatic resonances, consis-
tent with close spatial proximity of the aromatic platforms, and
deshielding of the cysteine a and b protons indicated their
exposure at the periphery of the cages. The study also explored
heterodimeric cage formation by mixing pairs of building
blocks. Combinations of 113 with 114, and of 114 with 115,
yielded three products each: the homodimers, 116–118, and the
corresponding heterodimers, 119 and 120 (Fig. 8d). By contrast,
the combination of platforms 113 and 115 produced only the
homodimeric species without detectable heterodimer (Fig. 8d).
This selectivity was rationalised in terms of two geometric
parameters, the rotation (q) and trapezoidal (z) angles, deter-
mined by molecular modelling. q quanties the degree of twist
required to align two platforms for disulde bond formation,
with values above 80° preventing cage closure, as in the case of
the heterodimer composed of 113 and 115 (q > 100°). z denes
the angle between the plane of the aromatic platform and the
cysteine arm, reecting the distortion required to bridge the
platforms. In this case, values exceeding 120° prevent cage
formation, as with the heterodimer from 113 and 115, charac-
terised by a size mismatch between platforms.

These examples conrm that disulde-based chemistry
provides a modular approach for constructing larger peptide-
derived assemblies. Nevertheless, directing the dynamic
combinatorial library towards a single thermodynamically fav-
oured product remains a challenge. For this reason, strategies
combining disulde exchange with orthogonal dynamic
processes, such as acylhydrazone formation, have emerged as
promising routes to improve delity and control over the
outcome of self-assembly.

In 2017 Ulrich and Stefankiewicz described a tetrapodal cage
constructed from 1,1,2,2-tetraphenylethene (TPE) tetra-
carboxaldehyde core 121 and cysteine-hydrazide linker 122
(Fig. 8e).104 The four benzaldehyde groups and phenyl rings of
121 can rotate freely in solution, rendering the precursor non-
© 2026 The Author(s). Published by the Royal Society of Chemistry



Fig. 9 Peptide-derived cages assembled via dynamic covalent bonds
and hydrogen bonding. (a) Tetraformylresorcin[4]arene scaffold 124
and peptide-based ligands employed for cage formation. Imine-linked
systems utilise dipeptides 127–128 and tripeptides 129–130 with
terminal amines, while hydrazone-linked systems employ hydrazide

Review Chemical Science
emissive. Upon cage formation, these rotations become
restricted, resulting in aggregation-induced emission that
enables real-time monitoring of the assembly process by uo-
rescence. In this design, each hydrazide condenses with an
aldehyde to form eight acylhydrazone linkages, stabilised by
internal hydrogen bonding that zips the structure into a closed
and rigid shell. Simultaneously, the oxidation of cysteine thiols
formed two disulde bonds, which preorganise the four TPE
units into a stacked, face-to-face arrangement. This combina-
tion of stacking and hydrophobic effects directs the dynamic
library towards the exclusive formation of a single, fully closed
tetrapodal cage 123 (Fig. 8e).

This method offers functionalisation opportunities, as the
amino termini of the cysteine residues remain accessible for
post-synthetic modication.104 This was demonstrated by
coupling hydrophilic units, such as 2-(2-methoxyethoxy)acetic
acid, and hydrophobic groups, such as 2-ethylhexanoic acid,
which modulate cage solubility in aqueous media or organic
solvents such as chloroform. DMSO was required in all cases to
facilitate thiol oxidation and ensure cage formation. This
solubility-tuning expands the operational scope of these doubly
dynamic covalent architectures, while retaining their charac-
teristic emission properties, with potential applications as
responsive uorescent materials.
derivatives of valine 131–132 and Phe–Gly 133–134. (b) Imine-based
cages assembled through condensation of amine-functionalised
peptides 127–130 with scaffold 124. Cage 135, obtained from
homochiral dipeptides, adopts a symmetric dimeric architecture
sealed by twelve hydrogen bonds. Cage 136 forms preferentially from
racemic tripeptides, showing social self-sorting into heterochiral
dimers stabilised by 24 hydrogen bonds arranged in an antiparallel b-
sheet-like pattern. (c) Acylhydrazone-based cages generated by
condensation of hydrazide-functionalised ligands 131–134 with scaf-
fold 124. Homochiral ligands yield discrete, rigid cage 137, derived
from valine ligand 131, which adopts a partially open conformation
with outward-facing isopropyl groups and a solvent-accessible cavity;
138, assembled from Phe–Gly ligand 133, displays a more compact,
closed conformation with the peptide arms folding tightly to exclude
solvent. Both cages are stabilised by a continuous seam of 16 anti-
parallel hydrogen bonds, and only homochiral assembly is observed
due to the planar geometry of the hydrazone linkage. (d) Structural
features of monomer 139 employed in the formation of hydrogen-
bonded octameric cage 140. Molecule 139 consists of a central 1,3,5-
trisubstituted benzene ring bearing three cysteine residues. Each
cysteine sulphur is protected with a trityl group. SCXRD shows that all
trityl groups are oriented on the same face of the aromatic core,
enforcing a directional arrangement in which the three carboxylate
groups project outward from the opposite face. This spatial pre-
organisation facilitates cooperative hydrogen bonding and promotes
cage assembly. SCXRD of cage 140 assembled exclusively through
hydrogen bonding. Eight units of 139 form a spheroidal architecture
featuring 48 cooperative hydrogen bonds. The resulting structure
displays D2 symmetry with partially open pores at the equator and
poles, enclosing a central cavity of ∼1700 Å3. Colour code: peptide
backbone and aromatic scaffold = grey, N= blue, O = red, S = yellow,
hydrogen bonds = black.
3.4 Hydrogen-bond directed cages

Hydrogen bonding offers an alternative strategy for controlling
peptide-based cage architectures by guiding strand alignment
and registry within conned geometries. The pseudopeptidic
cages developed by Szumna and co-workers are constructed on
tetraformylresorcin[4]arene scaffolds (124) that present four
formyl groups arranged symmetrically around a concave
aromatic platform (Fig. 9a).75,105 These scaffolds provide a rigid
aromatic foundation capable of engaging multiple peptide-
derived ligands to form discrete cages in solution and in the
solid state. Two distinct types of dynamic covalent bonds have
been employed to assemble these structures. Imine bonds are
formed via condensation with amines, whereas acylhydrazone
bonds are formed via condensation with hydrazides (Fig. 9a).
The difference between these linkages has profound conse-
quences for congurational exibility, geometric adaptability
and self-sorting behaviour.

Imine bonds formed from resorcinols allow tautomerism
between enol–imine and keto–enamine forms. The aldehyde
groups of the resorcinarene scaffolds predominantly adopt an
enolic conguration, while the imine linkage itself can tauto-
merise locally. The keto–enamine tautomer locks the C]N
bond into a planar, rigid geometry coplanar with the aromatic
ring, whereas the enol–imine tautomer may adopt a non-
coplanar geometry. This tautomeric exibility allows structural
adaptation during self-assembly that can relieve steric strain
and optimise stacking or CH–p interactions, contributing to the
congurational plasticity that enables sequence-dependent
sorting behaviour.

The amino acid sequences selected for these studies were
carefully designed to test how peptide length, chirality, and
© 2026 The Author(s). Published by the Royal Society of Chemistry
side-chain functionality inuence self-assembly. In the imine-
linked series, alternating hydrophobic and hydrophilic resi-
dues such as phenylalanine and glycine were used to mimic b-
sheet-like hydrogen bonding motifs. These residues generate
Chem. Sci.



Chemical Science Review
amphiphilic strands capable of forming antiparallel arrange-
ments. For dipeptides, such as L-Phe–Gly–NHCH3 127 or its
enantiomer 128, sequence parity ensures alignment of
hydrogen-bond donors and acceptors without inversion of
strand orientation. Crystallographic analysis of homochiral
cage 135 revealed a symmetric architecture sealed by 12
hydrogen bonds (Fig. 9b). The structure displayed asymmetry at
the molecular level, where one hemisphere contained rigid
keto–enamine linkages coplanar with the resorcinarene core,
while the opposite hemisphere exhibited exible enol-imine
linkages with distorted geometries.75 This asymmetry reects
the dynamic adaptability conferred by imine tautomerism,
allowing the cage to minimise strain, while maintaining
a continuous hydrogen-bond network.

When tripeptides, such as L-Phe–Gly–L-Phe–NHCH3 (129),
were employed, a different behaviour was observed. The odd
number of residues necessitates an inversion of strand orien-
tation to preserve antiparallel hydrogen bonding between
hemispheres. This inversion can only occur through hetero-
chiral pairing. Solution-phase NMR indicated that racemic
mixtures of tripeptides 129 and 130 preferentially formed
heterochiral cage 136, with social chiral self-sorting behaviour,
as conrmed by SCXRD analysis. Analysis of 136 showed the
alternating strands of opposite handedness arranged in an
antiparallel fashion, and were stabilised by 24 hydrogen bonds
(Fig. 9b).75 These results establish a clear sequence-parity-
dependent sorting logic, in which homochiral dimers
predominate for even-numbered sequences, whereas hetero-
chiral dimers predominate for odd-numbered sequences,
driven by the geometric requirements of maintaining a contin-
uous antiparallel hydrogen-bond seam.

Acylhydrazone-linked cages exhibit behaviour distinct from
their imine-linked counterparts, owing to the geometric rigidity
imposed by the acylhydrazone bond. This bond adopts a trans
conguration around the N–N linkage and suppresses tautom-
erism, resulting in a planar, locked geometry that xes the
orientation of the appended peptide strands, constraining the
overall architecture. This rigidity eliminates the conformational
adaptability seen in imine-based cages, enforcing strict
requirements for stereochemistry and strand alignment during
self-assembly.

To investigate the implications of this rigidity, Szumna and
co-workers systematically examined peptide-derived hydrazide
ligands both as pure enantiomers and as racemic mixtures. The
rst system employed the L-(131) and D-(132) enantiomers of
a valine-derived hydrazide ligand (Fig. 9a). Solution-phase
experiments demonstrated that racemic mixtures yielded
exclusively homochiral cages, indicating that only assemblies
comprising identical enantiomers could satisfy the geometric
demands of this rigid framework (Fig. 9c). The crystal structure
of homochiral cage 137 (Fig. 9c) based on 131 provided struc-
tural insight into this behaviour. Structure 137 revealed
a symmetric architecture in which two cavitands are joined to
form a dimeric cage, sealed by a continuous seam of 16
hydrogen bonds arranged antiparallel around the cage
equator.105 The valine side chains projected uniformly outward
from the cage surface, consistent with minimising steric
Chem. Sci.
hindrance and solvent exposure. Notably, the internal cavity of
this cage was partially occupied by solvent molecules, reecting
a conformation where the peptide arms did not fully fold
inward to exclude the solvent completely.

A second ligand derived from the dipeptide Phe–Gly–NHNH2

was studied to assess the inuence of peptide length and
composition (Fig. 9a). When enantiomerically pure L-Phe–Gly–
NHNH2 (133) and D-Phe–Gly–NHNH2 (134) were employed,
narcissistic self-sorting occurred. SCXRD analysis of homo-
chiral cage 138 (Fig. 9c) derived by 133 showed that the cage was
sealed by a continuous seam of antiparallel hydrogen bonds.
However, in contrast to the valine cage, cage 138 adopted amore
tightly folded structure, fully closing the cavity and preventing
solvent occupancy. The crystal structure showed the peptide
backbones arranged precisely to align donors and acceptors,
while the phenyl side chains projected outward from the cage
surface. This observation highlights how increasing peptide
length and introducing aromatic side chains promotes greater
folding and compactness of the cage, even though the rigid
acylhydrazone geometry still dictates strict homochiral sorting.
Subsequent work further conrmed that similar behaviour can
be observed for ligands with longer peptide sequences, tri-
peptides and tetrapeptides.106

These examples demonstrate how dynamic covalent bond
types dictate structural exibility, sorting logic and respon-
siveness to environmental conditions. Imine-based cages
exhibit congurational adaptability, permitting sequence-
parity-dependent sorting, whereby homochiral cages are fav-
oured for even-numbered sequences and heterochiral cages for
odd-numbered sequences. Acylhydrazone-based cages, by
contrast, exhibit rigid geometries that enforce homochiral
assembly irrespective of sequence length and require templa-
tion for formation in polar solvents. Both architectures exploit
b-sheet-like hydrogen-bond motifs but differ in their tolerance
of sequence variation, geometric exibility, and environmental
polarity, illustrating the critical role of bond rigidity and peptide
design in determining cage structure and function.

One of the major challenges of these hydrogen-bonded cages
is their stability in competitive, polar solvents. Assembly in this
context can be promoted by using a hydrophobic template that
stabilises the supramolecular architecture. Szumna and co-
workers expanded their library of cages by using peptides con-
taining polar amino acids, such as glutamate and histidine, and
tetraformylresorcin[4]arene scaffolds functionalised with polar
(125) or charged residues (126) to promote hydrogen bonding
and water solubility. The introduction of hydrophobic guests,
such as C60, induces the formation of well-dened capsular
dimers even in the competitive media of water and DMSO.107

The X-ray crystal structure obtained for a valine-derived cage
provides a structural model for this family of assemblies,
revealing a cavity enclosed by peptide backbones arranged in an
antiparallel b-barrel-like conguration around the encapsulated
fullerene. In 2017, Stefankiewicz and Sanders reported an
octameric cage assembled exclusively through hydrogen
bonding, without the need for any template.76 The cage
comprises eight identical enantiopure 139 building blocks,
each consisting of a 1,3,5-trisubstituted benzene core bearing
© 2026 The Author(s). Published by the Royal Society of Chemistry



Review Chemical Science
three cysteine residues with thiol groups protected as trityl
derivatives. The presence of the bulky trityl groups improves
solubility in non-polar solvents and promotes cage stability by
creating a hydrophobic outer shell.

X-ray crystallographic analysis revealed that all trityl groups
were oriented on the same side of the benzene core, directing
the three carboxylate groups in the opposite direction (Fig. 9d).
The resulting cage 140 exhibits a spheroidal architecture with
approximate D2 symmetry, enclosing a large central cavity of
1719 Å3. The external surface is partially open, featuring four
small pores at the equator (∼7.3× 7.4 Å) and two larger pores at
the poles (∼7.4 × 8.7 Å), allowing selective guest access while
excluding larger species. The cage is stabilised by 48 cooperative
hydrogen bonds formed between the carboxylic acid groups and
amide NH groups of adjacent building blocks (Fig. 9d). The
internal hydrogen bond distances vary subtly depending on
their position. Two aromatic CH protons form relatively short
hydrogen bonds (∼2.3 Å), resulting in stronger shielding in the
1H NMR spectrum, while a third experiences a longer hydrogen
bond (∼2.4 Å) and correspondingly weaker shielding. Similar
asymmetry is observed for the amide NH protons, reecting the
geometric constraints imposed by the overall architecture.
Solution-phase NMR conrmed that this structure is retained in
apolar solvents such as tetrachloroethane, and diffusion-
ordered NMR spectroscopy (DOSY) provided a hydrodynamic
diameter of ∼18.2 Å, consistent with crystallographic dimen-
sions. The cage demonstrates thermal and chemical robust-
ness, remaining intact from −10 to 105 °C and requiring more
than 40 equivalents of triethylamine to disrupt the hydrogen-
bond network. This stability arises from the highly coopera-
tive nature of the hydrogen-bonding motif and the geometrical
constraints of the architecture.

Granja and colleagues reported another system of hydrogen
bonded capsules formed from two a,g-cyclic octapeptides
bearing zinc porphyrin caps attached via dynamic hydrazone
linkages. The cyclic peptide, containing alternating D-leucine
and (1R,3S)-3-aminocyclopentanecarboxylic acid residues, self-
assembles into dimers through hydrogen bonding to form the
capsule framework. The resulting C2-symmetric structure
recognises bipyridine guests through coordination to both zinc
centres, with optimal binding observed for ligands matching
the 15.8–16.6 Å interaction distance.108

These ndings exemplify how purely hydrogen-bonded
assemblies can achieve stability and selective guest encapsula-
tion. The system highlights the potential of cooperative
hydrogen bonding as a design principle for robust, preorgan-
ised nanostructures, and its architecture offers ample oppor-
tunities for further derivatisation or tuning, by varying the
peripheral cysteine residues or protecting groups.

4. Applications of peptide cages

The incorporation of peptides into cage-like supramolecular
structures enables a range of functional properties that have
motivated exploration across diverse application areas. Peptides
provide an extensive molecular toolkit to introduce and ne-
tune chemical functionality and physicochemical properties
© 2026 The Author(s). Published by the Royal Society of Chemistry
within otherwise rigid architectures. Their compatibility with
aqueous and biologically relevant environments has prompted
investigation in biomedical contexts, including targeted drug
delivery, gene therapy, biosensing, diagnostic imaging, and
therapeutic applications, although most studies to date remain
at a proof-of-concept level.

Peptides contribute molecular recognition elements through
hydrogen bonding, aromatic interactions, electrostatic forces,
and hydrophobic effects, which can be exploited for selective
guest binding, sensing, and environmental monitoring. Amino
acid side chains enable modulation of host-guest interactions
and environmental responsiveness, with ionisable residues
allowing pH-dependent behaviour in switchable systems rele-
vant to pathophysiological conditions. The incorporation of
chiral residues generates locally asymmetric environments that
may inuence molecular recognition, while peptide sequence
and composition affect structural rigidity or adaptability, with
consequences for guest loading, release behaviour, and inter-
actions with biological interfaces. Together, these properties
position peptide-incorporating cages as versatile platforms for
emerging applications in medicine, molecular diagnostics,
environmental sensing, and biotechnology while highlighting
the need for further development to translate structural design
into robust functional performance.
4.1 Drug delivery and ion-transport therapy

Pseudopeptidic tripodal cage 100, once protonated, was shown
to bind up to two chloride anions, enabling anion encapsula-
tion under acidic conditions. This capacity to encapsulate
chloride with high affinity under acidic conditions is appealing
for developing drug candidates that operate selectively within
the acidic microenvironments that are characteristic of solid
tumours. This behaviour arises from protonatable binding sites
within the cage framework. This property could open the way to
ion transport across cell membranes, disrupting cellular
homeostasis, affecting membrane potential, and modulating
intracellular pH, ultimately leading to cytotoxic responses.109

The authors expanded their cage library by exploring aromatic
amino acid variants, i.e., 4-F-phenylalanine (141), tyrosine (142),
O-Me-tyrosine (143), and tryptophan (144) (Fig. 10a).110 In these
systems, variation of the amino acid side chains modulates
hydrophobicity and membrane affinity while preserving the
underlying cage architecture.

The amino acid side chains critically inuence transport
efficiency through an H+/Cl− symport mechanism. Compound
141 exhibited superior chloride efflux rates (0.198% Cl per s at
pH 6.2) compared to unmodied 100 or 143, correlating with
increased hydrophobicity. NMR studies conrmed full lipid
phase incorporation while maintaining chloride-binding
capacity. Acidic conditions accelerated chloride exchange
rates from 0.2 s−1 at pH 7.4 to 2.7 s−1 at pH 6.2–6.5, enabling
selective activation in acidic tumour microenvironments.

This pH-responsive chloride transport capability offers
promising anticancer therapeutic applications, although
current evidence remains limited to cellular and in vitromodels,
through selective cytotoxicity in tumour microenvironments.
Chem. Sci.



Fig. 10 Peptide-functionalised cages for chloride transport, pH-
responsive cytotoxicity, and targeted delivery. (a) Representative
structure of the tripodal pseudopeptidic cage scaffold common to
compounds 141–144. The green spheres represent the aromatic
amino acid incorporated into each cage, which varies between 4-F-
Phe (141), Tyr (142), O-CH3-Tyr (143), and Trp (144). These side-chain
variations modulate the overall hydrophobicity and membrane inter-
action profile of the cages, thereby affecting their H+/Cl− co-transport
efficiency and pH-dependent cytotoxicity. (b) Schematic depiction of
pH-triggered H+/Cl− symport across phospholipid bilayers. The
reverse pH gradient characteristic of tumour microenvironments
enables selective chloride release inside cancer cells, inducing cyto-
toxicity via disruption of ion homeostasis. (c) Representative structure
of PdII2L4 cage 145 incorporating different peptide ligands (146–149),
denoted as green spheres. Ligands 146–149 display integrin-targeting
peptides such as cyclic RGD or a5b1-binding motifs, enabling selective
delivery of cisplatin into tumour cells. Ligand 150 incorporates the
PepH3 brain-penetrating peptide and enables the corresponding cage
to traverse the blood–brain barrier, achieving efficient delivery of
diagnostic or therapeutic payloads into neural tissue.

Chemical Science Review
Solid tumours exhibit a reverse pH gradient compared to
normal tissues, with neutral intracellular pH and a slightly
acidic extracellular environment.111 This enables the chloride-
encapsulated cage to pass through the membrane and selec-
tively release ions inside tumor cells (Fig. 10b). In human lung
adenocarcinoma (A549) cells, all cages exhibited enhanced
cytotoxicity as extracellular pH decreased from physiological
levels. Compound 141 showed a particularly striking pH-
dependent activity, with IC50 values decreasing from 166 ± 35
mM at pH 7.5 to 29 ± 4 mM at pH 6.2, a ve-fold enhancement in
cytotoxic potency. Additionally, 141 showed moderate cyto-
compatibility towards healthy cells at concentrations up to 150
mM. This selectivity reects the inuence of peptide side-chain
chemistry on activity under pathological conditions.

Beyond ion transport, bioconjugation of peptides to metal–
organic cages has emerged as a strategy for addressing
Chem. Sci.
challenges in cancer chemotherapy, particularly integrin
receptor overexpression and cisplatin resistance mechanisms.
In this context, peptides function as targeting and recognition
elements rather than as structural components of the cage
framework. Integrins avb3 and a5b1 are overexpressed in various
malignant tumours, facilitating tumour angiogenesis, invasion,
and metastasis.112 This overexpression represents a therapeutic
vulnerability exploitable for selective drug delivery. Simulta-
neously, a major clinical challenge is cisplatin resistance, which
is mediated through enhanced DNA repair mechanisms, altered
cellular uptake, and increased efflux pump activity.113

Encapsulation of cisplatin within metal–organic cages
decorated with targeting-motifs offers a potential solution by
protecting the drug from deactivation while delivering it selec-
tively to integrin-rich tumour environments. [PdII2L4]

8+ cage 145
(Fig. 10c) can be bioconjugated with different peptide-based
integrin-binding moieties (145–148), maintaining host-guest
chemistry while acquiring selectivity for specic cellular
targets.84 Here, the rigid aromatic scaffold denes cage geom-
etry, while peptide conjugation introduces biological specicity.
Multiple ligand units displayed on the cage scaffold resulted in
higher binding affinity than individual free ligands, with 146
demonstrating over a 3-fold improvement in avb3 selectivity
relative to the reference compound cilengitide.

Peptide conjugation did not compromise structural integ-
rity, as conrmed by 1H-NMR spectroscopy showing character-
istic downeld shis of a-pyridinyl protons upon metal
coordination. The peptide component ensures binding selec-
tivity through high-affinity recognition of overexpressed integ-
rin receptors. It also contributes to shielding the cage surface,
protecting encapsulated drugs from premature release during
circulation, and enables controlled release mechanisms that
respond to target tissue microenvironments.

Cage 146 (Fig. 10c), when loaded with cisplatin, exhibited
improvements in therapeutic selectivity. Cytotoxicity against
avb3-overexpressing A375 melanoma cells was enhanced 2.1-
fold, while showing no increased toxicity against avb3-negative
A549 cells. Mass spectrometry demonstrated signicantly
reduced platinum accumulation in healthy liver and kidney
tissues for encapsulated cisplatin compared to free drug (p #

0.01). These ndings suggest that the coordination complex
remained intact during biological transit, with the peptide
component providing selective targeting while the cage archi-
tecture shielded the platinum payload from non-specic inter-
actions. These results indicate that peptide-mediated targeting
modulates biodistribution while the cage architecture preserves
structural integrity and encapsulation.

The versatility of PdII2L4 cages was further demonstrated
through the functionalisation of a ditopic ligand with a brain-
penetrating peptide, PepH3 (149), to traverse the blood–brain
barrier (Fig. 10c).85 In this system, the peptide is employed as
a transport and targeting element, while the cage scaffold
preserves its coordination geometry and encapsulation prop-
erties. This selective physiological barrier prevents over 98% of
potential neurotherapeutics from reaching target sites. Cage
145 conjugated with 149 demonstrated superior translocation
© 2026 The Author(s). Published by the Royal Society of Chemistry



Review Chemical Science
efficiency across a blood–brain barrier model compared to the
un-conjugated cage.

The peptide-functionalised system achieved rapid brain
accumulation (t1/2 z 5 minutes), reaching 0.42 ± 0.06% injec-
ted dose per gram tissue in CD1 mice when encapsulating
[99mTcO4]

−, comparable to the free PepH3 peptide performance
(0.31 ± 0.07% ID per g). The biodistribution prole demon-
strated selectivity, with preferential brain accumulation over
peripheral organs. Minimal release of free pertechnetate was
evidenced by comparable activity levels in blood, stomach, and
thyroid, contrasting with typical accumulation patterns for free
[99mTcO4]

−. These results indicate that peptide conjugation
enables blood–brain barrier traversal without compromising
host–guest stability in vivo.
4.2 Biomolecular recognition and diagnostic imaging

The design of pseudopeptidic molecular cages has evolved into
sophisticated stereoselective receptors capable of recognizing
biologically-relevant peptide sequences. Here, peptide-derived
functionality is exploited to introduce complementary interac-
tion sites within preorganised cage cavities. The imine-based
cages developed by Alfonso's group showed good association
constants towards Cbz–Ala–Phe–OH as compared to macrocy-
clic hosts.101 ESI-MS screening revealed that structural pre-
organisation was crucial for efficient peptide recognition, with
a mechanism involving aromatic interactions between phenyl-
alanine residues and the cage cavity, complemented by
hydrogen bonding between carboxylate groups and amide
moieties. These studies identied clear preferences for dipep-
tides bearing aromatic residues at the C-terminus. The cage
obtained from precursor 110 (Fig. 8a) emerged as the most
efficient receptor, with binding constants reaching 417 M−1 in
competitive CD3CN/CD3OH media, highlighting the impor-
tance of cooperative noncovalent interactions, attributed to
additional hydrogen bonding capabilities of its serine hydroxyl
groups.

Subsequent research focused on the biologically relevant Ac–
Glu–Tyr–OH dipeptide, a target sequence for tyrosine kinases.102

These enzymes catalyse protein phosphorylation reactions
regulating signal transduction, cellular metabolism, and cell
cycle progression, with aberrant activity implicated in cancer
and metabolic diseases. A remarkable breakthrough was real-
ised through the demonstration of consistent stereoselective
recognition across all four stereoisomers of Ac–Glu–Tyr–OH.102

Cages obtained from 110 and 111 exhibited selectivity following
LL > DD $ LD > DL, with the naturally occurring LL stereo-
isomer binding with highest affinity (631 ± 45 M−1 for 110 in
aqueous acetonitrile). This behaviour underscores how cage
preorganisation and peptide functional group complementarity
together enable stereochemical discrimination, representing
a rare example of synthetic receptors achieving stereoselective
peptide recognition in competitive media, arising from cong-
urationally dependent cooperative interactions between gluta-
mic acid and tyrosine residues with the chiral cage framework.

This stereoselectivity was retained in gas-phase studies using
ESI-MS with enantiomer-labelled methods and collision-
© 2026 The Author(s). Published by the Royal Society of Chemistry
induced dissociation experiments, suggesting that polar inter-
actions, rather than hydrophobic forces, primarily govern
selectivity. Spectroscopic studies and molecular modelling
revealed a three-site binding mechanism involving carboxylate
coordination, aromatic encapsulation through stacking, and
acetyl group stabilisation. In this context, peptide side-chain
functionality plays a decisive role in dening binding mode
and selectivity, as the phenolic hydroxyl group of tyrosine
provides additional hydrogen bonding, explaining enhanced
binding compared to phenylalanine analogues.

Beyond peptide recognition within discrete host cavities,
peptide-derived stereochemical information has also been
exploited to programme the selective recognition of higher-
order nucleic acid architectures, demonstrating how pre-
organisation and chirality encoded in peptide frameworks can
be translated into macromolecular targeting.

In a conceptually distinct yet philosophically related
strategy, Vázquez and co-workers demonstrated that peptide-
derived ligands can encode stereoselective recognition of non-
canonical DNA structures through metallosupramolecular hel-
icates. Oligocationic peptide ligands incorporating heterochiral
b-turn sequences self-assemble with FeII or CoII ions into chiral
dinuclear helicates that bind three-way DNA junctions with sub-
micromolar affinity.54 The stereochemical information
embedded in the peptide sequence directs the formation of LL

or DD helicates, whose trigonal geometry and shape comple-
mentarity enable insertion into the hydrophobic cavity at the
DNA junction branch point, assisted by electrostatic interac-
tions with the phosphate backbone. Rhodamine-labelled FeII
helicates were shown to internalise into living cells and selec-
tively localise at DNA replication foci, providing the rst
designed uorescent probes capable of visualising three-way
DNA junctions in cellulo. Building on this platform, the same
group subsequently introduced redox-active CuII peptide heli-
cates, yielding the rst chemical nuclease displaying selective
cleavage of three-way junctions both in vitro and in mammalian
cells.53 Mechanistic studies implicated a reactive oxygen species
mediated pathway consistent with metal-centred superoxide
formation, while TUNEL assays in synchronised cells conrmed
selective DNA damage at replication foci. Collectively, these
studies highlight how peptide-encoded stereochemistry, pre-
organisation, and metal coordination can be combined to
achieve selective recognition and reactivity towards transient
biological DNA architectures.
4.3 Molecular separation and environmental remediation

Suitably designed peptides can display the useful ability to self-
assemble into gelling nanostructures, with sequences as short
as 2–3 amino acids peptides creating robust hydrogels through
hierarchical assembly processes.114 These minimalistic gelators
form brillar networks that trap large solvent volumes, creating
somaterials with tuneable mechanical properties and stimuli-
responsive behaviours.115 Gelation is driven by non-covalent
interactions including hydrogen bonding, aromatic stacking,
and electrostatic interactions, modulated by pH, temperature,
and ionic strength.116 Peptide gels show compatibility with
Chem. Sci.



Chemical Science Review
metal ions, where metal coordination inuences gel formation,
stability, and mechanical properties.117–119

The combination of peptide gels with metal–organic cages
creates hierarchically organised, dual-porosity so materials.120

As shown in Fig. 11a, embedment of [FeII4L4]
8+ cages within

supramolecular tripeptide gels enables spatial separation of
different molecular guests through selective encapsulation
during diffusion. This hierarchical assembly exploits both
mesoscopic gel network pores and cage cavities for selective
guest entrapment, offering distinct pore sizes and physico-
chemical properties for controlled molecular transport and
separation.121 An additional advantage is the increased cage
stability against acid-mediated hydrolysis in the presence of the
peptide gel matrix.

Recent developments produced cages 90–92 (Fig. 11b)
whereby typical aniline peripheral ligands122 have been
substituted with PABA–L-Phe–D-Cys–L-Phe–NH2, PABA–L-Phe–D-
Phe–L-Cys–NH2, or PABA–L-Phe–D-Met–L-Phe–NH2 that
Fig. 11 Schematic illustration of the dual supramolecular system
combining a self-assembling tripeptide hydrogelator and two discrete
tetrahedral FeII4L4 cages. (a) The tripeptide PABA–L-Phe–D-Ala–L-
Phe–NH2 (150) undergoes hierarchical self-assembly into fibrillar
networks that entrap solvent molecules, forming a viscoelastic gel.
Within this matrix, two chemically distinct MOCs (152 and 155) are
incorporated without disrupting gelation. (b) A layered peptide gel
spatially confines the cages while preserving their intrinsic molecular
recognition properties. Each cage exhibits orthogonal guest selectivity
in acetonitrile, binding ReO4

− (for 152) and fluoroadamantane (for
155), respectively. (c) Cage 90 undergoes gelation through coordi-
nation of the thiols of the Cys to a second external metal ion, i.e., Ag+,
Zn2+, or Hg2+ (white spheres). The gel matrix forms through a two-
phase kinetic process, producing spherical nuclei whose size and
mechanical properties depend on the metal ion. Colour code for
rendered structures: peptide backbone and aromatic scaffold =

grey, N = blue, O = red, S = yellow, Fe = magenta, Ag, Zn, and Hg =

light grey, F = light green.

Chem. Sci.
incorporate peripheral cysteine or methionine residues. In
these systems, peptide sequence and residue positioning
directly inuence supramolecular behaviour. Interestingly,
gelation was attained only for cage 91 upon exposure to Ag+,
Zn2+, or Hg2+ ions through thiol-metal coordination.70 A likely
explanation is the limiting steric hindrance of the coordinating
Cys/Met in cages 90 and 92, which feature such amino acids in
the central position of the peptide sequence. Rheological
characterisation of the gels obtained from cage 91 revealed
variable gel stiffness from 1.6 kPa (Ag+) to 3.9 kPa (Hg2+),
reecting different metal–sulfur coordination affinities. The
gelation process exhibits distinctive two-stage kinetics: an
initial lag phase followed by rapid matrix formation. Silver ions
display the longest nucleation phase, forming larger spherical
nuclei, while zinc and mercury promote faster gelation with
smaller nuclei. A direct morphology–kinetics correlation is thus
established, where extended lag phases favour the formation of
larger nuclei and stronger coordination accelerates network
development. The resulting materials exhibit spherical nuclei
interconnected within the gel matrix, contrasting with typically
brillar networks arising from the self-assembly upon oxidation
of similar peptide sequences in the absence of cages.123 The
same oxidative approach to crosslink the cysteine residues of
cages 90 or 91 through disulde bridges did not lead to gelation,
further highlighting the constraints in their supramolecular
behaviour when self-assembling tripeptide motifs are bound at
the cage vertices.70 Nevertheless, the metal-triggered gelation
may enable promising environmental applications, particularly
heavy metal remediation, through selective coordination to
peripheral cysteine residues.

Environmental remediation represents an arena in which
peptide cages excel. Beyond metal ion capture, they bear the
potential to address critical water contaminants, such as
hydrocarbons. Cage 106 (Fig. 11c) demonstrates remarkable
selectivity for NaF in aqueous environments, with binding
affinities of 3.08 × 103 M−1, achieved through an atypical
entropy-driven endothermic mechanism.72 This anti-
Hofmeister behaviour distinguishes these systems from
conventional anion-binding receptors. The cage structural
exibility accommodates highly hydrated uoride ions without
requiring signicant desolvation, while maintaining selectivity
over other halides. SCXRD analysis revealed highly hydrated
binding pockets where water molecules participate in hydrogen
bonding networks with encapsulated uoride anions.

A variant of cage 106 with ligand 103 substituted with
a cyclohexyl group demonstrated exceptional efficacy in
removing per- and polyuoroalkyl substances (PFAS) from
contaminated water. Batch equilibrium experiments showed
70–80% removal of peruorooctanoic acid (PFOA) within ten
minutes at 1 mg L−1, reaching completion within six hours. At
higher concentrations (50 mg L−1), the system achieved 95%
removal efficiency within four hours. A Langmuir isotherm
model yielded an affinity coefficient of 2.8 × 105 M−1 and
maximum capacity of 19.99 mg g−1. The cage maintained
selectivity for uorinated compounds over non-uorinated
analogues, with PFOA removal exceeding 97%, while octanoic
acid removal remained at 20% under identical conditions. The
© 2026 The Author(s). Published by the Royal Society of Chemistry



Review Chemical Science
system demonstrated resilience in natural water, maintaining
effective PFAS capture despite the presence of organic matter.

Noteworthily, the applications described throughout this
section arise exclusively from hybrid peptide-aromatic cages.
Such cages derive their functionality from rigid aromatic cores
that provide structural stability and preorganisation, while
peptide components are incorporated to introduce chemical
functionality, responsiveness, and selectivity. This division of
roles enables molecular recognition across chemically diverse
targets, ranging from therapeutic agents to environmental
pollutants. Extension of such recognition to polar biomolecules
in aqueous media represents the next step. These cages create
multivalent interfaces, where peptide units generate selectivity
for biological targets such as integrin receptors, although
broader validation across different receptor classes remains
limited. Furthermore, heterochirality may generate asymmetric
binding surfaces for greater target discrimination. Environ-
mental responsiveness enables pH-triggered ion transport and
metal-induced gelation, demonstrating how peptide compo-
nents confer adaptive behaviour. Incorporation of enzymatic
triggers or redox-sensitive elements would expand this func-
tional repertoire. Peptide-metal coordination produces mate-
rials with tuneable mechanical properties for biomedical
applications, where reversible crosslinking strategies might
yield self-healing characteristics. By contrast, the purely
peptidic cages from Section 2 lack these features. Most of these
assemblies employ homochiral sequences with limited side-
chain diversity, reecting a focus on geometric validation
rather than functional design. This emphasis on structure has
naturally preceded the emergence of application-oriented
studies. The design principles underlying hybrid cage func-
tionality illustrate a possible pathway towards purely peptidic
architectures to transition from proof-of-concept structures to
functional platforms capable of molecular recognition, targeted
delivery, and stimuli-responsive assembly.
5. Conclusions and future
perspectives

The exploration of peptide-based supramolecular cages has
highlighted two distinct yet overlapping and complementary
structural design strategies, each with unique advantages and
inherent limitations. Purely peptidic cages, constructed entirely
from peptide sequences, capitalise on intrinsic conformational
preferences and metal coordination to form intricate topolog-
ical motifs, such as knots, catenanes, and interlocked struc-
tures. These architectures exhibit a high level of complexity and
topological precision, rivalling natural protein assemblies.
Despite their sophisticated designs, purely peptidic cages
encounter challenges that can include limited aqueous stability
and stringent assembly conditions, typically requiring organic
solvents or precisely controlled environments. Consequently,
their applications so far remain linked to structural elucidation
rather than functional exploitation.

In contrast, hybrid peptide-aromatic cage systems combine
rigid aromatic frameworks with peptide functionalities, offering
© 2026 The Author(s). Published by the Royal Society of Chemistry
structural robustness and modularity. This approach enables
the systematic ne-tuning of properties through targeted amino
acid modications, broadening the practical applicability of
such cages. These hybrid systems have found uses in areas such
as drug delivery, selective molecular recognition, and environ-
mental remediation. However, they are not without drawbacks.
Their synthetic complexity and the potential metabolic insta-
bility of their aromatic scaffolds, combined with challenges in
scalability, may present obstacles to implementation.

Several key design principles emerge from an analysis of
both approaches, although the eld remains at an early stage
and the extraction of general, predictive rules is still chal-
lenging. The structure–function relationships that we elucidate
herein should be thus interpreted as emerging trends rather
than universally established design principles. The careful
incorporation of diverse amino acid side chains and the stra-
tegic use of heterochirality have enabled selective molecular
recognition and stereochemical control of cage cavities in
specic systems. Additionally, the development of stimulus-
responsive features, including pH-sensitive behaviours, metal-
triggered structural rearrangements, and adaptive guest
binding, has enriched the functional landscape of peptide-
based cages. These properties underscore the inherent
complementarity between purely peptidic and hybrid cage
design strategies, suggesting that future advances will likely
integrate the strengths of both approaches.

A promising avenue thus involves merging the versatility of
peptide backbones with the geometric precision provided by
preorganised scaffolds. This hybrid strategy may reduce
entropic penalties associated with self-assembly, while
preserving the functional diversity inherent in peptides. Intro-
ducing non-natural building blocks, such as b-amino acids or
peptoids, provides a robust approach to impose conformational
constraints at the monomeric level.124–128 These residues may
stabilise ordered structures without compromising biocom-
patibility, although their broader impact on assembly and
function remains to be systematically assessed. Selecting these
components involves carefully balancing structural rigidity,
aqueous solubility, and potential immunogenicity to ensure
optimal performance in biological contexts.

The introduction or alteration of stereogenic centres allows
the exploration of a broader range of supramolecular architec-
tures. Moreover, stereochemical differentiation provides an
effective strategy to independently modulate backbone geom-
etry and functional group orientation, thereby enhancing
structural control and specicity.18

By analysing natural peptide sequences and microdomains,
researchers can isolate critical minimal motifs that promote
targeted folding or molecular recognition. Incorporating these
minimalist motifs into larger synthetic architectures stream-
lines the design process and leverages functionalities optimised
through evolutionary selection.129–131

Advances in modular functionalisation using bioorthogonal
chemistries have the potential to further enhance the versatility
of peptide-based cages. Click-chemistry reactions, inverse-
electron-demand Diels–Alder cycloadditions, and other bi-
oorthogonal methods facilitate rapid and selective conjugation
Chem. Sci.



Chemical Science Review
of diagnostic probes, therapeutic agents, or catalytic sites.132–134

Such late-stage functionalisation allows iterative optimisation
without necessitating complete resynthesis of the peptide
scaffold.

Finally, given the current youth and heterogeneity of the
eld, computational approaches such as molecular dynamics
simulations and data-driven methods including machine
learning should be regarded as long-term opportunities rather
than immediate solutions. At present, the limited availability of
consistent experimental datasets and validated computational
models restricts their direct application to peptide-based cages.
Nevertheless, conceptual guidance may be drawn from related
areas, particularly protein folding and protein cage assemblies,
where extensive experimental and computational studies have
enabled the identication of stabilising motifs and assembly
pathways.135–137 As the eld matures and more systematic
structure–property data become available, these approaches
may support hypothesis-driven design and prioritisation of
candidate sequences, complementing chemically informed
strategies rather than replacing them.138,139 Together, these
strategies promise to propel peptide-based supramolecular
cages beyond current constraints, enabling new opportunities
for practical applications.

Author contributions

SA: writing – original dra, visualisation. HX: writing – original
dra, visualisation. JRN: conceptualisation, project adminis-
tration, writing – review and editing. SM: conceptualisation,
project administration, writing – review and editing.

Conflicts of interest

There are no conicts to declare.

Data availability

No primary research results, soware, or code have been
included, and no new data were generated or analysed as part of
this review.

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Chem. Sci.


	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications

	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications

	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications

	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications
	Peptide cages: bioinspired supramolecular architectures for next-generation applications