Article https://doi.org/10.1038/s41467-023-41907-1

Hierarchical assembly of tryptophan zipper
peptides into stress-relaxing bioactive
hydrogels

Ashley K. Nguyen1,2, Thomas G. Molley1,2,3, Egi Kardia4,5,6, Sylvia Ganda1,2,
Sudip Chakraborty1, Sharon L. Wong4,5,6, Juanfang Ruan 7, Bethany E. Yee1,2,
Jitendra Mata 1,8, Abhishek Vijayan4,5,9, Naresh Kumar1, Richard D. Tilley 1,7,
Shafagh A. Waters2,4,5,6,10 & Kristopher A. Kilian 1,2,3,6

Soft materials in nature are formed through reversible supramolecular
assembly of biological polymers into dynamic hierarchical networks. Rational
design has led to self-assembling peptides with structural similarities to nat-
ural materials. However, recreating the dynamic functional properties inher-
ent to natural systems remains challenging. Here we report the discovery of a
short peptide based on the tryptophan zipper (trpzip) motif, that shows
multiscale hierarchical ordering that leads to emergent dynamic properties.
Trpzip hydrogels are antimicrobial and self-healing, with tunable viscoelasti-
city and unique yield-stress properties that allow immediate harvest of
embedded cells through a flick of the wrist. This characteristic makes Trpzip
hydrogels amenable to syringe extrusion, which we demonstrate with exam-
ples of cell delivery and bioprinting. Trpzip hydrogels display innate bioac-
tivity, allowing propagation of human intestinal organoids with apical-basal
polarization. Considering these extensive attributes, we anticipate the Trpzip
motif will prove a versatile building block for supramolecular assembly of soft
materials for biotechnology and medicine.

Natural extracellular matrices are composed of a meshwork of multi-
ple proteins with an interconnected and hierarchical structure that are
ideal for guiding tissue assembly. However, the in vitro use of these
matrices is hampered by batch-to-batch variability and concerns of
immunogenicity1,2. Thus, the discovery of synthetic alternatives
remains a principal goal for cell biologists and tissue engineers. In
pursuit of this, hydrogels comprised of self-assembling synthetic
peptides have attracted broad interest due to the uniformity of

starting material, ease of synthesis, biodegradability, and low
cytotoxicity3–5. These synthetic hydrogelators have been designed to
form entangled networks of peptide nanofibers that mimic the struc-
tural characteristics of native matrices, including mesh size, pore size,
and nanofiber architecture6,7.

New peptide hydrogelators are commonly designed via functio-
nalization of ultra-short hydrophobic peptides (2–5 residues), with
large N-terminal capping groups that favor self-assembly through pi-

Received: 10 March 2023

Accepted: 22 September 2023

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1School of Chemistry, University of New South Wales, Sydney, NSW 2052, Australia. 2Australian Center for Nanomedicine, University of New South Wales,
Sydney, NSW2052, Australia. 3School ofMaterials Science and Engineering, University of NewSouthWales Sydney, Sydney, NSW2052, Australia. 4School of
Biomedical Sciences, Faculty ofMedicine andHealth, University of NewSouthWales, Sydney, NSW2052, Australia. 5Molecular and IntegrativeCystic Fibrosis
Research Centre (miCF_RC), University of New South Wales, Sydney, NSW 2052, Australia. 6School of Clinical Medicine, Faculty of Medicine and Health,
University of New SouthWales, Sydney, NSW 2052, Australia. 7Electron Microscopy Unit, MarkWainwright Analytical Centre, University of New SouthWales,
Sydney, NSW2052, Australia. 8AustralianCentre for Neutron Scattering, AustralianNuclear Science and TechnologyOrganization, LucasHeights, NSW2234,
Australia. 9School of Biotechnology and Biomolecular Sciences, University of New South Wales, Sydney, NSW 2052, Australia. 10Department of Respiratory
Medicine, Sydney Children’s Hospital, Randwick, NSW 2031, Australia. e-mail: k.kilian@unsw.edu.au

Nature Communications |         (2023) 14:6604 1

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http://orcid.org/0000-0001-8994-5235
http://orcid.org/0000-0001-8994-5235
http://orcid.org/0000-0001-8994-5235
http://orcid.org/0000-0001-8994-5235
http://orcid.org/0000-0001-8994-5235
http://orcid.org/0000-0001-9225-7900
http://orcid.org/0000-0001-9225-7900
http://orcid.org/0000-0001-9225-7900
http://orcid.org/0000-0001-9225-7900
http://orcid.org/0000-0001-9225-7900
http://orcid.org/0000-0003-2097-063X
http://orcid.org/0000-0003-2097-063X
http://orcid.org/0000-0003-2097-063X
http://orcid.org/0000-0003-2097-063X
http://orcid.org/0000-0003-2097-063X
http://orcid.org/0000-0002-8963-9796
http://orcid.org/0000-0002-8963-9796
http://orcid.org/0000-0002-8963-9796
http://orcid.org/0000-0002-8963-9796
http://orcid.org/0000-0002-8963-9796
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stacking interactions8. Peptide amphiphiles are another class of gela-
tors, relying on an arrangement of hydrophobic and hydrophilic
domains to drive self-assembly9,10. Self-complementary ionic gelators
are typically formed from longer peptides (8–16 residues) with alter-
nating charged amino acids that self-assemble through electrostatic
interactions11. Alternative approaches involve rational design of pep-
tide sequences that imitate naturally occurring secondary protein
structures, such as the alpha helix12 or beta sheet13. Despite extensive
research into supramolecular peptide assembly, the discovery of new
hydrogelators is most often driven by serendipity or permutation of
pre-existing gelator sequences.

A relatively unexplored assembly motif is the tryptophan zipper
(Trpzip). This motif is characterized by four cross-strand tryptophan
residues that interlock via the indole rings, folding the peptide into a
beta hairpin conformation14. As a result of this highly stabilizing zipper
effect, beta hairpins can be formed from Trpzip peptides that are as
short as twelve amino acids. This is considerably shorter than pre-
viously reported beta hairpin hydrogelators, such as MAX peptides,
which rely on the tetrapeptide (-VDPPT-) unit and lengthier sequences
(>20 amino acids) to maintain a folded hairpin structure15. Previous
work has shown the promise of tryptophan as a building block for self-
assembled hydrogels; however, these systems still rely on the com-
bined use of other non-natural hydrophobicmoieties (e.g., benzene or
naphthyl residues)16,17 or conventional peptide gelator motifs (e.g.,
diphenylalanine) to help drive gelation18. Although Trpzip sequences
have only been shown to assemble into nanofibers over the course of
several weeks19, its potential as a new self-assembling structural motif
is evident. However, the Trpzip peptidemotif has not yet been used to
form hydrogels.

In thiswork,weutilizedmolecular dynamics simulations todesign
a peptide hydrogelator basedon theTrpzipmotif. Our Trpzippeptides
undergo hierarchical assembly within minutes, first forming long
nanofibers, followed by assembly into microscale domains with peri-
odic architecture. The resulting hydrogel showed thermoresponsive
gelation with tunable modulus, self-healing, and stress-relaxing char-
acteristics, cell viability and spreading even without cell adhesion
motifs, and antimicrobial activity. Adding short adhesion peptides
have minimal effect on the mechanical properties of the hydrogel and
adding extracellularmatrix proteins such as laminin enabled culture of
adult stem cell and induced pluripotent stem cell derived intestinal
organoids. The low yield-strain of the material facilitates rapid fluidi-
zation under shear, providing a simple mechanism to retrieve
embedded cells and tissue and to disperse cell-laden Trpzip gels via
syringe towards cell delivery and bioprinting applications.

Results and discussion
Computational screening identifies self-assembling tryptophan
zipper variants
The Trpzip peptide motif has enabled the synthesis of the shortest
reported beta hairpins to date (Fig. 1a)14. Originally designed for
studying the thermodynamics of protein folding, minor changes in
Trpzip peptide sequences have been shown to drastically alter
aggregation and nanofiber formation (Fig. 1b). Markiewicz et al. pro-
posed that the positively charged lysine residue in the eighth position
acted as an aggregation gatekeeper by preventing peptide monomer
association through repulsive forces19. To test this hypothesis, we ran
coarse-grain molecular dynamics (MD) simulations of Trpzip variants
using all twenty canonical amino acids, with the prediction that small
uncharged residues in place of lysine may be most likely to facilitate
nanofiber formation.

MD simulations were run for all twenty Trpzip1 peptide variants,
and the last frame of each simulation were visually assessed (Fig. 1c).
Comparing all variants by extracting the largest peptide aggregate
fromeach simulation and aligning themon the sameaxis,we found the
valine substitution showed the largest difference between aggregation

modes compared to the original sequence (Fig. 1d), which we named
Trpzip-V. Quantifying the moments of inertia of the largest peptide
clusters for all twenty variants confirmed the valine-substituted variant
formed large aggregates the most fibrous in morphology, while
Trpzip1 formed small spherical aggregates (Fig. 1e). Backmapping to
all-atom resolution similarly indicated aggregation of Trpzip-V
monomers formed fibrillar nanostructures (Supplementary Fig. 1).

Hydrogel assembly arises from multiscale hierarchical order
Next, we synthesized Trpzip-V to experimentally assess its potential
for self-assembly under physiological conditions (Supplementary
Fig. 2). Trpzip-V was able to form a gel under both acidic and basic pH
conditions (Supplementary Fig. 3a) but precipitated out of solution at
neutral pH. We attributed the loss in solubility at neutral pH to be due
to the peptide’s isoelectric point of 6.97. Therefore, a second variant
was designed with an uncharged glutamine residue to replace the
negatively charged glutamic acid (Trpzip-QV; Fig. 2a). This new variant
has an overall charge of +1 at pH 7 to enable solubility at neutral pH
(Supplementary Fig. 3b). After overnight incubation at 37 °C in pure
water, Trpzip-QV (0.1% w/v) formed a self-supporting hydrogel while
Trpzip1 remained liquid (Fig. 2a). Circular dichroism (CD) spectro-
scopy confirmed Trpzip-QV still folds into a beta hairpin, as evidenced
by the positive band at 228 nm, which is indicative of tryptophan’s
indole rings packing into a hairpin conformation (Fig. 2b). Addition-
ally, Trpzip-QV showed a higher level of aggregation after 24 h com-
pared to Trpzip1, as revealed by a lower CD signal at 228 nm, which is
correlated with the reorganization of the peptide hairpin into fibrillar
aggregates20,21. For simplicity, Trpzip-QV will be referred to as Trpzip
hereafter.

To understand the mechanism behind gelation, we performed
transmission electronmicroscopy (TEM), which revealed an entangled
network of fibrillar nanostructures, approximately 4.12 ± 1.03 nm in
diameter (Fig. 2c; Supplementary Fig. 4). To visualize the nanos-
tructures under hydrated conditions, Trpzip gels were imaged over
24 h using cryo-TEM, demonstrating gradual assembly and elongation
of nanofibers (Fig. 2d; Supplementary Fig. 5). Additionally, Fourier
transform infrared (FTIR) spectra showed prominent peaks in the
Amide I (1600–1800 cm−1) and Amide II (1500–1600 cm−1) regions
(Supplementary Fig. 6), suggesting gelation is driven by beta sheet
aggregation of the Trpzip monomers, consistent with the aggregation
modes for other beta hairpin gelators reported22.

To further probe the self-assembly pathway of Trpzip hydrogels,
we performed small angle neutron scattering (SANS). The data was
fitted initially with the shape-independent power-law model, which
revealed the slope in the high Q region was –2 (Fig. 2e; far left). This
suggested the formation of lamellae or disc-shaped particles on the
order of 1–10 nm. The slope in the low Q region was found to be −3.7,
indicating the formation of large mass fractal-like aggregates exceed-
ing 500nm in size. These large fractal aggregates continue to increase
in size over the course of seven days, as indicated by the decrease in
slope in the low Q region. This was further confirmed by ultra-small
angle neutron scattering (USANS) measurements (Supplementary
Fig. 7). Datafitting to a lamellaemodel indicates the size of the lamellae
particles is approximately 2.2 nm. At higher hydrogel concentrations
(3% w/v), a decrease in intensity in the high Q region indicates the
assembly of larger fractal aggregates (Fig. 2e; center left). The scat-
tering profile of Trpzip gels fit well with a combination of the lamellae
model in the high Q region and the power law fit in the low Q region
(Fig. 2e; center right and far right), as further confirmation of the
presence of both nanometer-scale lamellae particles and micrometer-
scale fractal aggregates.

To explore the microscale assembly, we performed scanning
electron microscopy (SEM). Gelation at basic pH produced a highly
homogenous network of lamellae stacks, with fibrillar nanostructures
on the order of a few nanometers comprising this meshwork (Fig. 2f;

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 2



Supplementary Fig. 8). Upon balancing to neutral pH, this highly
organized, discrete honeycomb network is disrupted, and the result-
ing gel network is reformed through entanglement of more irregularly
shaped nanofibers. Based on the combined findings, we propose
Trpzip-QV peptides self-assemble into hydrogels via the following
mechanism. Peptide monomers fold into a beta hairpin conformation
and assemble into a disc/ellipsoidal-shaped particle, as suggested by
SANS. These particles stack via peptide backbone interactions to cre-
ate nanofibers, aligning to create a meshwork of lamellae stacks which
give rise to the macro-scale order (Fig. 2g).

Trpzip hydrogels show tunable mechanics with self-healing and
stress relaxation
To evaluate the mechanical properties of Trpzip hydrogels, we per-
formed in situ oscillatory parallel plate rheometry on gels at various
peptide concentrations. The stiffness of Trpzip hydrogels increased

with peptide content, withG’ values ranging from 1–60 kPa and all gels
reaching an equilibrium storage modulus after approximately 12 h
(Fig. 3a). Trpzip gels display temperature-dependent gelation beha-
vior, with a ten-fold higher stiffness at 37 °C compared to 20 °C
(Fig. 3b). Surprisingly, the yield point of Trpzip gels occurs at a shear
stress of approximately 75 Pa (Fig. 3c). This is consistent with our
observations of rapid fluidization of the gel under moderate force
(Supplementary Video 1). The Trpzip gel also shows shear-thinning
behavior (Fig. 3d), with viscosity decreasing linearly in proportion to
the shear rate, suggesting it may be an ideal biomaterial for extrusion
and biofabrication. Since other peptide hydrogels can reversibly
assemble and disassemble their physically crosslinked networks22, we
performed a thixotropic test on Trpzip gels to determine how fast they
self-heal and recover after shear. After exposure to 5% strain for 5min,
the hydrogels re-crosslink immediately upon cessation of shear forces,
returning to the initial stiffness within an hour (Fig. 3e). A frequency

Serine Proline

Alanine Valine

c Original Trpzip1
S W T W E G N K W T W K

Trpzip-V Variant
S W T W E G N V W T W K

d

a

Trpzip-VTrpzip1e

b

Trpzip1
SWTWEGNKWTWK

Trpzip2
SWTWENGKWTWK

No peptide 
nanofibers

+

+ Peptide 
nanofibers

Fig. 1 | Coarse-grain molecular dynamics simulations to identify Trpzip
sequences prone to nanofiber aggregation. a Cartoon representation of the
tryptophan zipper folded in a beta hairpin conformation, with interlocking tryp-
tophan residues depicted. b Schematic demonstrating the role of lysine as an
aggregation gatekeeper in Trpzip1 and Trpzip2, and the effect of successful
aggregation gatekeeping on the nanofiber-forming ability of the peptides.
c Results of coarse-grain simulations run for Trpzip variants with serine, proline,

alanine, or valine in the place of the eighth lysine residue present in the original
Trpzip1 sequence. d Comparison of coarse-grain simulations run for the original
Trpzip1 and Trpzip-V variant. Center boxes show the largest cluster of peptides
extracted from each simulation and aligned on the same axis for visual comparison
of size, length, and fibril morphology of peptide aggregates. eMoments of inertia
were calculated for all variants generated using the twenty canonical amino acids.

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 3



amplitude sweep test confirmed the frequency used for all oscillatory
tests (1 Hz) was well within the linear viscoelastic region (Supplemen-
tary Fig. 9). Additionally, we found Trpzip gels could also be prepared
in pure water, with gelation triggered through the addition of phy-
siological buffers or cell culture media upon mixing. Interestingly, the
stiffness of gels formed with this method at half the concentration
(0.5% w/v) approximated the stiffness of gels formed using the pH
trigger method (1% w/v; Supplementary Fig. 10).

One of the important aspects of natural tissues is their ability to
show non-linear viscoelastic properties like stress-relaxation, essen-
tial in distributing cellular forces generated during tissue expansion
and morphogenesis. To assess whether Trpzip gels possess a similar
stress relaxation profile, we performed constant shear deformation
measurements (Fig. 3f) and compared the stress relaxation half-time
of Trpzip gels (1% w/v) to the natural matrix Matrigel and poly-
ethylene glycol dimethacrylate (PEG-DM) hydrogels. Unsurprisingly,
PEG-DM exhibited little stress relaxation due to its covalently cross-
linked network; however, due to their dynamic nature, Trpzip gels
show a similar stress-relaxation profile to Matrigel. We found the
stress relaxation half-time of Trpzip gels to be lower (58.5 ± 0.4 s)
compared to Matrigel (87.1 ± 0.76 s) (Fig. 3g), but within the range of
other natural matrices23. Another important aspect of natural mate-
rials is the presence of cell adhesion motifs. We examined the effect
of appending the laminin-derived Ile-Lys-Val-Ala-Val (IKVAV) adhe-
sion motif onto our Trpzip hydrogels. Integrating Trpzip–IKVAV
(200 μΜ) into a Trpzip gel resulted in no statistically significant
change in stiffness compared to pure Trpzip gels (Fig. 3h). This

suggests that decoupling materials parameters such as stiffness and
adhesivity in Trpzip gels is possible.

Trpzip hydrogels are antimicrobial and supportmammalian cell
growth
We next investigated the ability of Trpzip hydrogels to support
mammaliancell growth. The lowyield point of Trpzip gels enables cells
to be easily resuspended after adjustment to neutral pH, circumvent-
ing the need for large pH switches common to peptide-based
hydrogels24. We encapsulated human fetal fibroblasts (HFFs) in
Trpzip hydrogels and observed their viability after five days to be
comparable to cells grown on tissue culture plastic (Fig. 4a, b). Cells
exhibited spreading and elongation in Trpzip hydrogels in the absence
of exogenous ECM proteins or adhesive peptide motifs, likely due to
the positively charged nature of the material. To explore this further,
we encapsulated HFFs in both Trpzip gels and Fmoc-GFF gels, another
bioinert peptide hydrogel (Fig. 4c)25. Cells grown in Trpzip and Fmoc-
GFF gels were initially similar in size on day 1, however, cells in Trpzip
gels doubled in area after 7 days compared to those grown in Fmoc-
GFF gels (Fig. 4d; 23.7% increase). Cellular aspect ratio and cellular
roundness also increased a greater amount for cells grown in Trpzip
gels compared to Fmoc-GFF gels by day 7 (Supplementary Fig. 11a, b).
Strikingly, cells in Trpzip gels show similar morphology to cells cul-
tured in Matrigel after seven days (Supplementary Fig. 12a–d), and the
hydrogel itself remains completely intact after one month of culture
(Fig. 4e; Supplementary Fig. S13a–c). In addition, we culturedmyoblast
progenitor cells (C2C12s) in Trpzip gels for one month, and similarly

bTrpzip1

Trpzip-QV

Valine

Glutamine

a Glutamic acid

Lysine
Trpzip1 Trpzip-QV

Trpzip1

Trpzip-QV

SWTWEGNKWTWK

SWTWQGNVWTWK

c

pH 14 pH 7

f

200 220 240 260

-20

0

20

40

Wavelength (nm)

C
D

 (m
de

g)

Trpzip1

Trpzip-QV
0ºC
20ºC

40ºC
60ºC

g

d 30 s 24 h

Trpzip peptide

Nanoscale
particle

Lamellae
stacking

Microscale fiber 
entanglement

Macroscale 
hydrogel

10-3 10-2 10-1 100

10-4

10-2

100

102

104

q (Å-1)

1 wt% at 0 h

Lamellae Fit

Power Law Fit

10-3 10-2 10-1 100

10-4

10-2

100

102

104

q (Å-1)

0 h
6 h
24 h

10-3 10-2 10-1 100

10-4

10-2

100

102

104

q (Å-1)

1 wt% at 0 h

Combined fit

e

slope = –2

slope = –3.7

10-3 10-2 10-1 100

10-4

10-2

100

102

104

q (Å-1)

In
te

ns
i ty

(c
m

- 1
)

7 days

0 h
6 h
24 h

Fig. 2 | Synthesis, optimization, and characterization of Trpzip hydrogels.
a Chemical structures of Trpzip1 and Trpzip1-QV, with changes in amino acid
sequence highlighted. The photograph depicts Trpzip1 and Trpzip-QV peptides
dissolved in purewater at 1mg/mL after 24h at 37 °C. bCircular dichroism spectra
of Trpzip1 (dashed line) and Trpzip-QV (solid line) in H2O across a temperature
range of 0–60 °C. c Transmission electron micrographs of Trpzip-QV nanofibers
formed at pH 7. The scale is 200 nm (left) and 50nm (right). Data is representative
of two independent experiments. d Cryo-TEM of Trpzip-QV hydrogels (2% w/v in
DMEM, pH 7) at 30 s and 24 h post-gelation at 37 °C. The scale is 50nm (left) and

100nm (right). Data is representative of two independent experiments. e Small
angle neutron scattering profiles of Trpzip-QV hydrogels in deuterated DMEM at
1% w/v (far left), 3% w/v (center left), separate data fitting to the lamellae model fit,
and the power law fit (center right), and the combined data fitting against the
experimental scattering of 1% w/v Trpzip-QV hydrogels (far right). f Scanning
electron micrographs of Trpzip-QV hydrogels (3% w/v, DMEM) at pH 14 and pH 7.
Scale bars are 100μm, 5μm, 200μm, and 10μm, from left to right. Data is
representative of two independent experiments. g Schematic of proposed self-
assembly mechanism of Trpzip-QV peptide monomers into hydrogels.

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 4



observed evidence of continued proliferation throughout the original
gel volume but no dissolution of thematerial (Supplementary Fig. 13b,
d). Through immunofluorescence imaging, we observed the deposi-
tion of collagen I throughout Trpzip gels after 14 days of fibroblast
culture, suggesting endogenous deposition of ECM is occurring
(Fig. 4f; Supplementary Fig. 14a, b). Taken together, these data indicate
Trpzip hydrogels foster robust cell attachment, spreading, and elon-
gation without the need for cell adhesion cues. We note most other
synthetic peptide-based hydrogels lack this inherent bio-adhesivity26,
suggesting Trpzip gels may prove a versatile 3D cell culture material.

The low yield point and self-healing properties of Trpzip gels
also open the potential for syringe delivery. In liquid cell suspen-
sions, mechanical damage results in a significant loss of viability27.
We reasoned that Trpzip gels may be able to shield cells from the
damaging mechanical forces experienced during flow. To assess
this, HFFs encapsulated in Trpzip gels were extruded through a
syringe needle at high shear. After 24 h, the sheared cell viability was
comparable to cells grown on glass and non-extruded cells encap-
sulated in Trpzip gels (Fig. 4g). The yield-stress fluid properties of
Trpzip gels also provide scope for use as a support medium for
deposition of material; that is, the ability to fluidize under shear and
self-heal around a deposited material. To demonstrate this, we
printed high-density fibroblast cell inks into various droplet and line
constructs within a support bath of Trpzip gel (Fig. 4h; Supple-
mentary Fig. 15). Dot diameters averaged 650 ± 80 μm (n = 8), and
line diameters averaging 350 ± 50 μm (n = 4; 14% from theoretical
line width). Immunofluorescence imaging of the printed constructs
shows they consist of tightly packed cells (Fig. 4h), suggesting that

the yield point is high enough for use as a support medium for the
printed deposition of live cells.

The amino acid tryptophan has been shown to possess anti-
bacterial activity through its ability to permeabilise bacterial mem-
branes, thereby causing bacterial cell death28–30. We hypothesized that
the high tryptophan content in Trpzip peptides may confer some
antibacterial activity. To test this, we challenged sterilised Trpzip
hydrogels with both a Gram-positive and Gram-negative strain of
bacteria (Staphylococcus aureus and Escherichia coli, respectively) and
assessed antimicrobial activity after 24 h using a bacterial growth
inhibition assay (Fig. 4i; Supplementary Fig. 16).Weobserved amarked
reduction in bacterial growth for both strains, with Trpzip hydrogels
showing particularly high activity against S. aureus (99.99% reduction
in growth for S. aureus, 99.75% reduction in growth for E. coli). The dual
activity of Trpzip gels against both Gram-positive and Gram-negative
strains suggests they are promising therapeutic candidates against
polymicrobial infections31. Like other injectable antimicrobial
hydrogels32,33, Trpzip-based materials may prove useful as extrudable
self-healing antimicrobial hydrogels, with potential for use in biome-
dical applications.

Trpzip hydrogels can induce polarity changes in human intest-
inal organoids
Organoid culture relies heavily on Matrigel as an exogenous extra-
cellular matrix support material, despite being of murine origin and
having issues with batch variability. We reasoned that Trpzip gels,
having similar porosity and stress-relaxing characteristics to Matrigel,
could serve as a synthetic, minimally supportive matrix alternative for

Fig. 3 | Mechanical characterization of Trpzip hydrogels. a Oscillatory time
sweeps of Trpzip-QV hydrogels of varied concentration represented in percent
weight per volume (% w/v). Data is shown as mean ± s.d. (shaded area) from n = 3
independently prepared gels. b Oscillatory time sweeps of Trpzip-QV hydrogels
(1% w/v, DMEM, pH 7) at 20 °C and 37 °C (light and dark blue, respectively). Data
is shown asmean ± s.d. (shaded area) from n = 3 independently prepared gels. cA
strain sweep was performed at 1 Hz of a Trpzip-QV hydrogel (1% w/v, DMEM, pH
7). The dotted pink line indicates yield-point. Data is shown as mean ± s.d. (sha-
ded area) from n = 3 independently prepared gels. d A viscosity flow curve of
Trpzip-QV hydrogels (1% w/v, DMEM, pH 7). Data is shown asmean ± s.d. (shaded
area) from n = 3 independently prepared gels. e Thixotropic test on Trpzip-QV
hydrogels (3% w/v, DMEM, pH 7) involving exposure to 5% shear strain for 5min,

followed by reduction of shear strain to 1% for 2 h, repeated three times in suc-
cession. Data is shown as mean ± s.d. (shaded area) from n = 3 independently
prepared gels. f Stress-relaxation profiles of Trpzip-QVhydrogels (1%w/v, DMEM,
pH 7), Matrigel, and polyethylene-glycol dimethacrylate (PEG-DM) hydrogels.
Data is shown as mean ± s.d. (shaded area) from n = 3 independently prepared
gels. g Relaxation half-time (τ1/2) of Trpzip-QV hydrogels (1% w/v, DMEM, pH 7)
and Matrigel. P-values were calculated using a two-tailed unpaired t-test. Data is
shown as mean ± s.d. from n = 3 independently prepared gels. h Effect of IKVAV-
Trpzip-QV peptide (200 μM concentration) on bulk hydrogel stiffness. Data is
shown as mean ± s.d. from n = 3 independently prepared gels. P-values were
calculated using a two-tailed unpaired t-test.

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 5



Day 1 Day 7
0

1000

2000

3000

4000

C
el

l A
re

a 
(µ

m
2 )

Trpzip gelFmoc-GFF gel

p = 0.0008

p < 0.0001

p < 0.0001 p = 0.0002

n=199

n=174

n=366

n=154

Glas
s (

–s
he

ar)

Gel 
(–s

he
ar)

Gel 
(+s

he
ar)

0

95

100

105

110
Vi

ab
ilit

y 
(%

)
p = 0.0403

ns

ns

Con
tro

l

Trp
zip

 ge
l

100

102

104

106

108

1010

1012

C
FU

s/
m

L

p < 0.0001

Con
tro

l

Trp
zip

 ge
l

100

102

104

106

108

1010

1012
p = 0.0001

Glass Trpzip
0

95

100

Vi
ab

ilit
y 

(%
)

nsa db

ih

Live
Dead 

g

Shear stress

Gel (–shear)

Glass (–shear)Gel (+shear)

Live
Dead 

D
ay

 1
D

ay
 7

Fmoc-GFF gel Trpzip gel

Actin

c

Nuclei
Actin

Matrigel Trpzip gel

f

e

Actin

Dots
Lin

es
0

200

400

600

800

1000

D
ia

m
et

er
 (µ

m
)

Nuclei
Actin Collagen I

S. Aureus E. Coli
Cell bioink Trpzip gel support bath

Bacteria

Sterile Trpzip gel

Inoculation

Fig. 4 | Trpziphydrogels support cell growth, syringeextrusion, biofabrication
and show antimicrobial properties. a Confocal microscopy image of human
fibroblast cells stained with Calcein AM and ethidium homodimer in Trpzip
hydrogels (1% w/v, DMEM, pH 7) after 5 days in culture. The scale is 100μm.
bQuantified percentage of cell viability of fibroblasts cultured in Trpzip hydrogels
compared to cultureonglass (n = 5gels).Data are presented asmean ± s.d. P-values
calculated using two-tailed unpaired t-test. c Confocal microscopy image of
fibroblasts cultured in Fmoc-GFF hydrogels (1% w/v) and Trpzip hydrogels (1% w/v)
after seven days, without the use of RGD binding ligands. The scale bar is 50μm.
d Quantification of cell area (left) and cell aspect ratio (right) for fibroblasts cul-
tured in Fmoc-GFF hydrogels (n = 3) and Trpzip hydrogels (n = 3) for seven days.
Error bars show mean± s.d. P-values calculated using two-way ANOVA. e Confocal
microscopy image of HFFs cultured in Matrigel and Trpzip gels (no RGD) for
30 days. The scale bar is 100μm. Data is representative of one independent
experiment. f Deposition of endogenous collagen I by fibroblast cells after 14 days

in culture inTrpzip hydrogelswithout RGD ligands. The scale bar is 100μm.Data is
representative of one independent experiment. g Viability of cells encapsulated in
Trpzip hydrogels and then exposed to shear (n = 3 gels) compared to cells
experiencing no shear seeded on glass (2D; n = 3 wells) or within Trpzip gels (3D;
n = 3). Error bars show mean ± s.d. P-values calculated using one-way ANOVA. The
scale is 100μm. h Bioprinted constructs of cells in a Trpzip hydrogel support bath,
either as droplets (left panel) or lines (right panel). The scale is 500μm in optical
images and 200μm in immunofluorescence images. The measured average dia-
meter of printedcellular droplets (n = 8) or lines (n = 4). Errorbars showmean± s.d.
i Antibacterial activity of Trpzip hydrogels against both a gram positive (S. aureus)
and a gram negative (E. coli) species, assessed using a bacterial growth inhibition
assay. Photographs show agar plates used to count colony forming units (CFUs)
per mL of each bacterial species after incubation with Trpzip gels for 24h at 37 °C
(n = 3 gels). Data are presented as mean ± s.d. P-values calculated using two-tailed
unpaired t-test.

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 6



organoid growth. We selected human intestinal organoids—derived
from adult stem cells and induced pluripotent stem cells (iPSCs)—as
their morphogenesis and tissue patterning pathway have been exten-
sively studied34–36.

We passaged and seeded intestinal organoids from three partici-
pants with cystic fibrosis in Trpzip gels and cultured them for seven

days before comparing them alongside organoids grown in Matrigel
(Fig. 5a). The viability of organoidswas confirmedafter sevendaysusing
Calcein AM and ethidium homodimer (Supplementary Fig. 17a, b).
Organoids grown in Matrigel had projections and budding, with a
centralized lumen, whereas organoids grown in Trpzip hydrogels dis-
played a more spherical morphology (Fig. 5b). Morphometric analysis

Matr
ige

l

Trp
zip

 (T
)

T + 
La

m low

T + 
La

m hig
h

0

5000

10000

O
rg

an
oi

d 
sw

el
lin

g

Baseline Post-modulator

P < 0.0001

P < 0.0001

P < 0.0001

P < 0.0001

CDX2
ZO-1

Ly
so

zy
me

MUC2

0

50

100

%
 o

f o
rg

an
oi

ds
 e

xp
re

ss
in

g 
m

ar
ke

r

Matrigel
Trpzip gel

0 500 1000
-500

0

500

Dim1 (42.3%)

D
im

2 
(1

6.
7%

)

12
3

4
1

2

3

4

Matrigel
Trpzip gel

7 days

Human intestinal 
organoid Passage

Matrigel

Trpzip gel

Proteomics

Immunofluorescence

a

f g

Participant 1                         Participant 2                         Participant 3
b

M
at

rig
el

Tr
pz

ip
 g

el

Nuclei Actin ZO-1

c

e

d

Tr
pz

ip
 g

el
   

   
   

   
   

   
   

   
   

   
M

at
rig

el

Nuclei  MUC2 LYZ

Basal-out

Apical-out

i jh
Log2 

intensity

Trpzip (T) T+LamlowT+Lamhigh Matrigel

Pr
ot

ei
ns

t = 0 t = 90

Tr
pz

ip
 (T

)
M

at
rig

el
T 

+ 
La

m
hi

gh
T 

+ 
La

m
lo

w

Calcein AM

-4 -2 0 2 4
0

2

4

6

Log2 Fold Change

Lo
g 1

0P

IMPDH2

SUPT16H MYO1B

SLC12A2

DDX42

MCM4

SYNE2

RCC2

GLDCNOP56
RETSAT

NMES1

CES2

CYP2S1

LAMA3
RHPN2

HSD17B2

HSPB1

AKR1C2

LAMB3

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 7



revealed an average circularity value of 0.421 in Matrigel-grown orga-
noids and 0.807 in Trpzip-grown organoids, across the three partici-
pant lines (Supplementary Fig. 18). In contrast to Matrigel-grown
organoids, we observed Trpzip-grown organoids possessed an apical
out polarity, as evidenced by a layer of filamentous actin and the apical
tight-junction ZO-1 protein on the organoid exterior, along with the
visualization of microvilli of brush border cells (Fig. 5b, c; Supplemen-
tary Fig. 19a, b)37. We observed the same reversal of polarity in iPSC-
derived small intestinal organoids, as evidenced by filamentous actin
imaging (Supplementary Fig. 20).

To understand the differentiated state of these intestinal
organoids, we performed further immunofluorescence analysis.
Organoids grown in both Matrigel and Trpzip gels were examined
for the presence of intestinal epithelial patterning and polarization,
as well as markers of fully differentiated intestinal cell types
including Paneth cells and goblet cells (Fig. 5d). Immuno-
fluorescence analysis revealed the expression of the intestinal epi-
thelial marker CDX2 and the tight junction marker ZO-1 in 100% of
organoids, irrespective of participant origin or matrix condition,
confirming Trpzip gels support intestinal lineage differentiation
and proper epithelial polarization (Fig. 5e). We also quantified the
percentage of organoids expressing the markers MUC2 and LYZ to
assess abundance of the differentiated goblet cells and Paneth cells,
respectively. We found Matrigel-grown and Trpzip-grown orga-
noids express all markers with a similar frequency, although varia-
bility between participant lines was evident. We then performed
global proteomics for organoids cultured in Matrigel and Trpzip
hydrogels, which demonstrated 70% similarity with separate clus-
tering behavior by principal component analysis for the different
participants (Fig. 5f). Differential expression analysis indicates
changes in proteins involved in intestinal homeostasis and meta-
bolism (Fig. 5g), with increased cytoskeletal remodeling evident in
Trpzip grown organoids (Supplementary Fig. 21). These expression
differences are unsurprising considering the different morphology
and apparent apical polarity fostered by the hydrogels.

It is clear the surrounding matrix in organoid culture can play an
important role in regulating growth, polarity, and morphogenesis.
Most protocols use Matrigel as the encapsulate; however, the use of
alternative biomaterials has been of great interest in recent years. Early
iterations of synthetic matrices were often PEG-based, with the incor-
poration of MMP-degradable peptides36,38 to enable organoid mor-
phogenesis contingent on matrix degradation but have also included
polysaccharide and other full-length protein-based hydrogels39,40.
Recently, Lutolf and colleagues showed how a fully synthetic hydrogel
with both covalent and physical crosslinks enabled comparable orga-
nogenesis to Matrigel by virtue of matrix stress-relaxation23. Trpzip
gels show strong potential as a fully synthetic organoid matrix, emu-
lating both the stress-relaxing nature and dynamic hierarchical
assembly observed in natural materials.

Materials that foster apical-out polarity would benefit a range of
studies since this is the side that natively interacts with the external
environment. Most techniques for accessing the apical surface involve
invasively penetrating the organoid barrier through either micro-
injection, shearing, or mechanical disruption of organoids, or dis-
sociation of 3D organoids to be reseeded as 2D monolayers on
Transwell plates. Co et al. only recently reported the first non-
destructive 3D method of generating apical-out organoids through
suspension culture37. However, this approach precludes studies of the
epithelialmicroenvironment, an aspect that can be tuned using Trpzip
hydrogels. Once the Trpzip-embedded organoids grow larger
(>100μm), there is evidence for both outward and inward polarization
with an internal lumen. This characteristic will not impede studies of
apical facing organoid behavior.

Previous work has demonstrated how the presence of laminin
protein is important for supporting basal polarity and growth in syn-
thetic hydrogels41. While apical facing organoids hold several advan-
tages as discussed, we next sought to evaluate whether the addition of
laminin would influence the polarity and growth characteristics of
Trpzip-encapsulated organoids. We blended Trpzip hydrogels with
varying amounts of laminin to determine whether we couldmimic the
polarity and growth characteristics of organoids grown inMatrigel.We
cultured organoids from one participant in Matrigel, pure Trpzip gels,
Trpzip gels incorporating 0.4mg/mL laminin (low), and Trpzip gels
incorporating 3mg/mL laminin (high). Organoids grown in pure
Trpzip gels and those containing low laminin maintained a spherical
morphology (Supplementary Fig. 17a). In contrast, organoids grown in
the higher laminin content Trpzip gels appeared more similar in
morphology to organoids grown in Matrigel. Live/dead imaging indi-
cates a slight increase in cell death for the Trpzip-only conditions,
which we attribute to normal apoptotic signaling during morphogen-
esis as observed previously with apical-out organoid protocols (Sup-
plementary Fig. 17b)37. The addition of laminin also increases organoid
viability in the Trpzip hydrogels. Global proteomics analysis shows
significant similarity between all conditions – pure Trpzip, Trpzip with
low and high laminin, and Matrigel (Fig. 5h). Importantly, we observe
clustering of Trpzip with Trpzip-low laminin andMatrigel with Trpzip-
high laminin, suggesting greater similarity to Matrigel as we increase
the laminin content in the matrix (Fig. 5h; Supplementary Fig. 22a, b).

Since the addition of laminin to Trpzip appears to emulate growth
in Matrigel, we performed a forskolin swelling assay to quantitatively
assess organoid polarity. As the organoids were derived from patients
with the homozygous DF508-CFTR mutation, organoids with a basal-
out polarity are expected to swell upon correction and activation of
the cystic fibrosis transmembrane conductance regulator (CFTR)
channel. Upon activation of the CFTR channel, organoid swelling was
observed within 90min with live imaging (Fig. 5j, k; Supplementary
Video 2–5) in organoids grown in Matrigel and Trpzip-high laminin
hydrogels. Conversely, organoids grown in Trpzip gels and Trpzip-low

Fig. 5 | Development of adult-stem cell derived intestinal organoids in Trpzip
hydrogels compared to Matrigel. a Schematic describing experimental design to
evaluate organoid development in Trpzip hydrogels compared to Matrigel.
b Representative images across three independent experiments of organoid mor-
phology after 7 days in Matrigel and Trpzip gels across three participant organoid
lines. Scale is 100μm (top panel); 50μm (bottom panel). c Filamentous actin stain
to highlightmicrovilli localization on the exterior of organoids grown inTrpzipgels
(scale is 100μm). The inset shows microvilli from a cross-section view of the
organoid (scale is 50μm). Data is representative of three independent experiments.
d Representative images across three independent experiments of organoids
grown in either Trpzip gels orMatrigel marked for differentiated cell types. Paneth
cells and goblet cells are marked by LYZ and MUC2 respectively. The scale is
100μm. e Frequency of mature cell type differentiation in Trpzip gels (blue) and
Matrigel (red). Data points represent the percentage of organoids expressing each
marker as assessed by antibody staining across three participant organoid lines

with n = 10 organoids per marker. Error bars show mean ± s.d. f Principal compo-
nent analysis of protein expression profiles of organoids cultured in Matrigel and
Trpzip gels. g Volcano plot indicating significantly differentially expressed pro-
teins. The dashed horizontal line shows P-value cut-off and vertical lines indicate
up/down-regulated proteins. P-values were calculated using the Benjamini-
Hochberg procedure. h Hierarchical clustering analysis of global proteomics for
organoids cultured in Matrigel, pure Trpzip, and Trpzip with low and high laminin
content. Clustering distance is based on the Euclidean distance. i Brightfield live
imaging over 90min of organoid response to treatment with the CFTR modulator
(Trikafta) in Matrigel, pure Trpzip, and Trpzip with low and high laminin content.
Organoids have been stained with Calcein AM (green) to visualize viability. The
scale is 200μm. jQuantification of change in organoid size (normalized AUC t = 90;
n = 5 organoids per condition) following response to CFTR modulator (blue)
compared to baseline (black). Data are presented asmean ± s.d. P-values calculated
using two-way ANOVA.

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 8



laminin exhibited no such swelling, suggesting the organoids grown in
thesematrices display apical-out polarity. This is confirmed by the lack
of swelling that is also observed when organoids are grown in sus-
pension, a process bywhich is known to cause a reversion to apical-out
polarity (Supplementary Fig. 23)37. Taken together, we show basal-out
polarity can be maintained in organoids grown in Trpzip hydrogels
when a sufficient concentration of laminin protein is present.

Our work demonstrates a peptide hydrogelator based on the
tryptophan zipper motif that self-assembles into a nano- and micro-
structured material with unique mechanical and biological prop-
erties. Trpzip hydrogels are easily formed without the need for rigid
temperature control, which is often required for natural matrices.
The tunable modulus and low yield stress provide the first example
of a material where viscoelasticity can be varied to direct functional
biological outcomes followed by quick harvest through simple
agitation. This will prove highly beneficial for molecular character-
ization, which usually requires invasive enzyme-mediated dissolu-
tion of the surrounding matrix. Similarly, the low yield stress and
self-healing properties provide a means for syringe extrusion,
where fluidization of the hierarchical material protects the cells
from shear, towards applications in cell delivery and in biofabrica-
tion. Considering how these hydrogels are simultaneously bacter-
icidal and bioactive to mammalian cells, there is broad scope for
using Trpzip hydrogels in vitro as well as in vivo as a therapeutic
biomaterial.

Methods
Materials
Synthetic peptides (Trpzip-QV and Trpzip-IKVAV) were purchased as
the formate salt (purity >98%) fromGenScript Biotech (Singapore) Pte
Ltd and used without further purification.

Molecular dynamics
Avogadro 1.2.0 was used to create all-atom peptide structure files. The
MARTINI force field (version 2.2) and martinize.py42 were used to
generate the coarse grain (CG) form of each peptide variant. A cubic
simulation box (20 × 20 × 20nm3) was created using GROMACS ver-
sion 2021.343, and filled with 150 zwitterionic CG peptide monomers
(final peptide concentration of 31mmol L−1). The system was main-
tained at neutral pH by using amino acid side chains set to their
standard charge states at pH 7. Periodic boundary conditions were
applied in all three dimensions. Non-polarizable CG water was used to
solvate the simulation box, and counterions Na+ and Cl− were added if
needed to neutralize the overall charge of the system. Electrostatic
interactions and Lennard-Jones interactions were shifted to zero at a
cutoff of 1.1 nm. Electrostatic interactions were screened by setting the
relative dielectric constant (εr) to 15. The systemwas energyminimized
using the steepest descents algorithm for 10,000 steps or until forces
in excess of 100 kJmol−1 nm−1 were removed. The Berendsen
thermostat44 was used to maintain temperature (τT = 1 ps) and pres-
sure (τP = 3 ps) around 298K and 1 bar, respectively. The LINCS con-
straint algorithm45 was used to fix bond lengths.

Scripts used to run CG simulations were based on the Martini
tutorials, ‘High throughput peptide self-assembly’, available online at
http://cgmartini.nl/index.php/tutorials-general-introduction-gmx5/
tutorial-ht-peptide-gmx5. Coarse-grain structures were converted to
all-atom resolution using backward.py46.

Peptide synthesis and purification
Peptides were synthesized using solid phase peptide synthesis on a
Biotage Initiator+ Alstra microwave peptide synthesizer. Briefly,
2-chlorotrityl chloride resin (1.1mmol/g loading; 500mg; Chem-
Impex)wasallowed to swell indichloromethane (DCM) for 30min. The
first amino acid (3 equivalents) was dissolved in a solution of 2mL
DCM, 2mL peptide-grade N,N-dimethylformamide (DMF) and 1mL

N,N-diisopropylethylamine (DIPEA), before being allowed to couple to
the resin overnight. Methanol capping was performed once after the
first amino acid coupling. Fluorenylmethoxycarbonyl (Fmoc) depro-
tection was performed using 20% piperidine in DMF (repeated twice,
once for 5min and again for 10min). Subsequent amino acids were
coupled using benzotriazol-1-yloxytripyrrolidinophosphonium hexa-
fluorophosphate (PyBOP) activation, whereby 3 equivalents of the
Fmoc-amino acid, 3 equivalents of PyBOP in peptide-grade DMF, and 6
equivalents of DIPEA were used. Coupling reactions were performed
under microwave at 70 °C for 5min. Following completion of the
synthesis, the resin was dried and treated with a cleavage cocktail
consisting of 95% trifluoroacetic acid, 2.5% triisopropylsilane, and 2.5%
ethanedithiol for 3 h at RT on an orbital shaker. The crude peptide was
precipitated dropwise into ice-cold diethyl ether, followed by cen-
trifugation of the mixture (3000 g for 10min) and decanting of excess
diethyl ether to yield a solid pellet of the crude peptide.

For purification, the crude peptide was dissolved in Milli-Q
water and HPLC-grade acetonitrile (1:1 ratio) and injected onto an
Inertsil ODS-4 C18 column (20mm I.D., 150mm length, 5 μm parti-
cle size) at a flow rate of 5 mL/min. The eluting solvent system (in all
cases with 0.1% v/v formic acid as ion-pairing agent) had a linear
gradient of 20% (v/v) acetonitrile in water for 5min, gradually rising
to 80% (v/v) acetonitrile in water at 35min. This concentration was
kept constant until 40min when the gradient was decreased to 20%
(v/v) acetonitrile in water at 42min. Elution was determined by UV
detection at 254 nm. Peptide identity and purity were verified by
MALDI-TOF (Supplementary Fig. 2). Purified peptide was collected
from HPLC fractions, pooled, and lyophilised to yield a fluffy,
white solid.

Hydrogel preparation
Trpzip hydrogels were prepared by dissolving lyophilized peptide in
1 N NaOH (10% of the final hydrogel volume). The desired cell culture
media was added to aid further dissolution of the peptide (50% of the
final hydrogel volume). The hydrogel was adjusted to pH 7 using 1M
HCl before additional cell culture media was added to bring the
hydrogel to its final desired volume. Hydrogels were allowed to incu-
bate at 37 °C overnight before use in cell culture.

Trpzip hydrogels could also be prepared by dissolving lyophilized
peptide in Milli-Q water at a concentration of 1% (w/v). Magnetic stir-
ring on a hot plate (40 °C) was used to accelerate dissolution. Hydro-
gels were sterilized by exposure to UV light for 15min. Gelation was
triggered by adding cell culture media to a final concentration of
0.5% (w/v).

Transmission electron microscopy (TEM)
Carbon-coated copper grids (square mesh 300; ProSciTech) were
plasma-treated in the air for 1min. Peptide hydrogels (1% w/v; pH 7)
were diluted ten-fold and 5μL of the resulting solution was pipetted
onto the grid. The droplet was left on the grid for 1min before the
excess solutionwasblotted offwithfilter paper. The gridwas left to air-
dry prior to staining. Negative stain (1% aqueous uranyl acetate) was
applied for 1min before excess liquidwasblotted off using filter paper.
Bright-field TEMmicrographs were obtained on an FEI Tecnai G2 TEM
operating at an accelerating voltage of 200 kV. Images were acquired
using a BM Eagle 2 K CCD camera.

Circular dichroism (CD)
Peptide solutions were prepared at 0.1mg/mL in Milli-Q water. Far-UV
CD spectra were recorded between 180 and 300nm on Chirascan Plus
CD spectrometer (Applied Photophysics, UK). Spectrawas recorded in
1 nm steps and sampled at 0.5 s per point. All measurements were
taken in a 1mm quartz cuvette (Starna, Inc.). Final spectra were
recorded as the average of three scans, with baseline spectra
subtracted.

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 9

http://cgmartini.nl/index.php/tutorials-general-introduction-gmx5/tutorial-ht-peptide-gmx5
http://cgmartini.nl/index.php/tutorials-general-introduction-gmx5/tutorial-ht-peptide-gmx5


Fourier transform infrared spectroscopy (FTIR)
A Perkin Elmer Spotlight 400 FTIR spectrometer fitted with a diamond
crystal attenuated total reflectance (ATR) accessory was used to
acquire FTIR spectra. Trpzip hydrogels (3% w/v) were mounted
between the diamond crystal and force lever and all spectra were
scanned 20 times over the range of 2000–1000 cm−1.

Small and ultra-small angle neutron scattering (SANS
and USANS)
Trpzip gels were prepared by dissolving lyophilized peptide in deut-
erated DMEM before being transported to Australian Centre for Neu-
tron Scattering (ACNS) at the Australian Nuclear Science and
Technology Organization (ANSTO). SANS measurements were per-
formed on hydrogels samples at 37 °C.

The structure of the hydrogels was analyzed using the Quokka
pinhole small-angle neutron scattering (SANS) instrument47. Samples
were loaded in the quokka demountable cells of 20mm diameter and
pathlength 1mm. The scattering data of samples were collected at a
full q range of 0.0007-0.73 Å−1 with three detector configurations
(20m collimation with 8.1 Å neutrons), 12m (12m collimation with 5 Å
neutrons) and 1.3m (12m collimation with 5 Å neutrons). The scat-
tering profiles of the gels were recorded against the scattering vector
by using the following equation:

q=
4π
λ

sinθ ð1Þ

where q is the scattering vector, 2θ is the angle of scattering, λ is the
wavelength of the neutron beam. The obtained 2D raw scattering data
were reduced and converted to the absolute scale using the Igor Pro
software package (with Quokka SANS reduction macros)48. Igor Pro
was used to subtract appropriate solvent background from each
dataset. SasView (www.sasview.org) was used to fit the models to the
scattering data.

TheUSANS datawere collected using the Kookaburra Bonse–Hart
instrument at ACNS, ANSTO49. Round demountable cells (40mm dia-
meter, 1mm pathlength, 29mm sample aperture) were used tomount
samples. High fluxmodewas usedwith a neutronwavelength of 4.74 Å
to provide q ranges of 3.5 × 10−5–0.007 Å−1. The experimental USANS
data were de-smeared using the Lake algorithm incorporated in NIST
USANS macros. The neutron scattering length densities (SLD) of
Trpzip peptides of 1.46 × 10−6 Å−2 was calculated using the online SLD
calculator (https://www.ncnr.nist.gov/resources/activation/). SasView
was used to fit the scattering data.

Scanning electron microscopy (SEM)
Lyophilized hydrogel samples were fixed to aluminum stubs with
adhesive carbon discs. The samples and stubs were then sputter
coatedoncewith gold (EmitechK575x sputter coater). AHitachi S3400
(7–10 kV, probe current of 40) scanning electronmicroscopewas used
for all imaging.

Cryo-TEM
Trpzip hydrogels were prepared at 2% (w/v) in DMEM and allowed to
gel at 37 °C until the designated imaging time point. Gel (4.5μL) was
applied to glow discharged R2/2 copper grids (Quantifoil Micro Tools)
and blotted for 4 s in a controlled humidity chamber (95% humidity),
then plunged in liquid ethane using a Lecia EM GP device (Leica
Microsystem). The grids were imaged using a Talos Arctica cryoTEM
(Thermo Fisher Scientific) and operated at 200 kV, with the specimen
maintained at liquid nitrogen temperatures. Images were recorded on
a Falcon 3EC direct detector camera operated in linear mode.

Rheology
Rheological measurements were performed on an Anton Paar MCR
302e Rheometer with a parallel plate geometry (25mmdisc, 1mmgap
height, 560μL of hydrogel). Oscillatory measurements were per-
formed with 0.2% strain and a 1Hz frequency at 37 °C, unless specified
otherwise. Viscosity flow curve tests were performed with a log ramp
up rate from0.01 to 10 shear rate (1 s−1) over 10min. Strain sweep tests
were performed with a log ramp up rate from 0.02% shear strain up to
200% at 1 Hz frequency over 10min. Stress relaxation tests were per-
formedat 1% strain, afterwhich the stress profilewasnormalized to the
initial maximum stress. The decay half time was calculated by deter-
mining the time at which stress was half the initial normalized stress.
Frequency sweeps were run with a log ramp up rate from 0.01 to
100Hz with 0.2% strain (Supplementary Fig. 9).

Cell and organoid culture
Human fetal fibroblasts (HFF-1; SCRC-1041) were obtained from the
American Type Culture Collection (ATCC) and cultured in high-
glucose DMEM supplemented with 15% fetal bovine serum (FBS) and
1% penicillin/streptomycin (P/S). All HFF cultures were maintained at
37 °C, 5%CO2 and used between passages 17–22. Mousemyoblast cells
(C2C12) were obtained from ATCC (CRL-1772) were cultured in high-
glucose DMEM supplemented with 10% FBS and 1% P/S. All C2C12
cultures weremaintained at 37 °C, 5%CO2, and used between passages
9–11. For differentiation of C2C12 cells, media consisting of high glu-
cose DMEM supplemented with 10% horse serum and 1% P/S was used.
Media changes occurred every 2 days for both cell lines.

Human small intestinal organoids were derived from induced
pluripotent stem cells (iPSCs) obtained from ATCC (ACS-1020, lot
number 0176) using the STEMdiffTM intestinal organoid kit (StemCell
Technologies; cat #05140). All iPSC-derived organoids were main-
tained at 37 °C, 5% CO2 and in STEMdiffTM intestinal organoid growth
medium (StemCell Technologies; cat #05145) and used between pas-
sages 12–17. Media changes occurred every 2–3 days, and organoids
were passaged every 7–10 days depending on organoid size and den-
sity. All cell lines were authenticated by ATCC using STR profiling, as
confirmed by the Certificate of Analysis provided upon purchase.
iPSCs were additionally karyotyped.

Adult stem cell derived intestinal organoids were sourced from the
molecular and integrative Cystic Fibrosis (miCF) Biobank (HREC16/
SCH120) which were established from crypts isolated from four to six
rectal biopsies50. Isolated crypts were seeded in 70% Matrigel (Growth
factor reduced, phenol-free; Corning 356231) in 24-well plates at a
densityof approximately 10–30crypts in 3 × 10μLMatrigel droplets per
well. Intesticult organoid media (StemCell Technologies; cat #06010)
was supplemented with 1× penicillin-streptomycin, 50mg/mL genta-
micin, 50mg/mL vancomycin, 250 ng/mL fungizone and 100mg/mL
primocin. Cryopreserved organoids were seeded in Matrigel and cul-
tured for 7 days with Intesticult organoid media (StemCell Technolo-
gies; cat #06010), before being passaged and seeded in equal density in
Matrigel or Trpzip hydrogels (with 0.4mg/mL or 3mg/mL laminin,
designated as low and high laminin content, respectively; R&D Systems
Cultrex 3D Culture Matrix Laminin I; RDS344600501). At day 6–7 post-
seeding, organoid viability was assessed using Calcein AM (Thermo
Fisher Scientific C3100MP), then imaged, fixed, or lysed as necessary.

Cell viability assay
HFFs were detached from tissue culture flasks with 0.25% trypsin and
seeded in Trpzip hydrogels (1wt%, rehydrated in media) at a con-
centration of 600,000 cells/mL. The cell laden Trpzip gels were stif-
fened by incubation at 37 °C for 20min before cell culture media was
added. The media was changed every two days until viability was
assessed using a Calcein-AM/Ethidium Homodimer-1 kit (Thermo-
Fisher Scientific; cat #L3224). For live/dead staining, Calcein-AM
(0.5 μL/mL) and Ethidium-Homodimer-1 (2μL/mL) were added to

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 10

http://www.sasview.org
https://www.ncnr.nist.gov/resources/activation/


Trpzip gels for 40min before being washed twice with PBS prior to
imaging. For assessing viability of cells after injection, the above pro-
cedure was followed except that cell laden Trpzip gels were loaded
into a 1mL syringe before being extruded through an 18G needle.

Bioprinting
HFFs were detached from tissue culture flasks with 0.25% trypsin and
pelleted via centrifugation (300g for 3min). The supernatant was
removed and the cell pelletwas lightly brokenupvia pipetting, and care
was taken tonot introduce air bubbles. Thepelletwas thendrawn into a
1mL syringe, and the syringe inserted directly into a 3D printed fitting
on a Lulzbot 3Dbioprinter. The desired syringe needlewas then primed
with cell solution and cells were printed as either dots or lines into
custom 3D-printed squaremolds (0.8mm×0.8mm) containing Trpzip
gel (1% w/v) as a support bath. The printed constructs were then incu-
bated at 37 °C for 20min to allow stiffening of the gel before fixation
with 4% paraformaldehyde (PFA) for immunofluorescence analysis.

Antimicrobial assays
Briefly, S. aureus 38 or E. coli K12 were inoculated in 5mL of Mueller
Hinton Broth (MHB) media and incubated at 37 °C to establish an
overnight culture. Twenty-four hours post incubation, the bacteria
were pelleted out of the MHB via centrifugation at 1000 g for 10min.
An Eppendorf 5430 multifaceted centrifuge was used for cen-
trifugation. The supernatants were subsequently discarded, and the
bacteria were dissolved in fresh MHB. The volume of MHB was
adjusted such that the solution of bacteria in MHB recorded an
absorbance value of 0.1 in a microplate reader (600 nm), corre-
sponding to a starting concentration of the S. aureus 38 or E. coli K12
in the MHB of 108 bacteria/mL. The media was further diluted to
obtain a final bacterial concentration of 105 bacteria/mL before being
added to the vials containing sterile Trpzip hydrogel (1% w/v; 1mL).
The vials were then transferred to a humidified incubator and incu-
bated overnight at 37 °C. Post incubation, the media from each vial
was serially diluted from 1 to 10-fold in sterile PBS. Subsequently, the
diluted media was pipetted out on agar plates. The agar plates were
then incubated overnight at 37 °C. The following day, the number of
visible single bacterial colonies, referred to as the Colony Forming
Units (or CFUs), were counted. The CFUs observed in the agar plate
corresponding to the nth dilution was then used to calculate the
CFUs/mL of the undiluted media using the following formula:

CFUs
mL

undiluted mediað Þ=CFUs in nth dilution× 10n ð2Þ

Organoid encapsulation in Trpzip gels
Organoids were recovered from Matrigel using ice-cold DMEM/F12
basal media (Life Technologies 12634-010) and mechanically frag-
mented via pipette mixing. Organoids were then pelleted via cen-
trifugation (300 g for 5min at 4 °C), and the supernatant removed.
Organoids were resuspended in Trpzip gel before being added to a
plastic 96-well tissue culture plate in 50 μL droplets. The plate was
allowed to incubate at 37 °C for 30min to allow the gel to stiffen before
the addition of media.

Global proteomics
Organoids were extracted after 7 d of culture in either Matrigel or
various Trpzip gels, and subsequently lysed using RIPA buffer (50 µL;
Life Technologies 89900) and protease inhibitor cocktail (Sigma
11836153001), followed by 15 × 30 s cycles of sonication at 4 °C using
the Bioruptor Pico (Diagenode B01060010). The Pierce BCA Protein
Assay Kit was used to calculate protein concentrations. Lysates were
reduced with 5mM dithiothreitol (37 °C for 30min), alkylated using
10mMiodoacetamide (RT for 30min) and incubatedwith trypsin (1:20

w/w; 37 °C for 18 h) before being desalted using two SDB-RPS disks
(Empore, Sigma-Aldrich 66886-U). Nano-LC was performed to sepa-
rate proteolytic peptide samples using an UltiMate nanoRSLC UPLC
and autosampler system (Dionex, Amsterdam, Netherlands). Analysis
was performed using an Orbitrap Fusion Lumos Tribrid mass spec-
trometer (Thermo Scientific, Bremen, Germany).

MaxQuant (version 2.1.3), coupled with the Andromeda algo-
rithm, was used to analyze raw peak lists. The search parameters were
as follows: ±0.5 Da for peptide fragments; ±4.5 ppm tolerance for
precursor ions; oxidation (M) and N-terminal protein acetylation as
variable modifications; carbamidomethyl (C) as a mixed modification;
and enzyme specificity as trypsin with two missed cleavages possible.
The human Swiss-Prot database (August 2022 release) was used to
search peaks. The MaxLFQ algorithm (using default parameters) was
used for label-free protein quantification. The R package, Differential
Enrichment analysis of Proteomics data (DEP), was used for down-
stream processing of quantified proteomics data. Only proteins pre-
sent in at least 50%of the samples in eachofMatrigel encapsulated and
Trpzip gel samples were used for subsequent analysis. Differential
expression analysis was carried out using a log fold change cutoff of
0.264 and p-value cutoff of 0.05. TheQIAGEN IPA Fall Release 2022 (30
September 2022) was used to perform canonical pathway analysis of
differentially abundant proteins. The mass spectrometry proteomics
data havebeendeposited to the ProteomeXchangeConsortiumvia the
PRIDE partner repository with the dataset identifier PXD038870.

Fixation and immunofluorescence staining
All organoids were fixed and immunostained following the protocol
described here51. In more detail, organoids in Matrigel domes were
incubated on ice using ice-cold cell recovery solution for 20min to
remove excess Matrigel. Organoids were washed once more in fresh
cell recovery solution before being fixed in 4% methanol-free PFA for
45min at 4 °C.Organoids in Trpzipgelswere collectedby pipetting the
gel up and down to release the organoids, before transferring the
organoids and gel to a 15mL tube on ice. Excess peptide was removed
by diluting the mixture 3-fold with cold basal media, then allowing
organoids to sink via gravity before aspirating excess peptide aggre-
gates that remained in suspension. This process was repeated until all
peptide was removed, as indicated by the increasing clarity of the
media used to rinse the organoids. Organoids in Trpzip gels were then
fixed in 4% methanol-free PFA for 45min at 4 °C. Excess PFA was then
removed, and organoids were permeabilised with 0.1% (v/v) tween-20
in PBS (10min at 4 °C). Fixed organoids were transferred to a non-
adherent 24-well plate for the remainder of the immunostaining pro-
cess. Blocking was performed using 0.1% organoid washing buffer
(OWB; 1% bovine serum albumin and 0.1% triton X-100 in PBS) for
20min at RT. Primary antibodies were diluted inOWB to their working
concentration and incubated with fixed organoids overnight at 4 °C.
Fixed organoids were then washed in OWB at least 3 times over the
span of 1 d before secondary antibodies were diluted in OWB to their
working concentration and incubated overnight at 4 °C. Fixed orga-
noids were washed again in OWB at least 3 times over the span of
1 d before being cleared with a fructose-glycerol clearing solution
(60% v/v glycerol and 2.5M fructose) for 20min at RT. Immunostained
organoids were thenmounted onto amicroscope slide in the fructose-
glycerol clearing solution for imaging.

Microscopy
All fixed and immunostained cell and organoid samples were imaged
using a Zeiss LSM 800 confocal microscope and Zen Blue software
unless specified otherwise.

Forskolin-induced swelling assay
After 6–7 days of culture in Matrigel or various Trpzip gels, organoids
less than 100 µm in size were selected and seeded in 4μL Matrigel

Article https://doi.org/10.1038/s41467-023-41907-1

Nature Communications |         (2023) 14:6604 11



droplets in a 96-well plate. For viability assessment, organoids were
incubated with Calcein AM (5 µM; Thermo Fisher Scientific C3100MP)
for 30min prior to addition of forskolin (5μM). For cystic fibrosis
transmembrane conductance regulator (CFTR) targeted correction,
Trikafta (VX-770 + VX-661 + VX-445) was added together with for-
skolin. Organoid swelling was monitored using time-lapse brightfield
imaging (acquired at 10min intervals for 90min) using a Nikon Eclipse
Ti2-E microscope coupled with a Andor Zyla 4.2 sCMOS camera. A
custom-built script was used to quantify organoid swelling. Total
organoid surface area post-forskolin exposure was calculated and
normalized against initial organoid surface area to determine the
relative amount of swelling. The area under the curve (calculated
increase in organoid surface area from t = 0 to t = 90; baseline=100%)
was then calculated using GraphPad Prism.

Reporting summary
Further information on research design is available in the Nature
Portfolio Reporting Summary linked to this article.

Data availability
The datasets generated and/or analyzed in this study are available in
the ProteomeXChangeConsortiumunder accession codePXD038870,
and from the corresponding author upon request.

Code availability
The scripts used for MD simulations can be found on Github (https://
github.com/Ash-Nguyen/Trpzip).

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Acknowledgements
A.K.N. acknowledges scholarship support from the Australian Govern-
ment Research Training Program and the Baxter Family Postgraduate
Scholarship. This work was supported through funding from the Aus-
tralian Research Council Grant FT180100417 (K.A.K.), the National Health
andMedical ResearchCouncilGrant APP1185021 (K.A.K.) andAPP1188987
(S.A.W.), the National Cancer Institute of the National Institutes of Health
Grant R01CA251443 (K.A.K.), and the Sydney Children Hospital Network
Foundation (S.A.W.) andLuminesceAllianceResearchgrants (S.A.W.).We
thank the study participants and their families for their contributions. We
also thank Sydney Children’s Hospitals (SCH) Randwick Cystic Fibrosis
clinic especially Prof Adam Jaffe, A/Prof Keith Ooi, Dr Laura Fawcett, Dr
Yvonne Belessis, Leanne Plush, Amanda Thompson and Rhonda Bell in

the organization and collection of participant biospecimens for miCF
biobank. The authors acknowledge the help and support of staff at the
Katharina Gaus Light Imaging Facility (KGLMF) of the UNSW Mark Wain-
wright Analytical Centre. The authors acknowledge the use of the Cryo
Electron Microscopy Facility through the Victor Chang Cardiac Research
Institute Innovation Centre, funded by the NSW government and the
Electron Microscope Unit at UNSW Sydney. This study used the compu-
tational cluster Katana supported by Research Technology Services at
UNSW Sydney. We would also like to thank the Australian Nuclear Sci-
ence and Technology Organisation (ANSTO) for providing USANS and
SANS beam facilities under proposal number P 14142 for this work.

Author contributions
A.K.N. and K.A.K. conceived and initiated the study. A.K.N. carried out
experiments across the entire range of approaches, analyzed data,
prepared figures, and organized the preparation of the manuscript.
T.G.M. performed SEM imaging, stress-relaxation rheology measure-
ments, 3D bioprinting, cell morphometric analyses, and advised rheo-
logical measurements. E.K. and S.L.W. assisted with adult stem cell
derived organoid culture, performed organoid protein extraction, FIS
imaging, and analyzed FIS data. S.G. assisted with TEM sample pre-
paration and performed TEM imaging. S.C. performed antimicrobial
assays. J.F. assisted with cryo-TEM sample preparation and performed
cryo-TEM imaging. B.E.Y. and J.M. collected SANS and USANS data. J.M.
performed SANS and USANS data analysis. A.V. performed proteomics
data analysis. A.K.N. and K.A.K. wrote the manuscript with input from all
authors. N.K., R.D.T., S.A.W., and K.A.K., supervised the work.

Competing interests
The authors declare no competing interests.

Additional information
Supplementary information The online version contains
supplementary material available at
https://doi.org/10.1038/s41467-023-41907-1.

Correspondence and requests for materials should be addressed to
Kristopher A. Kilian.

Peer review information Nature Communications thanks the anon-
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Nature Communications |         (2023) 14:6604 13

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	Hierarchical assembly of tryptophan zipper peptides into stress-relaxing bioactive hydrogels
	Results and discussion
	Computational screening identifies self-assembling tryptophan zipper variants
	Hydrogel assembly arises from multiscale hierarchical order
	Trpzip hydrogels show tunable mechanics with self-healing and stress relaxation
	Trpzip hydrogels are antimicrobial and support mammalian cell growth
	Trpzip hydrogels can induce polarity changes in human intestinal organoids

	Methods
	Materials
	Molecular dynamics
	Peptide synthesis and purification
	Hydrogel preparation
	Transmission electron microscopy (TEM)
	Circular dichroism (CD)
	Fourier transform infrared spectroscopy (FTIR)
	Small and ultra-small angle neutron scattering (SANS and USANS)
	Scanning electron microscopy (SEM)
	Cryo-TEM
	Rheology
	Cell and organoid culture
	Cell viability assay
	Bioprinting
	Antimicrobial assays
	Organoid encapsulation in Trpzip gels
	Global proteomics
	Fixation and immunofluorescence staining
	Microscopy
	Forskolin-induced swelling assay
	Reporting summary

	Data availability
	Code availability
	References
	Acknowledgements
	Author contributions
	Competing interests
	Additional information