Introduction
Cadherin-based adherens junctions are integral to
epithelial cohesion, by establishing cell -cell adhesion
through cadherin trans -interactions between
neighboring cells and intracellular connections with the
actin cytoskeleton 1. During development and
homeostasis, epithelial cohesion must be tightly
coordinated with morphogenetic movements, which
requires dynamic regulation of the adhesive properties
of cadherin junctions
2–4 . This can be achieved by
regulating the organization of cadherin complexes into
lateral clusters on the cell surface, increasing the avidity
of intrinsically weak cadherin trans -interactions
5–8 .
Across different cell types and species various cadherin
clusters have been identified, ranging from nano- to
microscale supramolecular structures (reviewed by
9,10).
The formation of these clusters is mainly attributed to
cis-interactions between ectodomains of E-cadherin and
association with the actin cytoskeleton that, for instance,
limit lateral diffusion 11– 18. Nonetheless, the molecular
mechanisms regulating clustering, including the
contribution of other cadherin-complex components, is
incompletely understood
10. Moreover, how clustering of
the cadherin complex impacts adhesion dynamics in
epithelial tissues remains to be answered.
Over the last years it has become clear that clustering of
proteins at the membrane, including transmembrane
receptor complexes, is facilitated by liquid -liquid phase
separation (LLPS)
19– 21. This biophysical process
concentrates proteins into biomolecular condensates
through weak multivalent interactions, for instance
between intrinsically disordered regions (IDRs) enriched
for polar, charged or aromatic amino acids
22– 24.
Biomolecular condensates typically exhibit liquid -like
properties, and by locally concentrating proteins these
dynamic structures can catalyze enzymatic reactions,
sequester molecules or serve as a structural
organization platform
25,26. The formation of
condensates has recently been implicated in the
assembly and regulation of cell adhesion complexes
27.
The tight junction (TJ) scaffolding zonula occludens
(ZO) proteins form biomolecular condensates and
thereby organize into membrane -attached
compartments that locally enrich other components of
this complex during formation of nascent TJs
28,29.
Multiple focal adhesion (FA) proteins exhibit
condensation behavior, which contributes to integrin
clustering, and the assembly and dynamics of FAs
30– 32.
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Whether formation of biomolecular condensates also
contributes to the supramolecular organization of other
adhesion complexes, including cadherin- based
adhesions, remains to be determined.
β-Catenin is a central component of the cadherin
complex1. It binds to E -cadherin immediately following
synthesis of E -cadherin at the membrane of the
endoplasmic reticulum, and establishes the link with α-
catenin and consequently the actin cytoskeleton after
their arrival at the plasma membrane
33,34. The cellular
function of β-catenin extends beyond cell-cell adhesion,
as it also acts as transcriptional transactivator in the
Wnt-signaling pathway
35. The transcriptional role of β -
catenin was recently shown to be supported by its
capability to form biomolecular condensates, relying on
weak intermolecular interactions through its structurally
disordered N- and C -termini
36– 38. β-Catenin partitions
into condensates at transcriptional enhancer elements,
thereby promoting transcription of Wnt-target genes
36. In
this study, we investigated whether the condensation of
β-catenin also impacts the formation and organization
of cell-cell junctions. We find that β-catenin forms phase-
separated droplets in vitro in the presence of E-cadherin
and α-catenin and co- partitions these other cadherin
complex components into condensates. Using β-catenin
mutants with impaired condensate formation capacity ,
we demonstrate that β-catenin condensation promotes
its clustering together with E -cadherin and α -catenin at
the cell cortex and facilitates the formation of nascent
cell-cell junctions. Our data thus indicate a role for β-
catenin condensates in the supramolecular organization
of the cadherin complex, and provide evidence for the
importance of cadherin -complex clustering in
establishing adhesion between two opposing cells.
Results
β-Catenin co-partitions with other components of the
cadherin complex in vitro
The contribution of β-catenin condensate formation to
its transcriptional function36 raises the question whether
and how the condensation of β -catenin is linked to its
function in cell -cell adhesion complexes (Fig. 1A , left).
Incorporation in the cadherin complex through
interactions with E-cadherin and α-catenin could impair
β-catenin condensate formation, or alternatively, β -
catenin may integrate these other components of the
cadherin complex into condensates. To test these
possibilities, we analyzed the formation of phase -
separated droplets of purified β -catenin in vitro in the
presence of E -cadherin and α -catenin, using
recombinant β-catenin, the cytosolic tail of E -cadherin,
and α-catenin, conjugated with fluorescent proteins
(mEGFP-β-catenin
Wt, E- cadherincyto-mTagBFP2 and
mCherry-α-catenin, respectively) (Fig. 1A, right).
We and others previously showed that upon induction of
crowding by addition of 10% PEG -8000, mEGFP -β-
catenin partitioned into spherical, micron-sized droplets
in a concentration- dependent manner (refs.
36– 38, Figs.
1B, 1C and S1B). Under similar conditions, E-cadherincyto-
mTagBFP2 did not form droplets (Figs. 1B, 1C and S1B).
However, when combined at equimolar levels, similar to
their stoichiometry at the plasma membrane in cells 33,39,
E-cadherincyto-mTagBFP2 incorporated into droplets of
mEGFP-β-catenin (Figs. 1C and 1D). α-Catenin contains
predicted intrinsically disordered regions (Fig. S1A), and
formed droplets by itself at comparable concentrations
as mEGFP -β-catenin ( Figs. 1B , 1 C and S1B).
Furthermore, mCherry -α-catenin co -partitioned with β-
catenin, both in the absence and presence of E-cadherin
(Figs. 1C, 1D and 1F). In contrast, unconjugated
mTagBFP2 and mCherry controls were not able to form
droplets nor partition into β -catenin droplets (Figs. 1C,
1D and S1C). Live-imaging revealed fusion of proximal
droplets containing β-catenin, E -cadherin
cyto and α-
catenin, supporting their liquid -like properties ( Fig. 1E
and Movies S1-2). Altogether, these data demonstrate
that β-catenin forms phase separated droplets in the
presence of E -cadherin and α -catenin and these other
cadherin complex components co- partition into these
droplets.
We previously identified that condensate formation of β-
catenin relies on weak intermolecular interactions
through aromatic amino acids in its N - and C -terminal
IDRs
36– 38, which do not overlap with the established high-
affinity binding sites in β -catenin for E -cadherin (Fig.
S1D)40– 44. Mutation of these aromatic residues (from
here on referred to as β -cateninIDRs*) diminished the
partitioning of β-catenin, as well as co-partitioning of E -
cadherin and α-catenin (Figs. 1F, 1G, S1B and S1E). The
small fraction of β -cateninIDRs* droplets that did form
contained all three proteins, indicating that the
mutations impair the ability of β-catenin to form droplets
but not its interactions with E -cadherin and α -catenin.
These findings indicate that condensation of β -catenin
drives the concentration of all three core cadherin
complex components into droplets. In line with this, even
though β-catenin and α -catenin both form droplets at
similar concentrations, α -catenin did not co- partition
with E-cadherin
cyto in the absence of β-catenin (Figs. 1C
and 1D). Altogether, these data demonstrate that E -
cadherin and α-catenin co -partition with β -catenin into
phase-separated droplets formed by the IDR -dependent
condensation of β-catenin.
IDR-dependent clustering of β-catenin at the cell cortex
Having established that β-catenin condensation co-
partitions E-cadherin and α-catenin into droplets in vitro,
we made use of β -cateninIDRs* with hampered
condensation to investigate whether this behavior
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Figure 1. Droplet formation assay of β-catenin and components of the cadherin complex in vitro
A. Left: Schematic representation of E -cadherin (E -cad), β-catenin ( β-cat), α-catenin ( α-cat) and F -actin in cadherin -based adherens junctions. Right: Schematic
representation of the experimental procedure of the droplet formation assay. Purified recombinant proteins (mEGFP -β-catWt, mEGFP-β-catIDRs*, E-cadcyto-mTagBFP2
or mCherry-α-cat), or the unconjugated fluorescent proteins (FPs) as control, were mixed together in equimolar concentrations and the formation of droplets in the
mixture was microscopically analyzed. B. Representative images of droplet assay of purified mEGFP-β-catWt, E-cadcyto-mTagBFP2 or mCherry-α-cat (in the presence
of the unconjugated FPs as controls, not shown). All indicated proteins were premixed at a concentration of 1 μM before the addition of 10% PEG- 8000. C.
Quantification of the condensed fraction of purified cadherin/catenin complex components or unconjugated FP controls. The condensed fraction indicates the
percentage of fluorescent intensity inside droplets over the total intensity. Data was normalized t o the mEGFP-β-catWt/mCherry-α-ca/E-cadcyto-mTagBFP2 condition
for each channel separately. Each semi-transparent data point represents an image (n=10), each white datapoint represents mean of independent replicates (N =3),
full darker point indicates the mean of three experiments. Error bars indicate standard deviation between the different indep endent replicates, * p<0.025, **p<0.001
****p < 0.0001; Kruskal- Wallis test and Dunn’s multiple comparison test. D. Representative images of droplet co- partition assay of the indicated purified
cadherin/catenin complex components, or their unconjugated FP counterparts as controls. All indicated proteins were premixed at a concentration of 1 μM before
the addition of 10% PEG-8000. E. Representative still images of fusion events of droplets containing mEGFP -β-cat
Wt (488), mCherry -α-cat (561) and E -cadcyto-
mTagBFP2 (405). The indicated proteins were premixed at a concentration of 1 μM before the addition of 10% PEG- 8000. F. Representative images of droplet co-
partition assay of the indicated purified cadherin/catenin complex components. All indicated proteins were premixed at a concentration of 1 μM before the addition
of 10% PEG-8000. G. Quantification of the fraction of purified cadherin/catenin complex components or unconjugated FPs co- condensed in mEGFP-β-cat droplets,
indicating the percentage of fluorescent intensity inside mEGFP- β-catWt droplets over the total intensity of the image. Data was normalized to the mEGFP -β-
catWt/mCherry-α-cat/E-cadcyto-mTagBFP2 condition for each channel separately. Each semi-transparent data point represents an image (n=10), each white datapoint
represents mean of independent replicates (N=3), full darker point indicates the mean of three experiments . Error bars indicate standard deviation between the
different independent replicates, * p<0.025, **p<0.001 ****p < 0.0001; Kruskal-Wallis test and Dunn’s multiple comparison test. All scale bars represent 2 μm.
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contributes to its organization at cell-cell contacts. Live-
cell imaging of endogenously mEGFP -tagged β-catenin
in the colorectal cancer cell line HCT116, mouse
embryonic stem cells (mESCs) and embryonic kidney
cell line HEK293T displayed a striking organization of β-
catenin into small clusters (~250 – 600 nm in diameter)
along the cell cortex (Fig. 2A, S2A, S2B and Movies S3,
5 and 6 ). Further characterization of HCT116 cells at
varying cell densities revealed that mEGFP -β-catenin
cluster formation was not limited to cell- cell contacts,
but also occurred at free membranes lacking
neighboring cell contacts ( Fig. 2 A and Movie S 3).
Moreover, we occasionally observed the coalescence of
individual cortical mEGFP -β-catenin clusters (Fig. S2C
and Movie S7).
We used the HCT116 cell line to test whether β -catenin
condensation contributes to the formation of these
clusters. For this, we generated β-catenin knock-out (β-
catenin
KO) lines of HCT116 and re -introduced either
wildtype mScarlet- β-catenin (mSc -β-cateninWt) or
mScarlet-β-catenin with mutated IDRs (mSc -β-
cateninIDRs*; Figs. 2B and S2D). Both β -catenin variants
were similarly able to localize to cell- cell contacts ( Fig.
S2E), in line with the notion that the IDRs are not required
for β-catenin to bind E-cadherin (Fig. S1D)
40– 42. However,
the presence of the distinct, small clusters at the cell
cortex observed for β-catenin
Wt was strongly reduced in
cells expressing β-cateninIDRs* ( Figs. 2C -E). Moreover,
exogenously expressed mSc -β-cateninIDRs* did not
incorporate into clusters formed in cells expressing
endogenous β-catenin conjugated to mEGFP, whereas
the distribution of mSc -β-catenin
Wt closely overlapped
with the clusters formed by endogenous mEGFP -β-
catenin (Figs. 2F-H). Similarly, clusters of endogenous
mEGFP-β-catenin at the free membrane selectively
incorporated wildtype β -catenin and not β- cateninIDRs*
(Fig. S2F). Thus, the IDRs of β -catenin are essential for
the formation of β-catenin clusters at the cell cortex, and
β-catenin with hampered condensation capacity fails to
integrate into existing clusters of wildtype β-catenin.
To corroborate our findings indicating a role for β-
catenin condensation in its clustering at the cell cortex
and exclude potential confounding effects of the double
mutated IDRs, we designed additional β-catenin mutants
with impaired condensate formation capacity. We
previously showed that loss of a single β -catenin IDR
severely affects the formation of droplets in vitro ,
implying both the N- and C-terminal IDR are essential for
β-catenin condensate formation
36. We mutated the
aromatic amino acids in only the N- or C-terminal IDR of
β-catenin (referred to as β-cateninnIDR* and β-catenincIDR*,
respectively) and both were sufficient to attenuate the
formation of droplets (Figs. 3A and 3B). When these
mutants were introduced into β-catenin
KO HCT116 cells
(Fig. S3A ) we found that neither of the mutants
efficiently formed clusters at the cell cortex ( Figs. 3C
and 3D), similarly to β -catenin with both IDRs mutated
(Figs. 2D and 2E). These mutants independently link an
inhibition of condensate formation in vitro to the
absence of cluster formation in cells. Thereby, these
mutants corroborate the conclusion that β-catenin
condensation contributes to its clustering at the cell
cortex.
IDR-dependent β-catenin clusters integrate other
components of the cadherin/catenin complex to form
stable adhesion complexes
Next, we aimed to investigate whether IDR -dependent
clustering of β-catenin can drive the clustering of other
components of the cadherin/catenin complex. To this
end, we first co-expressed fluorescently tagged versions
of E-cadherin and α-catenin in HCT116 mEGFP-β-catenin
cells. E -cadherin-mCherry and mCherry -α-catenin
colocalized within the IDR -dependent mEGFP-β-catenin
clusters at the plasma membrane ( Figs. 4A -C). In
contrast, mCherry non- specifically targeted to the
plasma membrane by fusion to a C- terminal plasma
membrane localization signal (CAAX-motif of K-Ras, see
Methods) was not enriched at mEGFP-β-catenin clusters
(Figs. 4A -C). Incorporation of E -cadherin into the IDR -
dependent mEGFP-β-catenin clusters did not rely on its
ability to form trans- or cis-interactions, as N -terminally
truncated E -cadherin lacking these interaction regions
was similarly integrated into mEGFP- β-catenin clusters
(Fig. S4A ). We further excluded that cortical β -catenin
clusters were part of the β-catenin destruction complex,
which mediates β-catenin degradation and was
previously shown to assemble into supramolecular
clusters at the cell cortex in other model systems
45,46.
However, the destruction complex component Axin1
was not detected in the β-catenin clusters at the cell
cortex in HCT116 cells ( Fig. S4B ). Together, these
findings demonstrate that the IDR-dependent mEGFP-β-
catenin clusters represent clustered cadherin
complexes. Next, we tested whether β- catenin
condensate formation is essential for the clustering of
the other cadherin complex components, or if these
instead can independently form clusters. We therefore
exogenously expressed
mE
GFP -α-catenin in β -cateninKO HCT116 cells rescued
with either wildtype or the IDRs -mutated mSc-β-catenin,
which showed that the α-catenin clusters were not
formed in the presence of β-cateninIDRs* ( Fig. 4D -F).
Altogether, our data show that β -catenin condensation
clusters other cadherin complex components and
thereby contributes to their supramolecular organization
at cell-cell contacts.
To further examine IDR-dependent β-catenin clusters, we
applied electron microscopy (EM). We prepared 90-100
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Figure 2. Formation of β-catenin clusters at the cell cortex is dependent on its IDRs
A. Representative confocal images of endogenously tagged mEGFP- β-catenin in HCT116 cells at cell-cell contacts and at the free membrane, with zoom- ins
(yellow box) of individual cell-cell contacts, showing that β-catenin organizes into small clusters at the cortex. Individual clusters are detected by peak detection
on the corresponding line profile of the normalized fluorescent intensity of the junction, indicated by asterisks. See Movies S3 -4 for z-stacks of the displayed
images. B. Left: Western blot of lysates of parental and β-catenin knock-out (KO) HCT116 cells and KO cells with addback of mSc-β-cateninWt, probed for β-catenin
and α-tubulin. Right: Western blot of lysates of β-catenin KO HCT116 cells with addback mSc-β-cateninWt or mSc-β-cateninIDRs* probed for mScarlet and α-tubulin.
Note that the mScarlet antibody was used to compare the expression levels of exogenously expressed wildtype and mutated β-catenin, excluding potential effects
of the introduced mutations in β -catenin on antibody affinity. C. Schematic representation of assay to test β -catenin cluster formation of mSc -β-cateninWt and
mSc-β-cateninIDRs* at cell-cell contacts in β-catenin KO cells. D. Representative confocal images of β-catenin KO HCT116 cells with addback of mSc-β-cateninWt or
mSc-β-cateninIDRs*. Zoom -in shows individual cell-cell contact and its corresponding line profile of the normalized fluorescent intensity and detected peaks
(asterisks). Note that while one of the endogenous β-catenin alleles of HCT116 cells contains a S45 deletion disrupting destruction complex-mediated degradation,
the reintroduced wildtype β-catenin does not, indicating that this mutation is not required for cortical β-catenin cluster formation. E. Quantification of the number
of detected peaks per μm of mSc -β-cateninWt or mSc-β-cateninIDRs* expressed in β-catenin KO HCT116 cells. Each point represents a measurement for a single
cell-cell contact (n = 181 and 186), pooled from three independent measurements (medians of each indicated with circles). ****p < 0.0001 nested t- test. F.
Schematic representation of assay to test integration of exogenously expressed mSc -β-cateninWt or mSc -β-cateninIDRs* into mEGFP -β-catenin clusters of
endogenously tagged HCT116 cells. G . Representative confocal images of individual cell -cell contacts of HCT116 cells expressing both endogenously tagged
mEGFP-β-catenin (green) and exogenously expressed mSc -β-cateninWt or mSc -β-cateninIDRs* (magenta). The corresponding line profiles show the normalized
fluorescent intensity and detected peaks (asterisks) of both fluorophores. The fraction of peaks detected in the mEGFP channe l with an overlapping peak in the
mScarlet channel and the Pearson c orrelation (R2) between the line profiles of the two fluorophores are shown. H. Quantification of the fraction of mEGFP -β-
catenin peaks with an overlapping peak for exogenously expressed mSc-β-cateninWt or mSc-β-cateninIDRs*, respectively, per cell-cell contact. Each point represents
a measurement for a single cell -cell contact (n = 161 and 185), pooled from three independent measurements (medians of each indicated with circles). ***p <
0.001 nested t-test. Scale bars represent 10 μm (overview images) or 1 μm (zoom-ins of individual cell-cell contacts)
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nm cryosections of mEGFP -β-catenin HCT116 cell
monolayers flat-embedded to preserve the orientation of
the cells 47. E ndogenous mEGFP-β-catenin expression
was too low to discern clear sites of enrichment by
immunogold labeling of GFP. To circumvent this, we
imaged the same samples by correlative light -EM
(CLEM) ( Figs. 5A and S5A). Highly sensitive
fluorescence microscopy revealed mEGFP signal was
preserved and well visible , even in ultrathin sections.
Hence, we used mEGFP fluorescence to guide us to β -
catenin labeled regions by light microscopy and
sequentially imaged the same regions by EM. By
overlaying the two images we discerned that clusters of
mEGFP-β-catenin identified by light microscopy
represent cell-cell junctions, typically of a focal nature ,
with high protein densities at the adjacent cytosolic sites
(Figs. 5A and S5A ). The overall cell morphology and of
the identified cell-cell adhesions was similar in classical
resin-embedded EM, validating our CLEM findings ( Fig.
S5B)
48– 50. These results indicate that the IDR-dependent
β-catenin clusters at cell-cell contacts represent sites of
intercellular adhesion. In line with this, mosaic cultures
of mEGFP -β-catenin cells and mSc -β-catenin cells
revealed that the IDR- dependent β-catenin clusters
integrated β-catenin from both cells forming the cell-cell
contact, and thus appear to be part of intercellularly
connected adhesion complexes ( Figs. 5B and 5C).
Furthermore, disruption of the actin network by addition
of Cytoch alasin D altered the organization of the β -
catenin clusters, with individual clusters coalescing into
larger structures , which supports the idea that the se
clusters are engaged with the actin network ( Fig. S5C
and Movie S8).
The identification of cadherin/catenin clusters relying on
β-catenin condensation provides a conundrum, as
biomolecular condensates typically behave as dynamic,
liquid-like structures that appear to be antithetical with
the role of cadherin adhesions as force -bearing
structures
25,26. We therefore assessed the dynamics of
Figure 3. Independent β-catenin IDR-mutants corroborate the importance of β-catenin condensation in cortical cluster formation
A. Representative confocal images of droplet formation assays of purified mEGFP-β-cateninWt, mEGFP-β-cateninIDRs*, mEGFP-β-cateninnIDR* or mEGFP-β-catenincIDR*
in the presence of 10% PEG- 8000. B. Quantification of the partition ratio and condensed fraction of purified mEGFP -β-cateninWt, mEGFP-β-cateninIDRs*, mEGFP-β-
cateninnIDR* or mEGFP-β-catenincIDR* (8 μM). The partition ratio represents the mean intensity inside over outside droplets, while the condensed fraction represen ts
the percentage of fluorescent intensity inside droplets over the total intensity of the image. Each point represents a measur ement from one image (n>8), pooled
from three independent replicates (medians of each indicated with circles). * p<0.025, **p<0.001 ****p < 0.0001; Kruskal-Wallis test and Dunn’s multiple comparison
test. C. Representative confocal images of β-catenin KO HCT116 cells with addback of mSc-β-cateninnIDR* or mSc-β-catenincIDR*, showing individual cell-cell contact
and the corresponding line profile of normalized fluorescent intensity and detected peaks (asterisks). D. Quantification of the number of detected peaks per μm of
mSc-β-cateninnIDR* or mSc-β-catenincIDR* expressed in β-catenin KO HCT116 cells. The median is indicated with a circle and each point represents a measurement for
a single cell-cell contact (n = 92 and 104). All scale bars represent 2 μm (droplet assay, A) or 1 μm (individual cell-cell contacts, D).
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Monster, Manzato et al., 2025 (preprint) 7
β-catenin in the IDR -dependent clusters using
fluorescence recovery after photobleaching (FRAP). This
showed that mE GFP-β-catenin clusters at cell- cell
contacts did not recover beyond the fluorescence levels
of the surrounding membrane outside of the clusters,
indicating that the observed IDR -dependent clusters at
cell-cell contacts are immobile , stable structures ( Fig.
5D, S5D and Movie S9). In contrast, photobleached
clusters at the free membrane exhibited fluorescence
recovery within the cluster, and showed recovery kinetics
of t
1/2 = 17s (Figs. 5E, 5F and Movie S10). These findings
indicate the existence of dynamic IDR-dependent E -
cadherin/β-catenin clusters at the cell cortex outside of
cell-cell contacts. Altogether, our findings support a
model in which IDR -dependent clustering drives the
assembly of dynamic E -cadherin/β-catenin clusters at
the membrane. These clusters can mature into stable
structures upon the formation of cell -cell contacts ,
potentially involving additional anchoring interactions
that render the complex immobile.
The formation of nascent cell- cell adhesions is
promoted by IDR-dependent β-catenin clustering
Clustering of the cadherin complex increases the avidity
of extracellular E-cadherin domains, which can enhance
the probability of forming stable transmembrane
interactions during the formation of de novo cell -cell
adhesions
6–8 . Indeed, the formation of cadherin/catenin
clusters has previously been observed during the
formation of nascent cell-cell adhesions across different
cell types, including epithelial Madin-Darby canine kidney
(MDCK) cells
51– 54. To investigate the role of β -catenin
IDR-dependent clustering during this process, we
depleted endogenous β- catenin from MDCK cells and
reintroduced either wildtype mSc -β-catenin or the
different β-catenin-IDR mutants that are attenuated in
Figure 4. IDR-dependent β-catenin clusters adherens junction components
A. Schematic representation of assay to test enrichment of cadherin complex components (top) and the plasma membrane (visualized with mCherry-CAAX, bottom)
in clusters of endogenously tagged mEGFP-β-catenin in HCT116 cells. B. Representative confocal images of individual cell-cell contacts of HCT116 cells expressing
both endogenously tagged mEGFP -β-catenin (green) and exogenously expressed E -cadherin-mCherry, mCherry -α-catenin or mCherry -CAAX (magenta). The
corresponding line profiles show the normalized fluorescent intensity and detected peaks (asterisks) of both fluorophores. The fraction of peaks detected in the
mEGFP channel with an overlapping peak in the mScarlet channel and the Pearson correlation (R 2) between the line profiles of the two fluorophores are shown. C.
Quantification of the fraction of mEGFP-β-catenin peaks with an overlapping peak for exogenously expressed E-cadherin-mCherry (E-cad), mCherry-α-catenin (α-cat)
or mCherry-CAAX (CAAX), per cell-cell contact. Each point represents a measurement for a single cell-cell contact (n = 115, 128 and 140, respectively), pooled from
three independent measurements (medians of each indicated with circles). ***p < 0.001; ns = not significant; nested one-way ANOVA Tukey’s multiple comparisons
test. D. Schematic representation of assay to test α- catenin clustering in β-catenin knock -out (KO) HCT116 cells with addback of mSc -β-cateninWt or mSc -β-
cateninIDRs*, respectively. E. Representative confocal images of individual cell-cell contacts of β-catenin KO HCT116 cells with addback of mSc-β-cateninWt or mSc-
β-cateninIDRs* (magenta), respectively, coexpressing mEGFP -α-catenin (green). The corresponding line profiles show the normalized fluorescent intensity and
detected peaks (asterisks) of both fluorophores. The fraction of peaks detected in the mScarlet channel with an overlapping peak in the mEGFP channel and the
Pearson correlation (R2) between the line profiles of the two fluorophores are shown. N.A = not applicable, dividing by 0 peaks. F . Quantification of the number of
detected peaks of mEGFP-α-catenin (α-cat) and mS-β-catenin (β-cat) per μm, in β-catenin KO HCT116 cells with addback of wildtype (Wt) or IDRs -mutated (IDRs*)
β-catenin. Each point represents a measurement for a single cell -cell contact (n = 222 and 213), pooled from three independent measurements (medians of each
indicated with circles). ****p < 0.0001; ns = not significant; nested one-way ANOVA Tukey’s multiple comparisons test. All scale bars represent 1 μm.
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Monster, Manzato et al., 2025 (preprint) 8
their ability to form condensates (Figs. S6A and S6B). By
following sparsely seeded single cells over time during
the establishment of de novo cell-cell contacts, we
observed the emergence of cortical β-cateninWt in a
clustered pattern within minutes after initial contact
between protrusions of neighboring cells, similarly to
what has been described previously for E-cadherin (Figs.
6A, 6B and Movies S11 and S15)
55. In cells expressing
either of the three β -catenin IDR mutants, the clustering
of β-catenin in the initial phase of junction formation was
significantly hampered. These mutant cells showed a
strongly reduced presence or complete absence of
cluster formation, with instead a more uniform
appearance of β-catenin at the forming cell-cell contacts
(Figs. 6A, 6B and Movies S12-14).
In wildtype cells, the emergence of β -catenin clusters is
followed by lateral expansion of the new contact site,
Figure 5. Characterization of β-catenin clusters at the free membrane and cell-cell contacts
A. Representative example of correlative Light and Electron Microscopy (CLEM) image of HCT116 cells with endogenously tagged mEG FP-β-catenin in 90-100 nm
thawed cryosections. Light-microscopy (LM) images of mEGFP-β-catenin (green) together with DAPI (blue) were overlayed with EM images with immuno-EM labeling
of mEGFP with 10 nm gold particles. Sites of punctuated mEGFP -β-catenin enrichment typically coincided with the close proximity of membranes of two adjacent
cells and an intracellular electron density (arrowheads). Note that the correlative GFP fluorescence corresponds to sites with immunogold labeling for GFP, aiding
the detection and characterization of these sites. For additional examples, see Fig. S5A. The analysis involved 4 individual samples from 2 biological replicates. N,
nucleus; PM, plasma membrane; V, vesicle. B . Schematic representation of mosaic cultures of HCT116 cells expressing either endogenously tagged mEGFP -β-
catenin, or mSc-β-cateninWt in a β-catenin KO background. C. Representative confocal image of an individual cell -cell contact in a mosaic culture of HCT116 cells
expressing either endogenously tagged mEGFP- β-catenin (green, top cell) or mSc -β-cateninWt in a β -catenin KO background (magenta, bottom cell). The
corresponding line profile shows the normalized fluorescent intensity and detected peaks (asterisks) of both fluorophores in the same colors. The fraction of peaks
detected in the mEGFP channel with an overlapping peak in the mScarlet channel and the Pearson correlation (R2) between the line profiles of the two fluorophores
are shown. D. Representative still images of Fluorescent Recovery After Photobleaching (FRAP) experiment (see Movie S9). A single mEGFP-β-catenin cluster at a
cell-cell contact of endogenously tagged HCT116 cells was photobleached (yellow box, time point 0) and imaged over time. See Fig. S5 D for the quantification of
recovery over time. E. Representative still images of FRAP experiment. A single mEGFP -β-catenin cluster at the free membrane of endogenously tagged HCT116
cells was photobleached (yellow box, time point 0) and imaged over time (see Movie S10). F. Quantification of the normalized fluorescent signal (mean ± SD) before
and after photobleaching of mEGFP-β-catenin clusters at the free membrane (n = 10). Normalized fluorescent intensities of single clusters were measured every 10
seconds (blue dots), and the measurements were fitted to a single exponential curve (blue dotted line ± SD) to calculate the mobile fraction (F mob) and the half-life
recovery time (τ1/2; in seconds). Intensities of a distant region of the junction was similarly measured in each frame (gray line ±SD), to compare the recovered intensity
of the clusters to the intensity level of the linear junction. Scale bars represent 10 μm (overview imag es D, E), 1 μm (single cell -cell contacts; C-E) or 200 nm (EM
image A).
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Monster, Manzato et al., 2025 (preprint) 9
Figure 6. β-Catenin-dependent clustering facilitates junction formation in MDCKs
A. Representative still images (Movies S11 and S12) with zoom-in (bottom) of cluster formation (green arrowheads) during de novo contact formation between
two β-catenin knock-out (KO) MDCK cells with addback of mSc -β-cateninWt or mSc-β-catenincIDR* (Fire LUT). Time point 0 marks initial contact formation. For KO
cells with addback of mSc-β-cateninIDRs* or mSc-β-cateninnIDR*, see Movies S13 and S14, respectively. B. Quantification of the fraction of de novo cell-cell contacts
in β-catenin KO MDCK cells with mSc-β-cateninWt, mSc-β-cateninIDRs*, mSc-β-cateninnIDR* or mSc-β-catenincIDR* addback, showing clustering (green) or no clustering
(grey) and ability to form a linear junction (indicated with cross -hatching). Bars indicate mean fraction ± SD from t hree independent experiments (n = 91, 64, 55
and 73 contacts in total). **p < 0.005 one-way ANOVA with Sidak’s multiple comparison test of clustering capacity. C. Representative time-lapse images (Movies
S15 and S16) of the formation of a de novo cell-cell contact (zoom-in; yellow box) between two β-catenin KO MDCK cells with mSc-β-cateninWt or mSc-β-catenincIDR*
addback (Fire LUT). The onset of cortical β -catenin enrichment (marked by yellow arrowhead) and the completion of a linear contact (final frame) is delayed in
cells expressing mSc -β-catenincIDR* (shown as representative example for all IDR mutants, see Fig. 6D ). Time point 0 marks initial contact formation. D .
Quantification of the onset of cortical β-catenin enrichment after initial contact during de novo junction formation in β-catenin KO MDCK cells with mSc-β-cateninWt,
mSc-β-cateninIDRs*, mSc-β-cateninnIDR* or mSc-β-catenincIDR* addback. Each point represents a measurement for a single de novo cell-cell contact (n = 91, 64, 55 and
73, respectively), pooled from three independent experiments (medians of each indicated with circles). ***p < 0.0005; **p < 0.005; *p < 0.05 nested one-way ANOVA
with Sidak’s multiple comparison test. E. Two representative time-lapse images (Movies S17 and S18) exemplifying the unsuccessful formation of a linear cell -
cell contact between two β-catenin KO MDCK cells with mSc-β-catenincIDR* addback (Fire LUT), showing either the maintenance of dynamic protrusions rather than
the linearization of the contact (top), or the failure to extend the contact and eventual junction breakage (bottom). Time point 0 marks initial contact formation.
Scale bars represent 10 µm (overview images) or 1 µm (zoom-ins of cell-cell contacts).
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Monster, Manzato et al., 2025 (preprint) 10
and the cell -cell contact reorganizes from dynamic
protrusions into a linear junction in which β- catenin
rearranges into a more uniform distribution (Figs. 6A-C,
S6C and Movies S11 and S15). IDR-mutated cells were
able to eventually establish cell- cell contacts after an
extended period of time, indicated by the formation of a
cohesive monolayer (Fig. S6C ). However, mutant cells
showed a significantly decreased efficiency of junction
formation compared to wildtype cells. The rapid cortical
accumulation of β -catenin to the novel contact site of
two neighboring cells observed in wildtype cells was
strongly delayed in all three mutant cell lines ( Figs. 6C,
6D and Movies S12-14, S16). Furthermore, a significant
fraction of cells expressing the β -catenin IDR mutants
completely failed to form a linear cell-cell junction during
the timespan of the experiment (3-4 hrs), with cells either
maintaining dynamic protrusions without junction
linearization or not extending the new contact and
subsequently breaking their junction ( Fig. 6B, E and
Movies S17-18). Defects in junction formation in mutant
cells predominantly occurred between cell-cell contacts
devoid of clustering ( Fig. 6B ), substantiating that IDR-
dependent clustering of the cadherin complex increases
the probability of successful cell-cell contact formation.
Overall, these data demonstrate that β -catenin
condensation facilitates clustering of the
cadherin/catenin cell -cell adhesion complex, and this
clustering contributes to the formation of novel sites of
cell-cell adhesion.
Discussion
In this study, combining in vitro characterizations and
functional cellular analyses , we uncover a role for β-
catenin condensation in the supramolecular
organization of the cadherin complex (Fig. 7 ). We find
that the disordered termini of β- catenin establish the
formation of condensates that incorporate other
components of the cadherin complex and nucleate the
formation of submicron cadherin/catenin clusters. This
β-catenin-dependent clustering is essential for the
efficient formation of de novo cell-cell adhesions,
demonstrating that the function of β -catenin in the
cadherin complex extends beyond connecting cadherin
to α-catenin and the actin cytoskeleton.
From this work and other recent studies, the formation
of biomolecular condensates is emerging as a universal
mechanism driving the assembly and clustering of cell
adhesion complexes
19,20,28–31,56,57 . Across different
adhesions, this involves the condensation of adaptor
proteins that locally concentrate adhesion receptors and
their interacting partners to accommodate their
assembly into supramolecular structures. Our study
demonstrates that β-catenin fulfils this role in the
assembly of cadherin/catenin clusters (Fig. 7 ). As E -
cadherin binds β- catenin after its synthesis and they
traffic together to the plasma membrane
33,34, β-catenin
and E-cadherin may already co-condense together at the
membrane of secretory vesicles or shortly after arrival at
the cell surface. This condensation may be aided by the
dimensionality reduction of the membrane surface,
which could increase the lo cal concentration of β -
catenin above the threshold required for condensate
formation
58– 61. We hypothesize that these membrane-
associated β-catenin biomolecular condensates mature
from dynamic into solid structures capable of enduring
forces. This is in line with β -catenin IDR -dependent
clusters at cell- cell contacts of HCT116 cells
manifesting as immobile structures, whereas clusters at
free membranes display more dynamic behavior.
Condensate maturation is similarly proposed for other
force-bearing biomolecular condensates, including FAs
and centrosomes
62,63, resulting from stabilization of
intrinsic interactions within the condensate and/or
interactions with additional binding partners
64. A
potential candidate controlling the transition of E -
cadherin-associated β-catenin condensates into
immobile clusters is the actin cytoskeleton that rapidly
connects to the cadherin/catenin complex after its
Figure 7. Proposed model of β-catenin condensation-driven clustering of the cadherin/catenin complex
β-Catenin forms biomolecular condensates through its N - and C-terminal intrinsically disordered regions (IDRs). β-Catenin retains this ability when associated with
E-cadherin and thereby integrates E -cadherin into condensates. Consequently, β -catenin drives the formation of submicron clusters of E-cadherin/β-catenin at the
cell cortex (or already at secretory vesicles). These β -catenin IDR-dependent clusters are essential for efficient formation of de novo cell-cell junctions and develop
into sites of adhesion. The maturation of β-catenin IDR-dependent clusters into structures capable of enduring forces may involve linkage to the the actin cytoskeleton
or other interactions, which could potentially immobile the dynamic condensate. Clusters may eventually reorganize into a more uniform junction, as observed in
MDCK cells following the completion of a novel junction formation.
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Monster, Manzato et al., 2025 (preprint) 11
arrival at the plasma membrane 33, akin to the actin -
dependent stabilization of condensates of the TJ-
component ZO 28. The spatiotemporal kinetics of β -
catenin condensation in cells and the factors that
regulate formation and maturation of condensates
warrants further investigation.
We demonstrate that the condensate-forming properties
of β-catenin are indispensable for clustering of the
cadherin/catenin complex in both HCT116 cells and
during nascent junction formation in MDCK cells.
Clustering of the cadherin complex can enhance E-
cadherin transdimerization by increasing the avidity of
this interaction, which aids de novo junction formation as
evidenced by theoretical modeling
6–8 . This role of
cadherin complex clustering is supported by our
experimental findings, showing defects in de novo cell-
cell adhesions when IDR -dependent clustering is
disrupted. β-Catenin-dependent condensation likely acts
in concert with other clustering mechanisms of the
cadherin complex, including cis -interactions between E-
cadherin ectodomains, delimited diffusion by the actin
cytoskeleton, and the involvement of other cadherin-
associated proteins
9,10. These alternative mechanisms
may be preceded by cadherin/ β-catenin condensation,
and immobilize and organize these clusters. In line with
this, disruption of the actin cytoskeleton in HCT116 cells
resulted in individual clusters coalescing into larger
structures, suggesting that actin interactions may
delimit cluster diffusion (Fig. S5C ). C onversely,
alternative clustering mechanisms may also promote
condensate formation by locally concentrating
cadherin/β-catenin complexes. The distinct clustering
mechanisms may be partially redundant, and the
contribution of individual mechanisms potentially
diverges across cell types and species
9,10. Future studies
may resolve the interplay between the various clustering
mechanisms of cadherin adhesions and how they
coordinate the supramolecular organization of adherens
junctions across different cell types.
The observation that β -catenin co-partitions E-cadherin
into droplets in vitro is in line with structural analyses of
the E-cadherin/β-catenin complex, which demonstrated
that the high-affinity binding of β-catenin to E-cadherin is
solely established by the Armadillo domain and does not
involve the termini of β -catenin
40– 42. The IDRs are
therefore expected to remain exposed in the E -
cadherin/β-catenin heterodimer and able to form the
interactions required to establish condensates. Even
though a region of the N- terminal IDR of β -catenin
contributes to α -catenin binding
42,65, we find α -catenin
also to be incorporated into β -catenin droplets in vitro.
Importantly, our functional analyses demonstrate that
mutation of the C -terminal IDR of β -catenin is sufficient
to attenuate E -cadherin/β-catenin clustering and
junction formation, excluding any potential confounding
effects on α -catenin association. Interestingly, we find
that α-catenin also forms phase separated droplets by
itself at similar concentrations as β -catenin, although it
remains to be determined whether this contributes to the
organization of clusters of the cadherin complex (Fig.
1B). In contrast, our findings unambiguously
demonstrate that β-catenin condensation is essential to
drive the incorporation of all three core cadherin
complex components together into droplets (Fig. 1) and
sub-micron clusters at cell-cell contacts (Fig. 2).
The molecular composition of mature adherens
junctions extends far beyond the core components
described in this study
66, and these additional proteins
may influence β -catenin condensates and vice versa.
While disruption of β -catenin condensation is sufficient
to attenuate clustering and junction formation, this does
not exclude that other cadherin -associated proteins (in
addition to α -catenin) may exhibit similar behavior and
contribute to the condensation of the cadherin complex
in cells. For instance, p120-catenin and Afadin, which are
both implicated in clustering and adherens junction
formation
67– 71, both have predicted IDRs 72. Conversely,
in addition to cadherin clustering, β-catenin condensates
may locally concentrate specific cadherin -complex
interactors and thereby accelerate enzymatic
reactions
10. In this way β -catenin condensation could
impact signaling cascades or the activity of actin
cytoskeletal regulators
20, analogous to increased actin
nucleation at Nephrin adhesion receptors that is driven
by Nck/N-WASP condensation
62. How condensation of
β-catenin acts together with other interaction partners of
the cadherin/catenin complex to construct the
supramolecular organization and function of adherens
junctions warrants further investigation.
Materials and methods
Antibodies
The following commercial antibodies were used at the
indicated concentrations for Western blot (WB) and
immunofluorescence (IF): rabbit anti-αE-catenin (Sigma-
Aldrich; C2081; 1:500 IF); r abbit anti -β-catenin (Sigma;
C2206; 1:2500 WB); mouse anti -β-catenin (BD
Biosciences; 9018884; 1:1000 IF); mouse anti -α-tubulin
(DM1A; Calbiochem ; CP06; 1:5000 WB); rat anti- RFP
(5F8; Chromotek; 1:2500 WB); and mouse anti-γ-catenin
(Plakoglobin; Zymed; 13 -8500 1:250 IF). For electron
microscopy, biotin- anti-GFP (Rockland; 600 -106-215;
1:300) and rabbit anti -biotin (Rockland; 100 -4198; 1:10
000) antibodies were used.
Plasmids
Plasmids for bacterial expression were generated by In -
Fusion cloning of the indicated constructs into a pGEX -
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Monster, Manzato et al., 2025 (preprint) 12
2T plasmid: mEGFP, mEGFP-β-cateninWt (NM_001904.4;
36), mEGFP -β-cateninIDRs* 36, mEGFP -β-cateninnIDR* and
mEGFP-β-catenincIDR*, mTagBFP2, E- cadherincyto-
mTagBFP2 (E- cadherin NM_009864.2, amino acids
736– 783; 73) mCherry and mCherry -α-catenin
(NM_009818.1; 73). Lentiviral plasmids were generated
by In -Fusion cloning of the indicated constructs into a
pLV-CMV plasmid: mScarlet -β-cateninWt (NM_001904.4,
36), mScarlet- β-cateninIDRs* 36, mScarlet -β-cateninnIDR*,
mScarlet-β-catenincIDR*, E -cadherinΔecto-mScarlet
(NM_001287125.2, ΔAA166- 708), E- cadherin-mCherry
(NM_001287125.2), mCherry-αE-catenin (NM_009818.1;
74), mCherry -(KRAS)CAAX (amino acids
KMSKDGKKKKKKSKTKCVIM; 75) and mEGFP -α-catenin
(NM_009818.1 76). pcDNA3.1 -Axin1b-mRFP1
(NM_181050.3) was a kind gift from the Maurice lab
(UMC Utrecht, The Netherlands).
Protein purifications
Recombinant proteins were expressed in the E.coli
CK600K or BL21- DE3 Star strain and grown in Nutrient
Broth n1 (Sigma -Aldrich). Following induction with 100
μM IPTG for 14-16 hours at 25°C, cells were harvested by
centrifugation at 4000 rpm for 30 min at 4°C,
resuspended in lysis buffer (50 mM Tris- HCl pH 7.5, 50
mM NaCl, 5 mM EDTA, 5 mM β-mercaptoethanol and 5%
glycerol), lysed by sonication followed centrifugation at
20,000 rpm for 30 min at 4°C. Supernatants were loaded
onto Glutathione Sepharose ® 4B (Merck) beads in
gravity columns (Bio-Rad). Columns were washed twice
with 10 volumes of high salt washing buffer (50 mM Tris-
HCl pH 7.5, 400 mM NaCl, 5 mM β-mercaptoethanol and
5% glycerol), once with 10 volumes of droplet formation
buffer (50 mM Tris -HCl pH 7.5, 125 mM NaCl, 10%
glycerol, 1mM DTT) and once with TEV protease buffer
(50 mM Tris– HCl pH 8.0, 0.5 mM EDTA and 1 mM DTT).
TEV protease His-6 (Protean) cleavage was performed
with 1.5 kU of the enzyme in 4 ml of TEV protease buffer
overnight, and cleaved proteins were eluted with 2
volumes of TEV protease buffer. Proteins were further
purified by gel filtration chromatography (Superdex 200
HiLoad 16/60 GE; Healthcare) in 20 mM Tris– HCl pH 8.0,
125 mM NaCl, and 1 mM DTT. For α-catenin, specifically
the monomeric pool was collected.
Droplet assays
Recombinant proteins were diluted at indicated
concentrations in droplet formation buffer (50 mM Tris-
HCl pH 7.5, 125 mM NaCl, 10% glycerol, 1 mM DTT). After
addition of 10% PEG -8000 the protein solution was
immediately loaded onto microscope slides as a single
drop. Slides were imaged with spinning disk confocal
microscope (Nikon Ti2) with Apo TIRF 60x Oil DIC N2
lens or spinning disk CSU X1 Nikon Ti with Plan Apo VC
60x N.A. 1.40 oil. Images were post-processed to correct
for channel misalignment. Quantif ications were
performed according to a previously established
pipeline
77, the code for this analysis is available at the
following Github link: https://github.com/krishna-
shrinivas/2020_Henninger_Oksuz_Shrinivas_RNA_feed
back/tree/master/Droplet_analysis. Droplets were
segmented by intensity, size and circularity thresholds
and their intensity was calculated. The mean intensity of
each droplet (C -in) and of the bulk (C -out) were
calculated for each channel. The partition ratio was
computed as (C -in)/(C-out), as a proxy for average per
droplet concentration of fluorescent protein inside the
condensates over the concentration of fluorescent
protein outside the condensates. For each image, t he
total intensity of each droplet was calculated and then
the sum was computed (TC-in) as well as the total bulk
intensity of the whole field (TC -out). The condensed
fraction was computed as (TC -in)/(TC-out), as a
measure of the total amount of fluorescent protein
inside the condensates over the total amount of
fluorescent protein in a given image. Quantification data
was filtered to exclude droplets with partition ratios
lower than 1.1 for mCherry and mEGFP channels and
lower than 1.35 for mTagBFP2 to correct for mEGFP
bleedthrough. Two types of analysis were performed,
one in which all the droplets for all the channels were
considered for the condensed fraction (Figs. 1C and 3B)
and one in which the droplet mask of β-catenin was used
as a scaffold (β-catenin co-condensed fraction; Fig. 1G).
Cell lines and culture
MDCK GII cells were cultured at 37°C and 5% CO2 in low-
glucose DMEM (Sigma; D5523-10L) supplemented with
10% FBS (Sigma; F7524 -500ML), 1 g/liter sodium
bicarbonate, and Penicillin- Streptomycin (Lonza; LO
DE17-602E). HCT116 and HEK293T cells were cultured
in high -glucose DMEM (Sigma; D6429- 24X500ML)
supplemented with 10% FBS and Penicillin-
Streptomycin. V6.5 murine embryonic stem cells were
cultured at 37°C and 5% CO
2 on 0.2% gelatinized tissue
culture plates in 2i + LIF media, composed of DMEM/F12
(Lonza; BE04 -687F/U1), N2 supplement (GIBCO;
17502048), B27 supplement (GIBCO; 17504001), 0.5 mM
L-glutamine (Lonza; LO BE17- 605E), 0.5X non -essential
amino acids (Lonza; LO BE13- 114E), Penicillin -
Streptomycin, 0.1 mM β-mercaptoethanol (Sigma;
M6250), 1 uM PD0325901 (Selleckchem; S1036), 3 uM
CHIR99021 (Selleckchem; S2924), and 1000 U/mL
recombinant LIF (Millipore; ESG1107). Live -cell imaging
experiments were performed under the same culture
conditions. All cell lines we re regularly tested for the
absence of mycoplasma.
Cell lines in which β-catenin is endogenously tagged with
3x mEGFP have been previously described
36. Knock-out
lines for β -catenin in HCT116 and MDCK cells were
generated by CRISPR -Cas9, by transfection of
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Monster, Manzato et al., 2025 (preprint) 13
pSpCas9(BB)-2A-GFP (Addgene #48138) with gRNA
sequence (5 ’-GTTCCCACTCATACAGGACTTGG-3’)
targeting human and canine β -catenin, using
Lipofectamine LTX or Lipofectamine 3000, respectively.
Two days following transfection, GFP-positive cells were
sorted by FACS in 96 -wells culture plates to obtain
monoclonal lines. Clones were screened for successful
knock-out of β- catenin by immunofluorescence, and
validated by both western blotting and sequencing of the
genomic locus.
Stable lines of HCT116 and MDCK cells expressing
indicated constructs were generated using lentiviral
transductions followed by selection with Puromycin (Bio
connect; SC-108071B) or Blasticidin (Bio Connect; ant-bl-
1). In HCT116 and MDCK β -catenin knockout lines in
which mSc -β-catenin
Wt or mSc -β-cateninIDRs* were re-
expressed, cells were sorted by FACS to obtain
monoclonal lines. Plasmids E -cadherin
Δecto-mScarlet
and Axin1 -mRFP1 were transiently transfected in
HCT116 cells using Lipofectamine LTX and imaged two
days later.
Live-cell microscopy and analyses
For live-cell imaging, cells were seeded on glass-bottom
dishes (Lab -Tek II) precoated with Rat Tail Collagen I
(Corning). Cells were imaged on a Nikon Spinning Disc
confocal microscope using a 60× objective (NA = 1.49).
Imaging was performed at 37 C° and 5% CO2 in
temperature- and CO2-controlled incubators, using NIS-
Elements software. To study the effect of actomyosin
disruption, Cytochalasin D was added during image
acquisition at a concentration of 2 µg/ml.
For the detection of β -catenin clusters at cell -cell
contacts, lines (4 pixels wide) were manually drawn over
cell-cell contacts with a clear linear morphology using
ImageJ Fiji software
78. Only cells with comparable levels
of exogenous protein expression were included in the
analyses. Line profiles were normalized to the 20
th - 40th
lowest intensity values. Individual clusters were
detected using BAR plugin Find Peaks
79, with a minimal
peak amplitude of 50% (for endogenously tagged
mEGFP-β-catenin) or 25% (for exogenously expressed
mEGFP-β-catenin). For the quantification of number of
peaks per µm, detected peaks were manually verified,
blindly. The fraction of overlapping peaks was
determined by counting the number of mEGFP peaks per
cell-cell contact that had an mSc or mCherry peak
detected within 3 pixels distance. The size of mEGFP -β-
catenin clusters was determined by fitting a Gaussian
function to line profiles of in dividual clusters and
calculating the full -width at half -maximum ( 𝐹𝐹𝐹𝐹𝐹𝐹𝐹𝐹=
2�2 𝑙𝑙𝑙𝑙( 2)
𝜎𝜎) from the extrapolated standard deviation
(σ). All statistical analyses as indicated in the figure
legends were performed using Prism 8 software
(GraphPad). Data were tested for normality, with two-
sided tests employed unless otherwise specified, and
corrections for multiple comparisons were made when
indicated.
For the observation of in vitro droplets fusion events,
samples were prepared as explained in the droplet
assays method and images were acquired every 3,16 s.
Cell-cell junction formation
To analyze de novo junction formation, sub -confluent
MDCK cells were trypsinized and sparsely seeded as
single cells on collagen- coated glass -bottom dishes.
After attachment and spreading of cells (~2 hours), cells
were imaged at a time interval of 2 -3 minutes for 3 -4
hours, allowing single cells to migrate towards other
cells and form new contacts. De novo contacts were
manually scored for the duration from the first contact
between cells until the start of cortical β -catenin signal
appeared, for the presence of clusters du ring junction
formation, and for the successful establishment of a
linear junction (i.e. extension of the contact with no
junction breakage or failure to reduce dynamic
protrusions). All statistical analyses as indicated in the
figure legends were performed using Prism 8 software
(GraphPad). Data were tested for normality, with two -
sided tests employed unless otherwise specified, and
corrections for multiple comparisons were made when
indicated.
Immunostainings
For immunostainings, confluent cell monolayers grown
on collagen-coated glass-bottom dishes were fixed with
4% paraformaldehyde (PFA; Sigma- Aldrich);
permeabilized with 0.2% Triton X- 100 (Sigma- Aldrich);
blocked in buffer containing 1% BSA (Sigma-Aldrich), 1%
goat serum (Life Technologies), and 1% donkey serum
(Jackson Immunoresearch); and incubated with the
indicated primary and Alexa -conjugated secondary
antibodies (Life Technologies), together with DAPI
(Sigma-Aldrich) where indicated. Cells were analyzed on
a Zeiss LSM880 scanning confocal microscope using a
63× objective (NA = 1.15), using Zen image acquisition
software.
Fluorescent Recovery After Photobleaching (FRAP)
FRAP experiments were performed on a Zeiss LSM880
scanning confocal microscope using a 63× objective
(NA = 1.15), using Zen image acquisition software, or on
a Nikon Spinning Disc confocal microscope with a FRAP
module (OMS) using a 60× objective (NA = 1.42), using
NIS-Elements software. Imaging was performed at 37 C°
and 5% CO2 in temperature - and CO2- controlled
incubators. Individual clusters were bleached using
100% laser power and imaged over time (5-9.5 minutes)
with a 10 second interval in a z-stack (5x 0.5 µm interval).
Fluorescent intensities were measured using ImageJ
78
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Monster, Manzato et al., 2025 (preprint) 14
by manually drawing ROIs over individual clusters and a
concomitant distal region at the junction within
maximum projections for each time frame. Background-
subtracted florescent intensity values were normalized
to the pre -bleaching and immediate post -bleach mean
intensities. To calculate the mobile fraction (F
mob) and
the half -life recovery time ( τ1/2), the average of 15
replicates was fitted to a single exponential curve in
Prism 8 software (GraphPad):
𝑌𝑌(𝑡𝑡) = 𝑌𝑌(0) + (𝐹𝐹
𝑚𝑚𝑚𝑚𝑚𝑚− 𝑌𝑌(0)) ∗ (1 − e
− 𝑡𝑡 ln(2)
𝜏𝜏1/2 )
Correlative Light Electron Microscopy (CLEM)
CLEM was performed as described in detail in 80,81.
HCT116 cells expressing endogenously tagged
3xmEGFP-β-catenin were seeded on carbon- and
collagen-coated coverslips and fixed in 2% PFA and 0.2%
glutaraldehyde (GA). Cells were washed with PBS,
incubated in PBS/0.15% glycine for 10 minutes, washed
with PBS/0.1% BSA and incubated with 12% gelatin
(Merck; G1890) at 37⁰C for 30 minutes. The 12% gelatin
was then solidified at 4 ⁰C for 30 minutes, and the
coverslips were incubated with 2.3 M sucrose for 48
hours at 4 ⁰C. After incubation, the gelatin, including
embedded cells, had spontaneously detached from the
coverslip. The gelatin embedded cell layer was then cut
into blocks of ~1 mm
3 and mounted on pins with cell
bottoms facing up and snap -frozen and stored in liquid
nitrogen.
Samples were cryosectioned into ribbons of 90 -100nm
ultrathin sections and deposited on grids (Cell
Microscopy Core, UMC Utrecht). The grids were
incubated with PBS/0.15% glycine for 30 minutes at
37⁰C, rinsed with PBS and incubated with 10 µg/mL DAPI
in 0.1% BSA -c (Aurion; 900.099) and 0.5% fish skin
gelatin (Sigma-Aldrich; G7765) in PBS (BSA -c/FSG) for
20 minutes. Grids were then washed 5x in PBS and 2x in
50% glycerol in 0.1 M PHEM (EMS; 11162) before being
submerged in 50% glycerol in 0.1 M PHEM and
sandwiched between a coverslip and glass slide. The
sections were imaged for mEGFP signal and DAPI in this
configuration on a Leica thunder widefield microscope
with 100x objective (NA = 1.47), Photometrics prime 95B
sCMOS camera and LAS X software. After ima ge
collection of the whole ribbon of sections, the grids were
retrieved, washed 3x in PBS and incubated with BSA -
c/FSG) for 10 minutes. Next, we labeled grids with biotin-
anti-GFP antibody (Rockland; 600 -106-215; 1:300) in
BSA-c/FSG for 1 hour. Grids were then washed 5x in
PBS/0.1% BSA and incubated with bridging rabbit anti -
biotin antibody (Rockland; 100 -4198; 1:10000) in BSA-
c/FSG for 20 minutes, followed by 5 more PBS/0.1% BSA
washes and incubation with Protein- A conjugated to
10nm gold particles (Cell Microscopy Core, UMC Utrecht;
PAG10; 1:50) in BSA- c/FSG for 20 min. Grids were then
washed 5x with PBS, incubated with 1% GA in 0.1M
phosphate buffer, 2x PBS, 8x milliQ, and contrasted
using uranylacetate pH 7 (5 min) and
uranylacetate:methylcellulose pH 4 (10 minutes, 4⁰C).
Excess uranyl was blotted away and grids were dried
using the ‘loop -out’ method
81. The dried grids were
imaged in a FEI Tecnai T12 transmission electron
microscope (TEM) with Veleta VEL -FEI-TEC12-TEM
camera and SerialEM software. Regions selected by the
fluorescence images were correlated and imaged at
50,000x magnification in TEM. The obtained image
tilesets were correlated based on DAPI signal and
nuclear outlines using ImageJ Fiji software
78.
Electron Microscopy of resin-embedded cells
HCT116 3xmEGFP-β-catenin cells (the same cell line as
used in the CLEM experiments) were seeded in 3 cm
dishes 24 h prior to fixation. Fixative consisted of 2.5%
GA and 2% PFA in 0.1 M PHEM buffer and was added 1:1
to cell culture medium for 5 min at RT. Culture medium
and fixative were then replaced with fixative alone for 2
h at RT. Samples were then stored in 0.5 PFA in 0.1 M
PHEM at 4⁰C. For contrasting, 1% OsO4 was used for 1
h. After a dehydration series in ethanol, samples were
further processed in EPON in increasing concentrations
and finally embedded in 100% EPON. EPON was
polymerized for 5 d at 60°C.
These resin embedded samples were prepared for thin
sectioning by removal from the culture dish, cutting out
a rectangle of ∼0.5 by 1 mm and mounting, bottom side
up, on an EPON stub. We proceeded by cutting 60−70 nm
sections on a Leica Ultracut S (Leica microsystems)
using a DiATOME Ultra Diamond Knife 45° . Sections
were placed on Formvar - and carbon- coated copper
grids and poststained in a Leica EM AC20 (Leica
microsystems) using uranyl and lead citrate. Samples
were imaged on a Tecnai T20 (FEI Tecnai) TEM using
Radius software.
PONDR disorder score prediction
Disorder scores were calculated with the PONDR web
tool: http://www.pondr.com.
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Data availability
Source data are provided with this paper. Original
imaging data is available upon request.
Acknowledgements
We thank Ilya Grigoriev and Anna Akhmanova at Cell
Biology, Utrecht University (Utrecht, The Netherlands) for
the use of the spinning-disc confocal microscope for the
droplet assay experiments, the Cell Microscopy Core
UMC Utrecht for providing training, reagents and
equipment for the EM experiments, and members of our
laboratories for helpful discussions. This work was
supported by the Dutch Cancer Foundation (KWF- 12345
and 13589) and the Netherlands Organization for
Scientific Research (NWO; 016.Vidi.189.166, NWO
gravitational program CancerGenomiCs.nl 024.001.028,
and the Science-XL research program The Active Matter
Physics of Collective Metastasis 2019.022). The CLEM
infrastructure used in this work is part of the Netherlands
Electron Microscopy Infrastructure (NEMI), a National
Roadmap program for Large- Scale Research
Infrastructure, which is financed by the Dutch Research
Council (project number 184.034.014 to J.K.).
The authors declare that they have no known competing
financial interests or personal relationships that could
have appeared to influence the work reported in this
paper.
Author contributions
J.L.M., J.S. and M.G. conceived the study, J.L.M., C.M.,
W.J.P. and J.A.H. performed experiments and analyzed
data. J.A.B., C.H., and J.K. performed and supervised the
EM experiments. M.H. assisted with the purification of
recombinant proteins. M.G. supervised the study, and
J.L.M. and M.G. wrote the manuscript with input from all
authors
(which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
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