The morphogenetic remodelling of embryo architecture after implantation culminates in pro-amniotic cavity formation. Despite its key importance, how this transformation occurs remains unknown. Here, we apply high-resolution imaging of embryos developing in vivo and in vitro, spatial RNA sequencing and 3D trophoblast stem cell models to determine the sequence and mechanisms of these remodelling events. We show that cavitation of the embryonic tissue is followed by folding of extra-embryonic tissue to mediate the formation of a second extra-embryonic cavity. Concomitantly, at the boundary between embryonic and extra-embryonic tissues, a hybrid 3D rosette forms. Resolution of this rosette enables the embryonic cavity to invade the extra-embryonic tissue. Subsequently, β1-integrin signalling mediates the formation of multiple extra-embryonic 3D rosettes. Podocalyxin exocytosis leads to their polarized resolution, permitting the extension of embryonic and extra-embryonic cavities and their fusion into a unified pro-amniotic cavity. These morphogenetic transformations of embryogenesis reveal a previously unappreciated mechanism for lumen expansion and fusionThe M.Z.G lab is supported by grants from the European Research Council (669198) and the Welcome Trust (098287/Z/12/Z) and the EU Horizon 2020 Marie Sklodowska-Curie actions (ImageInLife,721537). C.K is supported by BBSRC Doctoral training studentship

A Villasenor

Antonia Weberling

C Trapnell

C Willenborg

Christos Kyprianou

D Kim

DM Bryant

E Hoijman

F Hong

G Kesavan

G Peng

G Trichas

Guangdun Peng

Guizhong Cui

HP Shih

I Bedzhov

J Chen

J Riedl

J Rossant

JA Rivera-Perez

JJ Jung

JL Lee

JT Blankenship

LE Stephens

M Barczyk

Magdalena Zernicka-Goetz

MD Muzumdar

MF Portereiko

MJ Harding

MN Shahbazi

Naihe Jing

Neophytos Christodoulou

PS Mrozowska

R Hiramatsu

Ran Wang

RM Kao

SJ Arnold

SL Ang

T Sakai

T Takeda

W Huang da

WE Johnson

Y Kojima

Y Ohinata

Z Yang

English

The morphogenetic remodelling of embryo architecture after implantation culminates in pro-amniotic cavity formation. Despite its key importance, how this transformation occurs remains unknown. Here, we apply high-resolution imaging of embryos developing in vivo and in vitro, spatial RNA sequencing and 3D trophoblast stem cell models to determine the sequence and mechanisms of these remodelling events. We show that cavitation of the embryonic tissue is followed by folding of extra-embryonic tissue to mediate the formation of a second extra-embryonic cavity. Concomitantly, at the boundary between embryonic and extra-embryonic tissues, a hybrid 3D rosette forms. Resolution of this rosette enables the embryonic cavity to invade the extra-embryonic tissue. Subsequently, β1-integrin signalling mediates the formation of multiple extra-embryonic 3D rosettes. Podocalyxin exocytosis leads to their polarized resolution, permitting the extension of embryonic and extra-embryonic cavities and their fusion into a unified pro-amniotic cavity. These morphogenetic transformations of embryogenesis reveal a previously unappreciated mechanism for lumen expansion and fusion

Christodoulou, Neophytos

Kyprianou, Christos

Weberling, Antonia

Wang, Ran

Cui, Guizhong

Peng, Guangdun

Jing, Naihe

Zernicka-Goetz, Magdalena

Caltech Authors - Main

Articles
https://doi.org/10.1038/s41556-018-0211-3
Sequential formation and resolution of multiple 
rosettes drive embryo remodelling after 
implantation
Neophytos Christodoulou1,4, Christos Kyprianou1,4, Antonia Weberling1, Ran Wang2, Guizhong Cui2, 
Guangdun Peng   2, Naihe Jing   2,3 and Magdalena Zernicka-Goetz   1*
1Mammalian Embryo and Stem Cell Group, Department of Physiology, Development and Neuroscience, University of Cambridge, Cambridge, UK.  
2State Key Laboratory of Cell Biology, CAS Center for Excellence in Molecular Cell Science, Shanghai Institute of Biochemistry and Cell Biology,  
Chinese Academy of Sciences, University of Chinese Academy of Sciences, Shanghai, China. 3School of Life Science and Technology, ShanghaiTech 
University,  
Shanghai, China. 4These authors contributed equally: Neophytos Christodoulou, Christos Kyprianou. *e-mail: mz205@cam.ac.uk
SUPPLEMENTARY INFORMATION
In the format provided by the authors and unedited.
NAtuRe Cell BioloGy | VOL 20 | NOVEMBER 2018 | 1278–1289 | www.nature.com/naturecellbiology1278
 
 
 
 
 
Supplementary Figure 1 
Analysis of extra-embryonic ectoderm tissue folding in embryos derived after decidua fixation 
 (a) Experimental strategy for post-fixation embryo recovery. (b) Representative E5.0 recovered from a fixed 
decidua. Accumulation of actin and phosphorylated myosin (arrows) is evident at the proximal tip of extra-
embryonic ectoderm cells in recovered embryos post-fixation. This indicates that apical actin accumulation and 
apical constriction tissue folding (see Fig. 1) is an active morphogenetic process and not a wound healing 
response stemming from the recovery of embryos from deciduae. (c) 3 representative examples of E5.0 
embryos recovered from fixed deciduae. Arrows indicate actin apical accumulation at extra-embryonic 
ectoderm most proximal cells. Image represents 3 biological replicates. Scale bars= 20um. 
 
 
 
 
 
 
Supplementary Figure 2 
ECM/ β1-integrin during extra-embryonic ectoderm and TSCs polarization 
 (a) ECM/ β1-integrin localization in E5.5 embryo revealed by antibodies for laminin, β1-integrin and active β1-
integrin (9EG7). Image representative of 10 embryos (b) Representative examples of TSC clumps culture in 
suspension in the presence or absence of Matrigel. In the absence of Matrigel TSCs fail to polarize. Specifically 
the cells fail to acquire columnar morphology (indicated by F-actin staining) and they don’t display apical Golgi 
polarization (GM130 staining; arrowheads) compared with TSCs cultured in the presence of Matrigel.  Image 
representative of 3 biological replicates (c) The effect of collagenase IV (COLIV) treatment on the surrounding 
basement membrane (assessed by laminin, collagen and perlecan staining) of E5.5 embryos cultured for 5h in 
the presence or absence of COLIV. Image representative of 5 biological replicates (d) β1-integrin activation 
status (indicated by 9EG7 antibody staining) in control and COLIV treated embryos. White arrowheads indicate 
basal site of ExE outside cells. Image representative of 2 biological replicates (e) The effect of COLIV 
treatment on the localization of the tight junction’s localisation assessed by ZO-1 staining in E5.5 embryos (two 
different z slices in control embryo; Z1 and Z2). Arrows point to apical site while arrowheads point towards the 
basal site. Image representative of 10 embryos (f) β1-integrin activation status (indicated by 9EG7 antibody 
staining) in control and β1-integrin blocking antibody (Ha2/5) treated TSCs in 3D culture; Image representative 
of  2 biological replicates. Scale bars=20um 
 
 
 
 
 
 
Supplementary Figure 3 
Characterization of extra-embryonic ectoderm cells 
 (a) Images of different Z slices (0.8 um) from a representative E5.5 (Stage III) embryo. Extra-embryonic 
ectoderm (ExE) rosettes are outlined with a dashed line. Arrows denote rosettes’ centre. Image representative of 
20 embryos (b) Representative example of an ExE rosette (dashed outline) found in E5.5 embryo as revealed by 
cell morphology (E-cadherin) and polarization (ZO-1). Orthogonal views (XZ, YZ) of the embryo are displayed 
on the right and the bottom of the image with the segmented rosette as viewed in the respective orthoslice. 
Image representative of 20 embryos. (c) Cell aspect ratio comparison of outside, inside vs inside cells that 
contribute to rosettes (Inside cells, R). Two sided unpaired student t-test;****p<0.0001;mean± SEM; n=50 
inside cells and n=47 inside rosette cells. (d) Plot of long and short axis. Two separate clusters are indicated 
(magenta and grey outlines). Cluster shown with magenta consists of outside cells and inside cells contributing 
to rosettes (inside cells R). Cluster shown with grey consists of inside cells that do not contribute to rosettes. 
Blue dashed line: y=x. n=50 outside and inside cells and n=47 inside rosette cells. Scale bars=20um 
 
 
 
 
 
 
Supplementary Figure 4 
Epiblast remodelling upon hybrid rosette resolution 
Stills from a time lapse movie of a LifeAct-GFP embryo showing epiblast EPI remodelling after hybrid rosette 
resolution. Cells are arbitrarily colour-coded for tracking. EPI: purple, yellow and cyan cells; ExE: blue, red and 
green cells. Image representative of 3 embryos. Scale bar=20um 
 
 
 
 
 
 
Supplementary Figure 5 
Extra-embryonic ectoderm rosettes facilitate cavities extension and fusion 
 (a) Representative example of E5.5 (stage III) embryo stained for E-Cadherin. White dots label the cells 
contributing to the epiblast (EPI) cavity’s proximal rosette (adjacent to EPI-ExE boundary). Image 
representative of 15 embryos. (b) Example of a resolving EPI cavity’s proximal rosette (dots show cells 
contributing to the rosette) through loss of cell-cell contacts (cells marked with hollow dots) of ExE cells at the 
boundary. YZ projection is displayed on the right of the image. Image representative of 10 embryos (c) Stills 
from a time lapse movie of an E5.5 LifeAct-GFP embryo showing EPI cavity expansion after EPI cavity’s 
proximal rosette resolution. Cells are arbitrarily color-coded for tracking. Image representative of 3 embryos 
(d)E5.5 (stage III) embryo stained for E-Cadherin and tight junction protein ZO-1. Two different z slices are 
presented (Z0 and Z17, Z step=0.8 um) one showing the ExE cavity and the other the overlaying rosette (white 
dots). YZ projection of rosette (white dots showing cells contributing to rosette) and ExE cavities shown on the 
far right of the panel. *=ExE cavity, **=EPI cavity. Image representative of 10 embryos. (e) Representative 
example of ExE cavity (asterisk in YZ projections, right panel) connected with the centre of an ExE cavity 
proximal rosette (arrowhead points to the centre of this rosette; magenta dots indicate cells contributing to both 
rosette and ExE cavity where white dots indicate the rest of rosette’s cells) through a tract of ZO-1 (arrow). 
White dotted line = EPI-ExE boundary. *=ExE cavity, **=EPI cavity. Image representative of 10 embryos. (f) 
Two representative examples of an invading EPI cavity and an extended ExE cavity connected with a polarized 
tract of ZO-1 (white circle). Image representative of 6 embryos. Scale bars = 20um 
 
 
 
 
 
Supplementary Figure 6 
Spatial transcriptome analysis of E5.25-E5.75 embryos 
 (a) Principal component analysis (PCA) of sections along the proximo-distal embryo axis from at E5.25, E5.5 
and E5.75.  Yellow outline: VE, Purple outline: epiblast (EPI), Cyan outline: extra-embryonic ectoderm (ExE). 
(b) Gene expression pattern for EPI (Pou5f1) and ExE (CDX2) markers from E5.25-E5.75. (c) Gene expression 
pattern for Wnt3 and T from E5.25-E5.75. (d) Differential gene expression analysis heat maps for GO term: 
integrin mediated signalling. E5.25: sections 2-4 EPI, sections 6-8 ExE ; E5.5: sections 2,4,5 EPI, sections 6-11 
ExE. 
 
 
 
 
 
 
Supplementary Figure 7 
Differential gene expression analysis of embryonic and extra-embryonic compartments 
 (a)Differential gene expression analysis heat maps between epiblast (EPI) and extra-embryonic ectoderm (ExE) 
in E5.25, E5.5 and E5.75 embryos. Representative gene ontology (G0) terms enriched in each tissue are shown 
on the right of each heat map. E5.25: sections 2-4 EPI, sections 6-8 ExE; E5.5: sections 2,4,5 EPI, sections 6-11 
ExE; E5.75 sections 3-8 EPI, sections 9-19 ExE. n=1 E5.25, n=1 E5.5 and n=1 E5.75 embryos (b) Combined 
principal component analysis (PCA) for embryonic and extra-embryonic sections from E5.25-E5.75. Purple 
outline: E5.25-E5.5 EPI; Cyan outline: E5.25-E5.5 ExE; Dashed purple outline: E5.75 EPI; Dashed cyan 
outline: E5.75 ExE. n=1 E5.25, n=1 E5.5 and n=1 E5.75 embryos 
 
 
 
 
 
 
Supplementary Figure 8 
Cell intercalation after initial cavities fusion results in the formation of a pseudostratified epithelium  
 (a)ExE acquires a pseudostratified epithelium morphology shortly after unification of the cavities. Image 
representative of 10 embryos. (b)After cavities fusion ExE cells show intercalative behaviour (green and yellow 
asterisks). Image representative of 5 embryos. (c) 3 different optical Z slices (0.6um) of a representative 
example of an E5.75(stage IV) embryo. Dashed outline in left panel shows pro-amniotic cavity spanning 
through EPI and ExE. In different Z slices (middle and right panel) ExE cells intercalating towards the 
basement membrane can be identified. Polarized pMLC localization displays the polarized nature of this event. 
Insets in middle and right panel show magnified fluorescent intensity color coded images of ExE intercalating 
cells. Image representative of 5 embryos. Scale bars=20um 
 
 
 
 
Supplementary Table 1: Processed RNA-seq data. 
 
Supplementary Table 2: Statistics source data 
 
Supplementary Movie 1.  Tissue folding mediated extra-embryonic cavity formation 
Time lapse movie (2D view) of a representative E5.0 Lifeact-GFP transgenic embryo showing tissue bending 
mediated extra-embryonic cavity formation. Representative of 5 separate time-lapse movies Time 
interval=5min. 
 
Supplementary Movie 2. Tissue folding mediated extra-embryonic cavity formation in 3D 
Top 3D view of Movie S1 showing apical constriction mediated cell ingression during extra-embryonic 
ectoderm cavity formation. Time interval=5min Representative of 5 separate time-lapse movies. 
 
Supplementary  Movie 3. Apical constriction during extra-embryonic ectoderm tissue folding 
Time lapse movie showing two different single cells from movie S2. Note the increase of medioapical actin 
before apical cell constriction. Time interval=5 min. 
 
 
 
Supplementary  Movie 4. 3D segmentation of representative extra-embryonic ectoderm rosettes 
3D segmentation of a representative extra-embryonic ectoderm rosette. Each rosette cell is represented with 
different colour. White circle highlights the rosette center. 
 
Supplementary  Movie 5. 3D segmentation of neighboring extra-embryonic ectoderm rosettes 
3D segmentation of a representative extra-embryonic ectoderm rosettes sharing cells. Each cell is represented 
with different colour. 
 
Supplementary Movie 6. Hybrid rosette resolution precedes epiblast remodelling(1).  
Time lapse movie of a representative E5.5 Lifeact-GFP transgenic embryo showing epiblast remodelling after 
hybrid rosette resolution. Time interval=20 min. Representative of 3 separate time-lapse movies  
 
Supplementary Movie 7. Hybrid rosette resolution precedes epiblast remodelling(2) 
Time lapse movie of a representative E5.5 Lifeact-GFP transgenic embryo showing epiblast remodelling after 
hybrid rosette resolution. Time interval=5 min. Representative of 3 separate time-lapse movies  
 
Supplementary Movie 8. Laser ablation mediated hybrid rosette resolution. 
Time lapse movie of a representative E5.5 Lifeact-GFP (stage II) transgenic embryo. The cell-cell interface 
connecting the hybrid rosette centre with the epiblast cavity was ablated via laser ablation (red bar). After  
ablation, the epiblast cavity has extended towards the centre of hybrid rosette, Time interval=1 min. 
Representative of 2 biological replicates. 
 
Supplementary Movie 9. Polarized tract connects the centre of a rosette with the embryonic cavity. 
Representative images through Z (Z=0.9um) of the boundary between epiblast and extra-embryonic ectoderm of 
a representative E5.5 embryo. Polarized track extending from the EPI cavity towards the centre of an ExE 
rosette is evident. blue: DAPI, red:E-cad, green: ZO-1. White dots indicate ExE rosette cells. n=10 embryos 
 
Supplementary Movie 10. ExE rosettes facilitate epiblast cavity extension(1). 
Time lapse movie of a representative E5.5 mTmG transgenic embryo showing epiblast cavity expansion 
towards the ExE after ExE rosette resolution. Time interval=20 min. Representative of 3 separate time-lapse 
movies.  
 
 
 
Supplementary Movie 11. ExE rosettes facilitate epiblast cavity extension(2). 
Time lapse movie of a representative E5.5 LifeactGFP transgenic embryo showing epiblast cavity expansion 
towards the ExE after ExE rosette resolution. Time interval=20 min. Representative of 3 separate time-lapse 
movies 
 
Supplementary Movie 12. ExE rosettes facilitate extra-embryonic cavity extension. 
Time lapse movie of a representative E5.5 LifeactGFP transgenic embryo showing extra-embryonic ectoderm 
cavity extension towards the EPI after ExE rosette resolution. Time interval=5 min. Representative of 3 separate 
time-lapse movies. 
 
Supplementary Movie 13. Rosette mediated embryonic and extra-embryonic cavities extension. 
Time lapse movie of a representative E5.5 LifeactGFP transgenic embryo showing embryonic and extra-
embryonic cavities extension after  rosette resolution. Green outlines indicate embryonic (bottom) and extra-
embryonic cavities (top). Yellow dots: cells contributing to resolving rosette during extra-embryonic cavity 
extension; Green dots: Yellow dots: cells contributing to resolving rosette during embryonic cavity extension; 
Time interval=5 min. Representative of 2 separate time-lapse movies. 
 
Supplementary Movie 14. Extra-embryonic ectoderm cell intercalation upon initial cavities fusion. 
Time lapse movie of a representative E5.75 mTmG (stage IV  V) transgenic embryo showing ExE cell 
intercalation after embryonic (bottom) and extra-embryonic(top) cavities fusion. magenta: cavities, green: 
Intercalating ExE cell. Time interval=20 min. Representative of 2 separate time-lapse movies. 


Sequential formation and resolution of multiple rosettes drive embryo remodelling after implantation

Christodoulou, N

Peng, Guangdum

Apollo (Cambridge)

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Sequential formation and resolution of multiple rosettes drive embryo remodelling after implantation

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