Acinar-ductal cell rearrangement drives branching morphogenesis of the murine pancreas in an IGF/PI3K-dependent manner

Jean-Francois Darrigrand; Anna Salowka; Alejo Torres-Cano; Rafael Tapia-Rojo; Tong Zhu; Sergi Garcia-Manyes; Francesca M. Spagnoli

doi:10.1016/j.devcel.2023.12.011

Acinar-ductal cell rearrangement drives branching morphogenesis of the murine pancreas in an IGF/PI3K-dependent manner

Jean-Francois Darrigrand, Anna Salowka, Alejo Torres-Cano, Rafael Tapia-Rojo, Tong Zhu, Sergi Garcia-Manyes, Francesca M. Spagnoli^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

During organ formation, progenitor cells need to acquire different cell identities and organize themselves into distinct structural units. How these processes are coordinated and how tissue architecture(s) is preserved despite the dramatic cell rearrangements occurring in developing organs remain unclear. Here, we identified cellular rearrangements between acinar and ductal progenitors as a mechanism to drive branching morphogenesis in the pancreas while preserving the integrity of the acinar-ductal functional unit. Using ex vivo and in vivo mouse models, we found that pancreatic ductal cells form clefts by protruding and pulling on the acinar basement membrane, which leads to acini splitting. Newly formed acini remain connected to the bifurcated branches generated by ductal cell rearrangement. Insulin growth factor (IGF)/phosphatidylinositol 3-kinase (PI3K) pathway finely regulates this process by controlling pancreatic ductal tissue fluidity, with a simultaneous impact on branching and cell fate acquisition. Together, our results explain how acinar structure multiplication and branch bifurcation are synchronized during pancreas organogenesis.

Original language	English
Pages (from-to)	326-338.E5
Journal	Developmental Cell
Volume	59
Issue number	3
Early online date	17 Jan 2024
DOIs	https://doi.org/10.1016/j.devcel.2023.12.011
Publication status	Published - 5 Feb 2024

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title = "Acinar-ductal cell rearrangement drives branching morphogenesis of the murine pancreas in an IGF/PI3K-dependent manner",

abstract = "During organ formation, progenitor cells need to acquire different cell identities and organize themselves into distinct structural units. How these processes are coordinated and how tissue architecture(s) is preserved despite the dramatic cell rearrangements occurring in developing organs remain unclear. Here, we identified cellular rearrangements between acinar and ductal progenitors as a mechanism to drive branching morphogenesis in the pancreas while preserving the integrity of the acinar-ductal functional unit. Using ex vivo and in vivo mouse models, we found that pancreatic ductal cells form clefts by protruding and pulling on the acinar basement membrane, which leads to acini splitting. Newly formed acini remain connected to the bifurcated branches generated by ductal cell rearrangement. Insulin growth factor (IGF)/phosphatidylinositol 3-kinase (PI3K) pathway finely regulates this process by controlling pancreatic ductal tissue fluidity, with a simultaneous impact on branching and cell fate acquisition. Together, our results explain how acinar structure multiplication and branch bifurcation are synchronized during pancreas organogenesis.",

author = "Jean-Francois Darrigrand and Anna Salowka and Alejo Torres-Cano and Rafael Tapia-Rojo and Tong Zhu and Sergi Garcia-Manyes and Spagnoli, {Francesca M.}",

note = "Funding Information: We acknowledge the support of the European Union{\textquoteright}s Horizon 2020 research and innovation program Pan3DP FET Open (grant number 800981 ) and Wellcome Trust Investigator Award ( 221807/Z/20/Z ) to F.M.S. J.-F.D. is supported by a fellowship from the NC3R (grant reference NC/V002260/1 ). A.T.-C. is the recipient of a postdoctoral fellowship from the “Fundaci{\'o}n Alfonso Mart{\'i}n Escudero.” A.S. is the recipient of a studentship from the Wellcome Trust Ph.D. program “Advanced therapies for regenerative medicine” (grant number 218461/Z/19/Z ). This work was supported in part by the Francis Crick Institute, which receives its core funding from Cancer Research UK ( CC0102 ), the UK Medical Research Council ( CC0102 ), and the Wellcome Trust ( CC0102 ). T.Z. is the recipient of a CSC-King{\textquoteright}s doctoral studentship and funding through the KCL British Heart Foundation Centre of Research Excellence . This work is supported by the EPSRC Strategic Equipment Grant ( EP/M022536/1 ), the European Commission (Mechanocontrol, grant agreement 731957 ), BBSRC sLoLa ( BB/V003518/1 ), Leverhulme Trust Research Leadership Award ( RL 2016-015 ), Wellcome Trust Investigator Award ( 212218/Z/18/Z ), and Royal Society Wolfson Fellowship ( RSWF/R3/183006 ) to S.G.-M. Publisher Copyright: {\textcopyright} 2023",

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AU - Salowka, Anna

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AU - Tapia-Rojo, Rafael

AU - Zhu, Tong

AU - Garcia-Manyes, Sergi

AU - Spagnoli, Francesca M.

N1 - Funding Information: We acknowledge the support of the European Union’s Horizon 2020 research and innovation program Pan3DP FET Open (grant number 800981 ) and Wellcome Trust Investigator Award ( 221807/Z/20/Z ) to F.M.S. J.-F.D. is supported by a fellowship from the NC3R (grant reference NC/V002260/1 ). A.T.-C. is the recipient of a postdoctoral fellowship from the “Fundación Alfonso Martín Escudero.” A.S. is the recipient of a studentship from the Wellcome Trust Ph.D. program “Advanced therapies for regenerative medicine” (grant number 218461/Z/19/Z ). This work was supported in part by the Francis Crick Institute, which receives its core funding from Cancer Research UK ( CC0102 ), the UK Medical Research Council ( CC0102 ), and the Wellcome Trust ( CC0102 ). T.Z. is the recipient of a CSC-King’s doctoral studentship and funding through the KCL British Heart Foundation Centre of Research Excellence . This work is supported by the EPSRC Strategic Equipment Grant ( EP/M022536/1 ), the European Commission (Mechanocontrol, grant agreement 731957 ), BBSRC sLoLa ( BB/V003518/1 ), Leverhulme Trust Research Leadership Award ( RL 2016-015 ), Wellcome Trust Investigator Award ( 212218/Z/18/Z ), and Royal Society Wolfson Fellowship ( RSWF/R3/183006 ) to S.G.-M. Publisher Copyright: © 2023

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N2 - During organ formation, progenitor cells need to acquire different cell identities and organize themselves into distinct structural units. How these processes are coordinated and how tissue architecture(s) is preserved despite the dramatic cell rearrangements occurring in developing organs remain unclear. Here, we identified cellular rearrangements between acinar and ductal progenitors as a mechanism to drive branching morphogenesis in the pancreas while preserving the integrity of the acinar-ductal functional unit. Using ex vivo and in vivo mouse models, we found that pancreatic ductal cells form clefts by protruding and pulling on the acinar basement membrane, which leads to acini splitting. Newly formed acini remain connected to the bifurcated branches generated by ductal cell rearrangement. Insulin growth factor (IGF)/phosphatidylinositol 3-kinase (PI3K) pathway finely regulates this process by controlling pancreatic ductal tissue fluidity, with a simultaneous impact on branching and cell fate acquisition. Together, our results explain how acinar structure multiplication and branch bifurcation are synchronized during pancreas organogenesis.

AB - During organ formation, progenitor cells need to acquire different cell identities and organize themselves into distinct structural units. How these processes are coordinated and how tissue architecture(s) is preserved despite the dramatic cell rearrangements occurring in developing organs remain unclear. Here, we identified cellular rearrangements between acinar and ductal progenitors as a mechanism to drive branching morphogenesis in the pancreas while preserving the integrity of the acinar-ductal functional unit. Using ex vivo and in vivo mouse models, we found that pancreatic ductal cells form clefts by protruding and pulling on the acinar basement membrane, which leads to acini splitting. Newly formed acini remain connected to the bifurcated branches generated by ductal cell rearrangement. Insulin growth factor (IGF)/phosphatidylinositol 3-kinase (PI3K) pathway finely regulates this process by controlling pancreatic ductal tissue fluidity, with a simultaneous impact on branching and cell fate acquisition. Together, our results explain how acinar structure multiplication and branch bifurcation are synchronized during pancreas organogenesis.

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DO - 10.1016/j.devcel.2023.12.011

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JO - Developmental Cell

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ER -

Acinar-ductal cell rearrangement drives branching morphogenesis of the murine pancreas in an IGF/PI3K-dependent manner

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