Retrograde movements determine effective stem cell numbers in the intestine

Maria Azkanaz; Bernat Corominas-Murtra; Saskia I.J. Ellenbroek; Lotte Bruens; Anna T. Webb; Dimitrios Laskaris; Koen C. Oost; Simona J.A. Lafirenze; Karl Annusver; Hendrik A. Messal; Sharif Iqbal; Dustin J. Flanagan; David J. Huels; Felipe Rojas-Rodríguez; Miguel Vizoso; Maria Kasper; Owen J. Sansom; Hugo J. Snippert; Prisca Liberali; Benjamin D. Simons; Pekka Katajisto; Edouard Hannezo; Jacco van Rheenen

doi:10.1038/s41586-022-04962-0

Retrograde movements determine effective stem cell numbers in the intestine

Maria Azkanaz, Bernat Corominas-Murtra, Saskia I.J. Ellenbroek, Lotte Bruens, Anna T. Webb, Dimitrios Laskaris, Koen C. Oost, Simona J.A. Lafirenze, Karl Annusver, Hendrik A. Messal, Sharif Iqbal, Dustin J. Flanagan, David J. Huels, Felipe Rojas-Rodríguez, Miguel Vizoso, Maria Kasper, Owen J. Sansom, Hugo J. Snippert, Prisca Liberali, Benjamin D. SimonsPekka Katajisto, Edouard Hannezo, Jacco van Rheenen

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

35 Citations (Scopus)

Abstract

The morphology and functionality of the epithelial lining differ along the intestinal tract, but tissue renewal at all sites is driven by stem cells at the base of crypts^1–3. Whether stem cell numbers and behaviour vary at different sites is unknown. Here we show using intravital microscopy that, despite similarities in the number and distribution of proliferative cells with an Lgr5 signature in mice, small intestinal crypts contain twice as many effective stem cells as large intestinal crypts. We find that, although passively displaced by a conveyor-belt-like upward movement, small intestinal cells positioned away from the crypt base can function as long-term effective stem cells owing to Wnt-dependent retrograde cellular movement. By contrast, the near absence of retrograde movement in the large intestine restricts cell repositioning, leading to a reduction in effective stem cell number. Moreover, after suppression of the retrograde movement in the small intestine, the number of effective stem cells is reduced, and the rate of monoclonal conversion of crypts is accelerated. Together, these results show that the number of effective stem cells is determined by active retrograde movement, revealing a new channel of stem cell regulation that can be experimentally and pharmacologically manipulated.

Original language	English
Pages (from-to)	548-554
Number of pages	7
Journal	Nature
Volume	607
Issue number	7919
DOIs	https://doi.org/10.1038/s41586-022-04962-0
Publication status	Published - 21 Jul 2022
Externally published	Yes

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10.1038/s41586-022-04962-0

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Azkanaz, M., Corominas-Murtra, B., Ellenbroek, S. I. J., Bruens, L., Webb, A. T., Laskaris, D., Oost, K. C., Lafirenze, S. J. A., Annusver, K., Messal, H. A., Iqbal, S., Flanagan, D. J., Huels, D. J., Rojas-Rodríguez, F., Vizoso, M., Kasper, M., Sansom, O. J., Snippert, H. J., Liberali, P., ... van Rheenen, J. (2022). Retrograde movements determine effective stem cell numbers in the intestine. Nature, 607(7919), 548-554. https://doi.org/10.1038/s41586-022-04962-0

@article{020b3c87b3eb416aa4d6e92ecda3f1e3,

title = "Retrograde movements determine effective stem cell numbers in the intestine",

abstract = "The morphology and functionality of the epithelial lining differ along the intestinal tract, but tissue renewal at all sites is driven by stem cells at the base of crypts1–3. Whether stem cell numbers and behaviour vary at different sites is unknown. Here we show using intravital microscopy that, despite similarities in the number and distribution of proliferative cells with an Lgr5 signature in mice, small intestinal crypts contain twice as many effective stem cells as large intestinal crypts. We find that, although passively displaced by a conveyor-belt-like upward movement, small intestinal cells positioned away from the crypt base can function as long-term effective stem cells owing to Wnt-dependent retrograde cellular movement. By contrast, the near absence of retrograde movement in the large intestine restricts cell repositioning, leading to a reduction in effective stem cell number. Moreover, after suppression of the retrograde movement in the small intestine, the number of effective stem cells is reduced, and the rate of monoclonal conversion of crypts is accelerated. Together, these results show that the number of effective stem cells is determined by active retrograde movement, revealing a new channel of stem cell regulation that can be experimentally and pharmacologically manipulated.",

author = "Maria Azkanaz and Bernat Corominas-Murtra and Ellenbroek, {Saskia I.J.} and Lotte Bruens and Webb, {Anna T.} and Dimitrios Laskaris and Oost, {Koen C.} and Lafirenze, {Simona J.A.} and Karl Annusver and Messal, {Hendrik A.} and Sharif Iqbal and Flanagan, {Dustin J.} and Huels, {David J.} and Felipe Rojas-Rodr{\'i}guez and Miguel Vizoso and Maria Kasper and Sansom, {Owen J.} and Snippert, {Hugo J.} and Prisca Liberali and Simons, {Benjamin D.} and Pekka Katajisto and Edouard Hannezo and {van Rheenen}, Jacco",

note = "Funding Information: We thank the members of the van Rheenen laboratory for reading the manuscript, and the members of the bioimaging, FACS and animal facility of the NKI for experimental support. We acknowledge the staff at the MedH Flow Cytometry core facility, Karolinska Institutet, and LCI facility/Nikon Center of Excellence, Karolinska Institutet. This work was financially supported by the Netherlands Organization of Scientific Research NWO (Veni grant 863.15.011 to S.I.J.E. and Vici grant 09150182110004 to J.v.R.) and the CancerGenomics.nl (Netherlands Organisation for Scientific Research) program (to J.v.R.) the Doctor Josef Steiner Foundation (to J.v.R). B.D.S. acknowledges funding from the Royal Society E.P. Abraham Research Professorship (RP\R1\180165) and the Wellcome Trust (098357/Z/12/Z and 219478/Z/19/Z). B.C.-M. acknowledges the support of the field of excellence {\textquoteleft}Complexity of life in basic research and innovation{\textquoteright} of the University of Graz. O.J.S. and their laboratory acknowledge CRUK core funding to the CRUK Beatson Institute (A17196 and A31287) and CRUK core funding to the Sansom laboratory (A21139). P.K. and their laboratory are supported by grants from the Swedish Research Council (2018-03078), Cancerfonden (190634), Academy of Finland Centre of Excellence (266869, 304591 and 320185) and the Jane and Aatos Erkko Foundation. P.L. has received funding from the European Research Council (ERC) under the European Union{\textquoteright}s Horizon 2020 research and innovation programme (grant agreement no. 758617). E.H. acknowledges funding from the European Research Council (ERC) under the European Union{\textquoteright}s Horizon 2020 research and innovation programme (grant agreement no. 851288). Funding Information: We thank the members of the van Rheenen laboratory for reading the manuscript, and the members of the bioimaging, FACS and animal facility of the NKI for experimental support. We acknowledge the staff at the MedH Flow Cytometry core facility, Karolinska Institutet, and LCI facility/Nikon Center of Excellence, Karolinska Institutet. This work was financially supported by the Netherlands Organization of Scientific Research NWO (Veni grant 863.15.011 to S.I.J.E. and Vici grant 09150182110004 to J.v.R.) and the CancerGenomics.nl (Netherlands Organisation for Scientific Research) program (to J.v.R.) the Doctor Josef Steiner Foundation (to J.v.R). B.D.S. acknowledges funding from the Royal Society E.P. Abraham Research Professorship (RP\R1\180165) and the Wellcome Trust (098357/Z/12/Z and 219478/Z/19/Z). B.C.-M. acknowledges the support of the field of excellence {\textquoteleft}Complexity of life in basic research and innovation{\textquoteright} of the University of Graz. O.J.S. and their laboratory acknowledge CRUK core funding to the CRUK Beatson Institute (A17196 and A31287) and CRUK core funding to the Sansom laboratory (A21139). P.K. and their laboratory are supported by grants from the Swedish Research Council (2018-03078), Cancerfonden (190634), Academy of Finland Centre of Excellence (266869, 304591 and 320185) and the Jane and Aatos Erkko Foundation. P.L. has received funding from the European Research Council (ERC) under the European Union{\textquoteright}s Horizon 2020 research and innovation programme (grant agreement no. 758617). E.H. acknowledges funding from the European Research Council (ERC) under the European Union{\textquoteright}s Horizon 2020 research and innovation programme (grant agreement no. 851288). Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

month = jul,

day = "21",

doi = "10.1038/s41586-022-04962-0",

language = "English",

volume = "607",

pages = "548--554",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Publishing Group",

number = "7919",

}

Azkanaz, M, Corominas-Murtra, B, Ellenbroek, SIJ, Bruens, L, Webb, AT, Laskaris, D, Oost, KC, Lafirenze, SJA, Annusver, K, Messal, HA, Iqbal, S, Flanagan, DJ, Huels, DJ, Rojas-Rodríguez, F, Vizoso, M, Kasper, M, Sansom, OJ, Snippert, HJ, Liberali, P, Simons, BD, Katajisto, P, Hannezo, E & van Rheenen, J 2022, 'Retrograde movements determine effective stem cell numbers in the intestine', Nature, vol. 607, no. 7919, pp. 548-554. https://doi.org/10.1038/s41586-022-04962-0

TY - JOUR

T1 - Retrograde movements determine effective stem cell numbers in the intestine

AU - Azkanaz, Maria

AU - Corominas-Murtra, Bernat

AU - Ellenbroek, Saskia I.J.

AU - Bruens, Lotte

AU - Webb, Anna T.

AU - Laskaris, Dimitrios

AU - Oost, Koen C.

AU - Lafirenze, Simona J.A.

AU - Annusver, Karl

AU - Messal, Hendrik A.

AU - Iqbal, Sharif

AU - Flanagan, Dustin J.

AU - Huels, David J.

AU - Rojas-Rodríguez, Felipe

AU - Vizoso, Miguel

AU - Kasper, Maria

AU - Sansom, Owen J.

AU - Snippert, Hugo J.

AU - Liberali, Prisca

AU - Simons, Benjamin D.

AU - Katajisto, Pekka

AU - Hannezo, Edouard

AU - van Rheenen, Jacco

N1 - Funding Information: We thank the members of the van Rheenen laboratory for reading the manuscript, and the members of the bioimaging, FACS and animal facility of the NKI for experimental support. We acknowledge the staff at the MedH Flow Cytometry core facility, Karolinska Institutet, and LCI facility/Nikon Center of Excellence, Karolinska Institutet. This work was financially supported by the Netherlands Organization of Scientific Research NWO (Veni grant 863.15.011 to S.I.J.E. and Vici grant 09150182110004 to J.v.R.) and the CancerGenomics.nl (Netherlands Organisation for Scientific Research) program (to J.v.R.) the Doctor Josef Steiner Foundation (to J.v.R). B.D.S. acknowledges funding from the Royal Society E.P. Abraham Research Professorship (RP\R1\180165) and the Wellcome Trust (098357/Z/12/Z and 219478/Z/19/Z). B.C.-M. acknowledges the support of the field of excellence ‘Complexity of life in basic research and innovation’ of the University of Graz. O.J.S. and their laboratory acknowledge CRUK core funding to the CRUK Beatson Institute (A17196 and A31287) and CRUK core funding to the Sansom laboratory (A21139). P.K. and their laboratory are supported by grants from the Swedish Research Council (2018-03078), Cancerfonden (190634), Academy of Finland Centre of Excellence (266869, 304591 and 320185) and the Jane and Aatos Erkko Foundation. P.L. has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 758617). E.H. acknowledges funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 851288). Funding Information: We thank the members of the van Rheenen laboratory for reading the manuscript, and the members of the bioimaging, FACS and animal facility of the NKI for experimental support. We acknowledge the staff at the MedH Flow Cytometry core facility, Karolinska Institutet, and LCI facility/Nikon Center of Excellence, Karolinska Institutet. This work was financially supported by the Netherlands Organization of Scientific Research NWO (Veni grant 863.15.011 to S.I.J.E. and Vici grant 09150182110004 to J.v.R.) and the CancerGenomics.nl (Netherlands Organisation for Scientific Research) program (to J.v.R.) the Doctor Josef Steiner Foundation (to J.v.R). B.D.S. acknowledges funding from the Royal Society E.P. Abraham Research Professorship (RP\R1\180165) and the Wellcome Trust (098357/Z/12/Z and 219478/Z/19/Z). B.C.-M. acknowledges the support of the field of excellence ‘Complexity of life in basic research and innovation’ of the University of Graz. O.J.S. and their laboratory acknowledge CRUK core funding to the CRUK Beatson Institute (A17196 and A31287) and CRUK core funding to the Sansom laboratory (A21139). P.K. and their laboratory are supported by grants from the Swedish Research Council (2018-03078), Cancerfonden (190634), Academy of Finland Centre of Excellence (266869, 304591 and 320185) and the Jane and Aatos Erkko Foundation. P.L. has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 758617). E.H. acknowledges funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 851288). Publisher Copyright: © 2022, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2022/7/21

Y1 - 2022/7/21

N2 - The morphology and functionality of the epithelial lining differ along the intestinal tract, but tissue renewal at all sites is driven by stem cells at the base of crypts1–3. Whether stem cell numbers and behaviour vary at different sites is unknown. Here we show using intravital microscopy that, despite similarities in the number and distribution of proliferative cells with an Lgr5 signature in mice, small intestinal crypts contain twice as many effective stem cells as large intestinal crypts. We find that, although passively displaced by a conveyor-belt-like upward movement, small intestinal cells positioned away from the crypt base can function as long-term effective stem cells owing to Wnt-dependent retrograde cellular movement. By contrast, the near absence of retrograde movement in the large intestine restricts cell repositioning, leading to a reduction in effective stem cell number. Moreover, after suppression of the retrograde movement in the small intestine, the number of effective stem cells is reduced, and the rate of monoclonal conversion of crypts is accelerated. Together, these results show that the number of effective stem cells is determined by active retrograde movement, revealing a new channel of stem cell regulation that can be experimentally and pharmacologically manipulated.

AB - The morphology and functionality of the epithelial lining differ along the intestinal tract, but tissue renewal at all sites is driven by stem cells at the base of crypts1–3. Whether stem cell numbers and behaviour vary at different sites is unknown. Here we show using intravital microscopy that, despite similarities in the number and distribution of proliferative cells with an Lgr5 signature in mice, small intestinal crypts contain twice as many effective stem cells as large intestinal crypts. We find that, although passively displaced by a conveyor-belt-like upward movement, small intestinal cells positioned away from the crypt base can function as long-term effective stem cells owing to Wnt-dependent retrograde cellular movement. By contrast, the near absence of retrograde movement in the large intestine restricts cell repositioning, leading to a reduction in effective stem cell number. Moreover, after suppression of the retrograde movement in the small intestine, the number of effective stem cells is reduced, and the rate of monoclonal conversion of crypts is accelerated. Together, these results show that the number of effective stem cells is determined by active retrograde movement, revealing a new channel of stem cell regulation that can be experimentally and pharmacologically manipulated.

UR - http://www.scopus.com/inward/record.url?scp=85134162879&partnerID=8YFLogxK

U2 - 10.1038/s41586-022-04962-0

DO - 10.1038/s41586-022-04962-0

M3 - Article

C2 - 35831497

AN - SCOPUS:85134162879

SN - 0028-0836

VL - 607

SP - 548

EP - 554

JO - Nature

JF - Nature

IS - 7919

ER -

Retrograde movements determine effective stem cell numbers in the intestine

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