Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy

Emily J. Jones; Zoe J. Matthews; Lejla Gul; Padhmanand Sudhakar; Agatha Treveil; Devina Divekar; Jasmine Buck; Tomasz Wrzesinski; Matthew Jefferson; Stuart D. Armstrong; Lindsay J. Hall; Alastair J.M. Watson; Simon R. Carding; Wilfried Haerty; Federica Di Palma; Ulrike Mayer; Penny P. Powell; Isabelle Hautefort; Tom Wileman; Tamas Korcsmaros

doi:10.1242/DMM.037069

Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy

Emily J. Jones, Zoe J. Matthews, Lejla Gul, Padhmanand Sudhakar, Agatha Treveil, Devina Divekar, Jasmine Buck, Tomasz Wrzesinski, Matthew Jefferson, Stuart D. Armstrong, Lindsay J. Hall, Alastair J.M. Watson, Simon R. Carding, Wilfried Haerty, Federica Di Palma, Ulrike Mayer, Penny P. Powell, Isabelle Hautefort, Tom Wileman, Tamas Korcsmaros^*

^*Corresponding author for this work

Microbiology and Infection

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

19 Citations (Scopus)

Abstract

Paneth cells are key epithelial cells that provide an antimicrobial barrier and maintain integrity of the small-intestinal stem cell niche. Paneth cell abnormalities are unfortunately detrimental to gut health and are often associated with digestive pathologies such as Crohn's disease or infections. Similar alterations are observed in individuals with impaired autophagy, a process that recycles cellular components. The direct effect of autophagy impairment on Paneth cells has not been analysed. To investigate this, we generated a mouse model lacking Atg16l1 specifically in intestinal epithelial cells, making these cells impaired in autophagy. Using three-dimensional intestinal organoids enriched for Paneth cells, we compared the proteomic profiles of wild-type and autophagy-impaired organoids. We used an integrated computational approach combining protein-protein interaction networks, autophagy-targeted proteins and functional information to identify the mechanistic link between autophagy impairment and disrupted pathways. Of the 284 altered proteins, 198 (70%) were more abundant in autophagy-impaired organoids, suggesting reduced protein degradation. Interestingly, these differentially abundant proteins comprised 116 proteins (41%) that are predicted targets of the selective autophagy proteins p62, LC3 and ATG16L1. Our integrative analysis revealed autophagy-mediated mechanisms that degrade key proteins in Paneth cell functions, such as exocytosis, apoptosis and DNA damage repair. Transcriptomic profiling of additional organoids confirmed that 90% of the observed changes upon autophagy alteration have effects at the protein level, not on gene expression. We performed further validation experiments showing differential lysozyme secretion, confirming our computationally inferred downregulation of exocytosis. Our observations could explain how protein-level alterations affect Paneth cell homeostatic functions upon autophagy impairment.

Original language	English
Article number	dmm037069
Journal	DMM Disease Models and Mechanisms
Volume	12
Issue number	3
DOIs	https://doi.org/10.1242/DMM.037069
Publication status	Published - Mar 2019

Bibliographical note

Funding Information:
This work was supported by a fellowship to T.K. in computational biology at the Earlham Institute (Norwich, UK) in partnership with the Quadram Institute (Norwich, UK), and strategically supported by the Biotechnological and Biosciences Research Council, UK (BBSRC) grants (BB/J004529/1, BB/P016774/1 and BB/CSP17270/1). Z.J.M. and J.B. were supported by PhD studentships from Norwich Medical School. A.J.M.W. and L.J.H. were supported by the BBSRC grant BB/J004529/1. L.J.H. was also supported by a Wellcome Trust Investigator Award (100,974/C/13/Z). P.P.P. was supported by the BBSRC grant BB/J01754X/1. L.G. and A.T. were supported by the BBSRC Norwich Research Park Biosciences Doctoral Training Partnership (grant BB/M011216/1). T. Wrzesinski and W.H. were supported by a Medical Research Council, UK (MRC) award (MR/P026028/1). Next-generation sequencing and library construction was delivered via the BBSRC National Capability in Genomics and Single Cell (BB/CCG1720/1) at Earlham Institute by members of the Genomics Pipelines Group.

Publisher Copyright:
© 2019. Published by The Company of Biologists Ltd

Keywords

Atg16l1
Intestinal organoids
Paneth cells
Quantitative proteomics
Selective autophagy

ASJC Scopus subject areas

Neuroscience (miscellaneous)
Medicine (miscellaneous)
Immunology and Microbiology (miscellaneous)
General Biochemistry,Genetics and Molecular Biology

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10.1242/DMM.037069

Cite this

Jones, E. J., Matthews, Z. J., Gul, L., Sudhakar, P., Treveil, A., Divekar, D., Buck, J., Wrzesinski, T., Jefferson, M., Armstrong, S. D., Hall, L. J., Watson, A. J. M., Carding, S. R., Haerty, W., Palma, F. D., Mayer, U., Powell, P. P., Hautefort, I., Wileman, T., & Korcsmaros, T. (2019). Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy. DMM Disease Models and Mechanisms, 12(3), Article dmm037069. https://doi.org/10.1242/DMM.037069

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title = "Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy",

abstract = "Paneth cells are key epithelial cells that provide an antimicrobial barrier and maintain integrity of the small-intestinal stem cell niche. Paneth cell abnormalities are unfortunately detrimental to gut health and are often associated with digestive pathologies such as Crohn's disease or infections. Similar alterations are observed in individuals with impaired autophagy, a process that recycles cellular components. The direct effect of autophagy impairment on Paneth cells has not been analysed. To investigate this, we generated a mouse model lacking Atg16l1 specifically in intestinal epithelial cells, making these cells impaired in autophagy. Using three-dimensional intestinal organoids enriched for Paneth cells, we compared the proteomic profiles of wild-type and autophagy-impaired organoids. We used an integrated computational approach combining protein-protein interaction networks, autophagy-targeted proteins and functional information to identify the mechanistic link between autophagy impairment and disrupted pathways. Of the 284 altered proteins, 198 (70%) were more abundant in autophagy-impaired organoids, suggesting reduced protein degradation. Interestingly, these differentially abundant proteins comprised 116 proteins (41%) that are predicted targets of the selective autophagy proteins p62, LC3 and ATG16L1. Our integrative analysis revealed autophagy-mediated mechanisms that degrade key proteins in Paneth cell functions, such as exocytosis, apoptosis and DNA damage repair. Transcriptomic profiling of additional organoids confirmed that 90% of the observed changes upon autophagy alteration have effects at the protein level, not on gene expression. We performed further validation experiments showing differential lysozyme secretion, confirming our computationally inferred downregulation of exocytosis. Our observations could explain how protein-level alterations affect Paneth cell homeostatic functions upon autophagy impairment.",

keywords = "Atg16l1, Intestinal organoids, Paneth cells, Quantitative proteomics, Selective autophagy",

author = "Jones, {Emily J.} and Matthews, {Zoe J.} and Lejla Gul and Padhmanand Sudhakar and Agatha Treveil and Devina Divekar and Jasmine Buck and Tomasz Wrzesinski and Matthew Jefferson and Armstrong, {Stuart D.} and Hall, {Lindsay J.} and Watson, {Alastair J.M.} and Carding, {Simon R.} and Wilfried Haerty and Palma, {Federica Di} and Ulrike Mayer and Powell, {Penny P.} and Isabelle Hautefort and Tom Wileman and Tamas Korcsmaros",

note = "Funding Information: This work was supported by a fellowship to T.K. in computational biology at the Earlham Institute (Norwich, UK) in partnership with the Quadram Institute (Norwich, UK), and strategically supported by the Biotechnological and Biosciences Research Council, UK (BBSRC) grants (BB/J004529/1, BB/P016774/1 and BB/CSP17270/1). Z.J.M. and J.B. were supported by PhD studentships from Norwich Medical School. A.J.M.W. and L.J.H. were supported by the BBSRC grant BB/J004529/1. L.J.H. was also supported by a Wellcome Trust Investigator Award (100,974/C/13/Z). P.P.P. was supported by the BBSRC grant BB/J01754X/1. L.G. and A.T. were supported by the BBSRC Norwich Research Park Biosciences Doctoral Training Partnership (grant BB/M011216/1). T. Wrzesinski and W.H. were supported by a Medical Research Council, UK (MRC) award (MR/P026028/1). Next-generation sequencing and library construction was delivered via the BBSRC National Capability in Genomics and Single Cell (BB/CCG1720/1) at Earlham Institute by members of the Genomics Pipelines Group. Publisher Copyright: {\textcopyright} 2019. Published by The Company of Biologists Ltd",

year = "2019",

month = mar,

doi = "10.1242/DMM.037069",

language = "English",

volume = "12",

journal = "DMM Disease Models and Mechanisms",

issn = "1754-8403",

publisher = "The Company of Biologists Ltd.",

number = "3",

}

Jones, EJ, Matthews, ZJ, Gul, L, Sudhakar, P, Treveil, A, Divekar, D, Buck, J, Wrzesinski, T, Jefferson, M, Armstrong, SD, Hall, LJ, Watson, AJM, Carding, SR, Haerty, W, Palma, FD, Mayer, U, Powell, PP, Hautefort, I, Wileman, T & Korcsmaros, T 2019, 'Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy', DMM Disease Models and Mechanisms, vol. 12, no. 3, dmm037069. https://doi.org/10.1242/DMM.037069

TY - JOUR

T1 - Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy

AU - Jones, Emily J.

AU - Matthews, Zoe J.

AU - Gul, Lejla

AU - Sudhakar, Padhmanand

AU - Treveil, Agatha

AU - Divekar, Devina

AU - Buck, Jasmine

AU - Wrzesinski, Tomasz

AU - Jefferson, Matthew

AU - Armstrong, Stuart D.

AU - Hall, Lindsay J.

AU - Watson, Alastair J.M.

AU - Carding, Simon R.

AU - Haerty, Wilfried

AU - Palma, Federica Di

AU - Mayer, Ulrike

AU - Powell, Penny P.

AU - Hautefort, Isabelle

AU - Wileman, Tom

AU - Korcsmaros, Tamas

N1 - Funding Information: This work was supported by a fellowship to T.K. in computational biology at the Earlham Institute (Norwich, UK) in partnership with the Quadram Institute (Norwich, UK), and strategically supported by the Biotechnological and Biosciences Research Council, UK (BBSRC) grants (BB/J004529/1, BB/P016774/1 and BB/CSP17270/1). Z.J.M. and J.B. were supported by PhD studentships from Norwich Medical School. A.J.M.W. and L.J.H. were supported by the BBSRC grant BB/J004529/1. L.J.H. was also supported by a Wellcome Trust Investigator Award (100,974/C/13/Z). P.P.P. was supported by the BBSRC grant BB/J01754X/1. L.G. and A.T. were supported by the BBSRC Norwich Research Park Biosciences Doctoral Training Partnership (grant BB/M011216/1). T. Wrzesinski and W.H. were supported by a Medical Research Council, UK (MRC) award (MR/P026028/1). Next-generation sequencing and library construction was delivered via the BBSRC National Capability in Genomics and Single Cell (BB/CCG1720/1) at Earlham Institute by members of the Genomics Pipelines Group. Publisher Copyright: © 2019. Published by The Company of Biologists Ltd

PY - 2019/3

Y1 - 2019/3

N2 - Paneth cells are key epithelial cells that provide an antimicrobial barrier and maintain integrity of the small-intestinal stem cell niche. Paneth cell abnormalities are unfortunately detrimental to gut health and are often associated with digestive pathologies such as Crohn's disease or infections. Similar alterations are observed in individuals with impaired autophagy, a process that recycles cellular components. The direct effect of autophagy impairment on Paneth cells has not been analysed. To investigate this, we generated a mouse model lacking Atg16l1 specifically in intestinal epithelial cells, making these cells impaired in autophagy. Using three-dimensional intestinal organoids enriched for Paneth cells, we compared the proteomic profiles of wild-type and autophagy-impaired organoids. We used an integrated computational approach combining protein-protein interaction networks, autophagy-targeted proteins and functional information to identify the mechanistic link between autophagy impairment and disrupted pathways. Of the 284 altered proteins, 198 (70%) were more abundant in autophagy-impaired organoids, suggesting reduced protein degradation. Interestingly, these differentially abundant proteins comprised 116 proteins (41%) that are predicted targets of the selective autophagy proteins p62, LC3 and ATG16L1. Our integrative analysis revealed autophagy-mediated mechanisms that degrade key proteins in Paneth cell functions, such as exocytosis, apoptosis and DNA damage repair. Transcriptomic profiling of additional organoids confirmed that 90% of the observed changes upon autophagy alteration have effects at the protein level, not on gene expression. We performed further validation experiments showing differential lysozyme secretion, confirming our computationally inferred downregulation of exocytosis. Our observations could explain how protein-level alterations affect Paneth cell homeostatic functions upon autophagy impairment.

AB - Paneth cells are key epithelial cells that provide an antimicrobial barrier and maintain integrity of the small-intestinal stem cell niche. Paneth cell abnormalities are unfortunately detrimental to gut health and are often associated with digestive pathologies such as Crohn's disease or infections. Similar alterations are observed in individuals with impaired autophagy, a process that recycles cellular components. The direct effect of autophagy impairment on Paneth cells has not been analysed. To investigate this, we generated a mouse model lacking Atg16l1 specifically in intestinal epithelial cells, making these cells impaired in autophagy. Using three-dimensional intestinal organoids enriched for Paneth cells, we compared the proteomic profiles of wild-type and autophagy-impaired organoids. We used an integrated computational approach combining protein-protein interaction networks, autophagy-targeted proteins and functional information to identify the mechanistic link between autophagy impairment and disrupted pathways. Of the 284 altered proteins, 198 (70%) were more abundant in autophagy-impaired organoids, suggesting reduced protein degradation. Interestingly, these differentially abundant proteins comprised 116 proteins (41%) that are predicted targets of the selective autophagy proteins p62, LC3 and ATG16L1. Our integrative analysis revealed autophagy-mediated mechanisms that degrade key proteins in Paneth cell functions, such as exocytosis, apoptosis and DNA damage repair. Transcriptomic profiling of additional organoids confirmed that 90% of the observed changes upon autophagy alteration have effects at the protein level, not on gene expression. We performed further validation experiments showing differential lysozyme secretion, confirming our computationally inferred downregulation of exocytosis. Our observations could explain how protein-level alterations affect Paneth cell homeostatic functions upon autophagy impairment.

KW - Atg16l1

KW - Intestinal organoids

KW - Paneth cells

KW - Quantitative proteomics

KW - Selective autophagy

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U2 - 10.1242/DMM.037069

DO - 10.1242/DMM.037069

M3 - Article

C2 - 30814064

AN - SCOPUS:85063271945

SN - 1754-8403

VL - 12

JO - DMM Disease Models and Mechanisms

JF - DMM Disease Models and Mechanisms

IS - 3

M1 - dmm037069

ER -

Integrative analysis of Paneth cell proteomic and transcriptomic data from intestinal organoids reveals functional processes dependent on autophagy

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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