DNMT1 is a Required Genomic Regulator for Murine Liver Histogenesis and Regeneration

Kosuke Kaji; Valentina M Factor; Jesper B Andersen; Marian E Durkin; Akira Tomokuni; Jens U Marquardt; Matthias S Matter; Tanya Hoang; Elizabeth A Conner; Snorri S Thorgeirsson

doi:10.1002/hep.28563

DNMT1 is a Required Genomic Regulator for Murine Liver Histogenesis and Regeneration

Kosuke Kaji, Valentina M Factor, Jesper B Andersen, Marian E Durkin, Akira Tomokuni, Jens U Marquardt, Matthias S Matter, Tanya Hoang, Elizabeth A Conner, Snorri S Thorgeirsson

20 Citations (Scopus)

Abstract

DNA methyltransferase 1 (DNMT1) is an essential regulator maintaining both epigenetic reprogramming during DNA replication and genome stability. We investigated the role of DNMT1 in the regulation of postnatal liver histogenesis under homeostasis and stress conditions. We generated Dnmt1 conditional knockout mice (Dnmt1^Δalb) by crossing Dnmt1^fl/fl with albumin-cyclization recombination transgenic mice. Serum, liver tissues, and primary hepatocytes were collected from 1-week-old to 20-week old mice. The Dnmt1^Δalb phenotype was assessed by histology, confocal and electron microscopy, biochemistry, as well as transcriptome and methylation profiling. Regenerative growth was induced by partial hepatectomy and exposure to carbon tetrachloride. The impact of Dnmt1 knockdown was also analyzed in hepatic progenitor cell lines; proliferation, apoptosis, DNA damage, and sphere formation were assessed. Dnmt1 loss in postnatal hepatocytes caused global hypomethylation, enhanced DNA damage response, and initiated a senescence state causing a progressive inability to maintain tissue homeostasis and proliferate in response to injury. The liver regenerated through activation and repopulation from progenitors due to lineage-dependent differences in albumin-cyclization recombination expression, providing a basis for selection of less mature and therefore less damaged hepatic progenitor cell progeny. Consistently, efficient knockdown of Dnmt1 in cultured hepatic progenitor cells caused severe DNA damage, cell cycle arrest, senescence, and cell death. Mx1-cyclization recombination-driven deletion of Dnmt1 in adult quiescent hepatocytes did not affect liver homeostasis. Conclusion: These results establish the indispensable role of DNMT1-mediated epigenetic regulation in postnatal liver growth and regeneration; Dnmt1^Δalb mice provide a unique experimental model to study the role of senescence and the contribution of progenitor cells to physiological and regenerative liver growth. (Hepatology 2016;64:582-598).

Original language	English
Journal	Hepatology
Volume	64
Issue number	2
Pages (from-to)	582–598
Number of pages	17
ISSN	0270-9139
DOIs	https://doi.org/10.1002/hep.28563
Publication status	Published - 1 Aug 2016

Access to Document

10.1002/hep.28563

Cite this

@article{51e9dfbec72247c399e09f03184b8756,

title = "DNMT1 is a Required Genomic Regulator for Murine Liver Histogenesis and Regeneration",

abstract = "DNA methyltransferase 1 (DNMT1) is an essential regulator maintaining both epigenetic reprogramming during DNA replication and genome stability. We investigated the role of DNMT1 in the regulation of postnatal liver histogenesis under homeostasis and stress conditions. We generated Dnmt1 conditional knockout mice (Dnmt1Δalb) by crossing Dnmt1fl/fl with albumin-cyclization recombination transgenic mice. Serum, liver tissues, and primary hepatocytes were collected from 1-week-old to 20-week old mice. The Dnmt1Δalb phenotype was assessed by histology, confocal and electron microscopy, biochemistry, as well as transcriptome and methylation profiling. Regenerative growth was induced by partial hepatectomy and exposure to carbon tetrachloride. The impact of Dnmt1 knockdown was also analyzed in hepatic progenitor cell lines; proliferation, apoptosis, DNA damage, and sphere formation were assessed. Dnmt1 loss in postnatal hepatocytes caused global hypomethylation, enhanced DNA damage response, and initiated a senescence state causing a progressive inability to maintain tissue homeostasis and proliferate in response to injury. The liver regenerated through activation and repopulation from progenitors due to lineage-dependent differences in albumin-cyclization recombination expression, providing a basis for selection of less mature and therefore less damaged hepatic progenitor cell progeny. Consistently, efficient knockdown of Dnmt1 in cultured hepatic progenitor cells caused severe DNA damage, cell cycle arrest, senescence, and cell death. Mx1-cyclization recombination-driven deletion of Dnmt1 in adult quiescent hepatocytes did not affect liver homeostasis. Conclusion: These results establish the indispensable role of DNMT1-mediated epigenetic regulation in postnatal liver growth and regeneration; Dnmt1Δalb mice provide a unique experimental model to study the role of senescence and the contribution of progenitor cells to physiological and regenerative liver growth. (Hepatology 2016;64:582-598).",

author = "Kosuke Kaji and Factor, {Valentina M} and Andersen, {Jesper B} and Durkin, {Marian E} and Akira Tomokuni and Marquardt, {Jens U} and Matter, {Matthias S} and Tanya Hoang and Conner, {Elizabeth A} and Thorgeirsson, {Snorri S}",

note = "{\textcopyright} 2016 by the American Association for the Study of Liver Diseases.",

year = "2016",

month = aug,

day = "1",

doi = "10.1002/hep.28563",

language = "English",

volume = "64",

pages = "582–598",

journal = "Hepatology",

issn = "0270-9139",

publisher = "JohnWiley & Sons, Inc.",

number = "2",

}

TY - JOUR

T1 - DNMT1 is a Required Genomic Regulator for Murine Liver Histogenesis and Regeneration

AU - Kaji, Kosuke

AU - Factor, Valentina M

AU - Andersen, Jesper B

AU - Durkin, Marian E

AU - Tomokuni, Akira

AU - Marquardt, Jens U

AU - Matter, Matthias S

AU - Hoang, Tanya

AU - Conner, Elizabeth A

AU - Thorgeirsson, Snorri S

PY - 2016/8/1

Y1 - 2016/8/1

N2 - DNA methyltransferase 1 (DNMT1) is an essential regulator maintaining both epigenetic reprogramming during DNA replication and genome stability. We investigated the role of DNMT1 in the regulation of postnatal liver histogenesis under homeostasis and stress conditions. We generated Dnmt1 conditional knockout mice (Dnmt1Δalb) by crossing Dnmt1fl/fl with albumin-cyclization recombination transgenic mice. Serum, liver tissues, and primary hepatocytes were collected from 1-week-old to 20-week old mice. The Dnmt1Δalb phenotype was assessed by histology, confocal and electron microscopy, biochemistry, as well as transcriptome and methylation profiling. Regenerative growth was induced by partial hepatectomy and exposure to carbon tetrachloride. The impact of Dnmt1 knockdown was also analyzed in hepatic progenitor cell lines; proliferation, apoptosis, DNA damage, and sphere formation were assessed. Dnmt1 loss in postnatal hepatocytes caused global hypomethylation, enhanced DNA damage response, and initiated a senescence state causing a progressive inability to maintain tissue homeostasis and proliferate in response to injury. The liver regenerated through activation and repopulation from progenitors due to lineage-dependent differences in albumin-cyclization recombination expression, providing a basis for selection of less mature and therefore less damaged hepatic progenitor cell progeny. Consistently, efficient knockdown of Dnmt1 in cultured hepatic progenitor cells caused severe DNA damage, cell cycle arrest, senescence, and cell death. Mx1-cyclization recombination-driven deletion of Dnmt1 in adult quiescent hepatocytes did not affect liver homeostasis. Conclusion: These results establish the indispensable role of DNMT1-mediated epigenetic regulation in postnatal liver growth and regeneration; Dnmt1Δalb mice provide a unique experimental model to study the role of senescence and the contribution of progenitor cells to physiological and regenerative liver growth. (Hepatology 2016;64:582-598).

AB - DNA methyltransferase 1 (DNMT1) is an essential regulator maintaining both epigenetic reprogramming during DNA replication and genome stability. We investigated the role of DNMT1 in the regulation of postnatal liver histogenesis under homeostasis and stress conditions. We generated Dnmt1 conditional knockout mice (Dnmt1Δalb) by crossing Dnmt1fl/fl with albumin-cyclization recombination transgenic mice. Serum, liver tissues, and primary hepatocytes were collected from 1-week-old to 20-week old mice. The Dnmt1Δalb phenotype was assessed by histology, confocal and electron microscopy, biochemistry, as well as transcriptome and methylation profiling. Regenerative growth was induced by partial hepatectomy and exposure to carbon tetrachloride. The impact of Dnmt1 knockdown was also analyzed in hepatic progenitor cell lines; proliferation, apoptosis, DNA damage, and sphere formation were assessed. Dnmt1 loss in postnatal hepatocytes caused global hypomethylation, enhanced DNA damage response, and initiated a senescence state causing a progressive inability to maintain tissue homeostasis and proliferate in response to injury. The liver regenerated through activation and repopulation from progenitors due to lineage-dependent differences in albumin-cyclization recombination expression, providing a basis for selection of less mature and therefore less damaged hepatic progenitor cell progeny. Consistently, efficient knockdown of Dnmt1 in cultured hepatic progenitor cells caused severe DNA damage, cell cycle arrest, senescence, and cell death. Mx1-cyclization recombination-driven deletion of Dnmt1 in adult quiescent hepatocytes did not affect liver homeostasis. Conclusion: These results establish the indispensable role of DNMT1-mediated epigenetic regulation in postnatal liver growth and regeneration; Dnmt1Δalb mice provide a unique experimental model to study the role of senescence and the contribution of progenitor cells to physiological and regenerative liver growth. (Hepatology 2016;64:582-598).

U2 - 10.1002/hep.28563

DO - 10.1002/hep.28563

M3 - Journal article

C2 - 26999257

SN - 0270-9139

VL - 64

SP - 582

EP - 598

JO - Hepatology

JF - Hepatology

IS - 2

ER -

DNMT1 is a Required Genomic Regulator for Murine Liver Histogenesis and Regeneration

Abstract

Access to Document

Fingerprint

Cite this