Literature DB >> 26012551

Hypoxia Signaling Cascade for Erythropoietin Production in Hepatocytes.

Yutaka Tojo1, Hiroki Sekine2, Ikuo Hirano3, Xiaoqing Pan2, Tomokazu Souma3, Tadayuki Tsujita4, Shin-ichi Kawaguchi5, Norihiko Takeda6, Kotaro Takeda7, Guo-Hua Fong7, Takashi Dan5, Masakazu Ichinose8, Toshio Miyata5, Masayuki Yamamoto3, Norio Suzuki9.   

Abstract

Erythropoietin (Epo) is produced in the kidney and liver in a hypoxia-inducible manner via the activation of hypoxia-inducible transcription factors (HIFs) to maintain oxygen homeostasis. Accelerating Epo production in hepatocytes is one plausible therapeutic strategy for treating anemia caused by kidney diseases. To elucidate the regulatory mechanisms of hepatic Epo production, we analyzed mouse lines harboring liver-specific deletions of genes encoding HIF-prolyl-hydroxylase isoforms (PHD1, PHD2, and PHD3) that mediate the inactivation of HIF1α and HIF2α under normal oxygen conditions. The loss of all PHD isoforms results in both polycythemia, which is caused by Epo overproduction, and fatty livers. We found that deleting any combination of two PHD isoforms induces polycythemia without steatosis complications, whereas the deletion of a single isoform induces no apparent phenotype. Polycythemia is prevented by the loss of either HIF2α or the hepatocyte-specific Epo gene enhancer (EpoHE). Chromatin analyses show that the histones around EpoHE dissociate from the nucleosome structure after HIF2α activation. HIF2α also induces the expression of HIF3α, which is involved in the attenuation of Epo production. These results demonstrate that the total amount of PHD activity is more important than the specific function of each isoform for hepatic Epo expression regulated by a PHD-HIF2α-EpoHE cascade in vivo.
Copyright © 2015, American Society for Microbiology. All Rights Reserved.

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Year:  2015        PMID: 26012551      PMCID: PMC4524113          DOI: 10.1128/MCB.00161-15

Source DB:  PubMed          Journal:  Mol Cell Biol        ISSN: 0270-7306            Impact factor:   4.272


  70 in total

1.  Hematological, hepatic, and retinal phenotypes in mice deficient for prolyl hydroxylase domain proteins in the liver.

Authors:  Li-Juan Duan; Kotaro Takeda; Guo-Hua Fong
Journal:  Am J Pathol       Date:  2014-02-06       Impact factor: 4.307

2.  Plasticity of renal erythropoietin-producing cells governs fibrosis.

Authors:  Tomokazu Souma; Shun Yamazaki; Takashi Moriguchi; Norio Suzuki; Ikuo Hirano; Xiaoqing Pan; Naoko Minegishi; Michiaki Abe; Hideyasu Kiyomoto; Sadayoshi Ito; Masayuki Yamamoto
Journal:  J Am Soc Nephrol       Date:  2013-07-05       Impact factor: 10.121

3.  Targeting of HIF-alpha to the von Hippel-Lindau ubiquitylation complex by O2-regulated prolyl hydroxylation.

Authors:  P Jaakkola; D R Mole; Y M Tian; M I Wilson; J Gielbert; S J Gaskell; A von Kriegsheim; H F Hebestreit; M Mukherji; C J Schofield; P H Maxwell; C W Pugh; P J Ratcliffe
Journal:  Science       Date:  2001-04-05       Impact factor: 47.728

4.  Cobalt stimulates HIF-1-dependent but inhibits HIF-2-dependent gene expression in liver cancer cells.

Authors:  Christina Befani; Ilias Mylonis; Ioanna-Maria Gkotinakou; Panagiotis Georgoulias; Cheng-Jun Hu; George Simos; Panagiotis Liakos
Journal:  Int J Biochem Cell Biol       Date:  2013-08-16       Impact factor: 5.085

5.  HIF prolyl 4-hydroxylase-2 inhibition improves glucose and lipid metabolism and protects against obesity and metabolic dysfunction.

Authors:  Lea Rahtu-Korpela; Sara Karsikas; Sohvi Hörkkö; Roberto Blanco Sequeiros; Eveliina Lammentausta; Kari A Mäkelä; Karl-Heinz Herzig; Gail Walkinshaw; Kari I Kivirikko; Johanna Myllyharju; Raisa Serpi; Peppi Koivunen
Journal:  Diabetes       Date:  2014-05-01       Impact factor: 9.461

6.  Vascular tumors in livers with targeted inactivation of the von Hippel-Lindau tumor suppressor.

Authors:  V H Haase; J N Glickman; M Socolovsky; R Jaenisch
Journal:  Proc Natl Acad Sci U S A       Date:  2001-02-13       Impact factor: 11.205

7.  Congenital erythrocytosis associated with gain-of-function HIF2A gene mutations and erythropoietin levels in the normal range.

Authors:  Silverio Perrotta; Daniel P Stiehl; Francesca Punzo; Saverio Scianguetta; Adriana Borriello; Debora Bencivenga; Maddalena Casale; Bruno Nobili; Silvia Fasoli; Adriana Balduzzi; Lilla Cro; Katarzyna J Nytko; Roland H Wenger; Fulvio Della Ragione
Journal:  Haematologica       Date:  2013-05-28       Impact factor: 9.941

Review 8.  Diabetic nephropathy: are there new and potentially promising therapies targeting oxygen biology?

Authors:  Toshio Miyata; Norio Suzuki; Charles van Ypersele de Strihou
Journal:  Kidney Int       Date:  2013-03-13       Impact factor: 10.612

9.  BRG1 and BRM chromatin-remodeling complexes regulate the hypoxia response by acting as coactivators for a subset of hypoxia-inducible transcription factor target genes.

Authors:  Johnny A Sena; Liyi Wang; Cheng-Jun Hu
Journal:  Mol Cell Biol       Date:  2013-07-29       Impact factor: 4.272

10.  H3.3 actively marks enhancers and primes gene transcription via opening higher-ordered chromatin.

Authors:  Ping Chen; Jicheng Zhao; Yan Wang; Min Wang; Haizhen Long; Dan Liang; Li Huang; Zengqi Wen; Wei Li; Xia Li; Hongli Feng; Haiyong Zhao; Ping Zhu; Ming Li; Qian-fei Wang; Guohong Li
Journal:  Genes Dev       Date:  2013-09-24       Impact factor: 11.361
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  22 in total

Review 1.  Therapeutic targeting of the HIF oxygen-sensing pathway: Lessons learned from clinical studies.

Authors:  Volker H Haase
Journal:  Exp Cell Res       Date:  2017-05-05       Impact factor: 3.905

2.  Distinct subpopulations of FOXD1 stroma-derived cells regulate renal erythropoietin.

Authors:  Hanako Kobayashi; Qingdu Liu; Thomas C Binns; Andres A Urrutia; Olena Davidoff; Pinelopi P Kapitsinou; Andrew S Pfaff; Hannes Olauson; Annika Wernerson; Agnes B Fogo; Guo-Hua Fong; Kenneth W Gross; Volker H Haase
Journal:  J Clin Invest       Date:  2016-04-18       Impact factor: 14.808

Review 3.  HIF prolyl hydroxylase inhibitors for the treatment of renal anaemia and beyond.

Authors:  Patrick H Maxwell; Kai-Uwe Eckardt
Journal:  Nat Rev Nephrol       Date:  2015-12-14       Impact factor: 28.314

Review 4.  Advances in understanding the mechanisms of erythropoiesis in homeostasis and disease.

Authors:  Raymond Liang; Saghi Ghaffari
Journal:  Br J Haematol       Date:  2016-07-21       Impact factor: 6.998

Review 5.  Targeting EPO and EPO receptor pathways in anemia and dysregulated erythropoiesis.

Authors:  Nicole Rainville; Edward Jachimowicz; Don M Wojchowski
Journal:  Expert Opin Ther Targets       Date:  2015-09-30       Impact factor: 6.902

6.  Prolyl-4-hydroxylase 2 and 3 coregulate murine erythropoietin in brain pericytes.

Authors:  Andres A Urrutia; Aqeela Afzal; Jacob Nelson; Olena Davidoff; Kenneth W Gross; Volker H Haase
Journal:  Blood       Date:  2016-09-28       Impact factor: 22.113

Review 7.  What can we learn from ineffective erythropoiesis in thalassemia?

Authors:  Paraskevi Rea Oikonomidou; Stefano Rivella
Journal:  Blood Rev       Date:  2017-10-03       Impact factor: 8.250

Review 8.  Roles of renal erythropoietin-producing (REP) cells in the maintenance of systemic oxygen homeostasis.

Authors:  Norio Suzuki; Masayuki Yamamoto
Journal:  Pflugers Arch       Date:  2015-10-10       Impact factor: 3.657

9.  Chromatin occupancy and epigenetic analysis reveal new insights into the function of the GATA1 N terminus in erythropoiesis.

Authors:  Te Ling; Yehudit Birger; Monika J Stankiewicz; Nissim Ben-Haim; Tomer Kalisky; Avigail Rein; Eitan Kugler; Wei Chen; Chunling Fu; Kevin Zhang; Hiral Patel; Jacek W Sikora; Young Ah Goo; Neil Kelleher; Lihua Zou; Shai Izraeli; John D Crispino
Journal:  Blood       Date:  2019-11-07       Impact factor: 22.113

Review 10.  Mechanisms of erythrocyte development and regeneration: implications for regenerative medicine and beyond.

Authors:  Emery H Bresnick; Kyle J Hewitt; Charu Mehta; Sunduz Keles; Robert F Paulson; Kirby D Johnson
Journal:  Development       Date:  2018-01-10       Impact factor: 6.868
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