Literature DB >> 29669812

Tankyrase modulates insulin sensitivity in skeletal muscle cells by regulating the stability of GLUT4 vesicle proteins.

Zhiduan Su1, Vinita Deshpande1, David E James2,3, Jacqueline Stöckli4.   

Abstract

Tankyrase 1 and 2, members of the poly(ADP-ribose) polymerase family, have previously been shown to play a role in insulin-mediated glucose uptake in adipocytes. However, their precise mechanism of action, and their role in insulin action in other cell types, such as myocytes, remains elusive. Treatment of differentiated L6 myotubes with the small molecule tankyrase inhibitor XAV939 resulted in insulin resistance as determined by impaired insulin-stimulated glucose uptake. Proteomic analysis of XAV939-treated myotubes identified down-regulation of several glucose transporter GLUT4 storage vesicle (GSV) proteins including RAB10, VAMP8, SORT1, and GLUT4. A similar effect was observed following knockdown of tankyrase 1 in L6 myotubes. Inhibition of the proteasome using MG132 rescued GSV protein levels as well as insulin-stimulated glucose uptake in XAV939-treated L6 myotubes. These studies reveal an important role for tankyrase in maintaining the stability of key GLUT4 regulatory proteins that in turn plays a role in regulating cellular insulin sensitivity.
© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.

Entities:  

Keywords:  GLUT4 storage vesicle; Tankyrase; glucose transport; glucose transporter type 4 (GLUT4); insulin resistance; proteomics; skeletal muscle

Mesh:

Substances:

Year:  2018        PMID: 29669812      PMCID: PMC5986224          DOI: 10.1074/jbc.RA117.001058

Source DB:  PubMed          Journal:  J Biol Chem        ISSN: 0021-9258            Impact factor:   5.157


  62 in total

1.  Rab10, a target of the AS160 Rab GAP, is required for insulin-stimulated translocation of GLUT4 to the adipocyte plasma membrane.

Authors:  Hiroyuki Sano; Lorena Eguez; Mary N Teruel; Mitsunori Fukuda; Tuan D Chuang; Jose A Chavez; Gustav E Lienhard; Timothy E McGraw
Journal:  Cell Metab       Date:  2007-04       Impact factor: 27.287

2.  Rabs 8A and 14 are targets of the insulin-regulated Rab-GAP AS160 regulating GLUT4 traffic in muscle cells.

Authors:  Shuhei Ishikura; Philip J Bilan; Amira Klip
Journal:  Biochem Biophys Res Commun       Date:  2006-12-27       Impact factor: 3.575

3.  The RabGAP TBC1D1 plays a central role in exercise-regulated glucose metabolism in skeletal muscle.

Authors:  Jacqueline Stöckli; Christopher C Meoli; Nolan J Hoffman; Daniel J Fazakerley; Himani Pant; Mark E Cleasby; Xiuquan Ma; Maximilian Kleinert; Amanda E Brandon; Jamie A Lopez; Gregory J Cooney; David E James
Journal:  Diabetes       Date:  2015-01-09       Impact factor: 9.461

4.  The major protein of GLUT4-containing vesicles, gp160, has aminopeptidase activity.

Authors:  K V Kandror; L Yu; P F Pilch
Journal:  J Biol Chem       Date:  1994-12-09       Impact factor: 5.157

5.  Adipose tissue glucose transporters in NIDDM. Decreased levels of muscle/fat isoform.

Authors:  M K Sinha; C Raineri-Maldonado; C Buchanan; W J Pories; C Carter-Su; P F Pilch; J F Caro
Journal:  Diabetes       Date:  1991-04       Impact factor: 9.461

6.  Deletion of Rab GAP AS160 modifies glucose uptake and GLUT4 translocation in primary skeletal muscles and adipocytes and impairs glucose homeostasis.

Authors:  Melissa N Lansey; Natalie N Walker; Stefan R Hargett; Joseph R Stevens; Susanna R Keller
Journal:  Am J Physiol Endocrinol Metab       Date:  2012-09-25       Impact factor: 4.310

7.  The Inactivation of RabGAP Function of AS160 Promotes Lysosomal Degradation of GLUT4 and Causes Postprandial Hyperglycemia and Hyperinsulinemia.

Authors:  Bingxian Xie; Qiaoli Chen; Liang Chen; Yang Sheng; Hong Yu Wang; Shuai Chen
Journal:  Diabetes       Date:  2016-08-23       Impact factor: 9.461

8.  Palmitate-induced down-regulation of sortilin and impaired GLUT4 trafficking in C2C12 myotubes.

Authors:  Yo Tsuchiya; Hiroyasu Hatakeyama; Natsumi Emoto; Fumie Wagatsuma; Shinichi Matsushita; Makoto Kanzaki
Journal:  J Biol Chem       Date:  2010-08-30       Impact factor: 5.157

9.  Cloning and characterization of a novel insulin-regulated membrane aminopeptidase from Glut4 vesicles.

Authors:  S R Keller; H M Scott; C C Mastick; R Aebersold; G E Lienhard
Journal:  J Biol Chem       Date:  1995-10-06       Impact factor: 5.157

10.  Poly-ADP ribosylation of PTEN by tankyrases promotes PTEN degradation and tumor growth.

Authors:  Nan Li; Yajie Zhang; Xin Han; Ke Liang; Jiadong Wang; Lin Feng; Wenqi Wang; Zhou Songyang; Chunru Lin; Liuqing Yang; Yonghao Yu; Junjie Chen
Journal:  Genes Dev       Date:  2014-12-29       Impact factor: 11.361
View more
  10 in total

1.  ANKRD9 is a metabolically-controlled regulator of IMPDH2 abundance and macro-assembly.

Authors:  Dawn Hayward; Valentina L Kouznetsova; Hannah E Pierson; Nesrin M Hasan; Estefany R Guzman; Igor F Tsigelny; Svetlana Lutsenko
Journal:  J Biol Chem       Date:  2019-07-23       Impact factor: 5.157

2.  Unravelling the Structural Mechanism of Action of 5-methyl-5-[4-(4-oxo-3H-quinazolin-2-yl)phenyl]imidazolidine-2,4-dione in Dual-Targeting Tankyrase 1 and 2: A Novel Avenue in Cancer Therapy.

Authors:  Xylia Q Peters; Clement Agoni; Mahmoud E S Soliman
Journal:  Cell Biochem Biophys       Date:  2022-05-30       Impact factor: 2.989

Review 3.  The PARP Enzyme Family and the Hallmarks of Cancer Part 1. Cell Intrinsic Hallmarks.

Authors:  Máté A Demény; László Virág
Journal:  Cancers (Basel)       Date:  2021-04-23       Impact factor: 6.639

4.  Tankyrase inhibition ameliorates lipid disorder via suppression of PGC-1α PARylation in db/db mice.

Authors:  Hong Wang; Sara Kuusela; Rita Rinnankoski-Tuikka; Vincent Dumont; Rim Bouslama; Usama Abo Ramadan; Jo Waaler; Anni-Maija Linden; Nai-Wen Chi; Stefan Krauss; Eija Pirinen; Sanna Lehtonen
Journal:  Int J Obes (Lond)       Date:  2020-04-21       Impact factor: 5.095

5.  The deubiquitinating enzyme USP25 binds tankyrase and regulates trafficking of the facilitative glucose transporter GLUT4 in adipocytes.

Authors:  Jessica B A Sadler; Christopher A Lamb; Cassie R Welburn; Iain S Adamson; Dimitrios Kioumourtzoglou; Nai-Wen Chi; Gwyn W Gould; Nia J Bryant
Journal:  Sci Rep       Date:  2019-03-18       Impact factor: 4.379

6.  ADP-ribosylation signalling and human disease.

Authors:  Luca Palazzo; Petra Mikolčević; Andreja Mikoč; Ivan Ahel
Journal:  Open Biol       Date:  2019-04-26       Impact factor: 6.411

Review 7.  Regulation of Glucose Metabolism by NAD+ and ADP-Ribosylation.

Authors:  Ann-Katrin Hopp; Patrick Grüter; Michael O Hottiger
Journal:  Cells       Date:  2019-08-13       Impact factor: 6.600

8.  PKD-dependent PARP12-catalyzed mono-ADP-ribosylation of Golgin-97 is required for E-cadherin transport from Golgi to plasma membrane.

Authors:  Giovanna Grimaldi; Angela Filograna; Laura Schembri; Matteo Lo Monte; Rosaria Di Martino; Marinella Pirozzi; Daniela Spano; Andrea R Beccari; Seetharaman Parashuraman; Alberto Luini; Carmen Valente; Daniela Corda
Journal:  Proc Natl Acad Sci U S A       Date:  2022-01-04       Impact factor: 12.779

Review 9.  Ubiquitin-like processing of TUG proteins as a mechanism to regulate glucose uptake and energy metabolism in fat and muscle.

Authors:  Jonathan S Bogan
Journal:  Front Endocrinol (Lausanne)       Date:  2022-09-29       Impact factor: 6.055

10.  β-catenin regulates muscle glucose transport via actin remodelling and M-cadherin binding.

Authors:  Stewart W C Masson; Brie Sorrenson; Peter R Shepherd; Troy L Merry
Journal:  Mol Metab       Date:  2020-10-01       Impact factor: 7.422
  10 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.