Literature DB >> 27615140

When β-cells fail: lessons from dedifferentiation.

D Accili1, S C Talchai2, J Y Kim-Muller2, F Cinti2, E Ishida2, A M Ordelheide2, T Kuo2, J Fan2, J Son2.   

Abstract

Diabetes is caused by a combination of impaired responsiveness to insulin and reduced production of insulin by the pancreas. Until recently, the decline of insulin production had been ascribed to β-cell death. But recent research has shown that β-cells do not die in diabetes, but undergo a silencing process, termed "dedifferentiation." The main implication of this discovery is that β-cells can be revived by appropriate treatments. We have shown that mitochondrial abnormalities are a key step in the progression of β-cell dysfunction towards dedifferentiation. In normal β-cells, mitochondria generate energy required to sustain insulin production and its finely timed release in response to the body's nutritional status. A normal β-cell can adapt its mitochondrial fuel source based on substrate availability, a concept known as "metabolic flexibility." This capability is the first casualty in the progress of β-cell failure. β-Cells lose the ability to select the right fuel for mitochondrial energy production. Mitochondria become overloaded, and accumulate by-products derived from incomplete fuel utilization. Energy production stalls, and insulin production drops, setting the stage for dedifferentiation. The ultimate goal of these investigations is to explore novel treatment paradigms that will benefit people with diabetes.
© 2016 John Wiley & Sons Ltd.

Entities:  

Keywords:  aldehyde dehydrogenase; biomarker; genetics; human disease; lineage marker; progenitor cells; regeneration; therapeutic failure

Mesh:

Substances:

Year:  2016        PMID: 27615140      PMCID: PMC5021187          DOI: 10.1111/dom.12723

Source DB:  PubMed          Journal:  Diabetes Obes Metab        ISSN: 1462-8902            Impact factor:   6.577


  68 in total

1.  FoxOs integrate pleiotropic actions of insulin in vascular endothelium to protect mice from atherosclerosis.

Authors:  Kyoichiro Tsuchiya; Jun Tanaka; Yu Shuiqing; Carrie L Welch; Ronald A DePinho; Ira Tabas; Alan R Tall; Ira J Goldberg; Domenico Accili
Journal:  Cell Metab       Date:  2012-03-07       Impact factor: 27.287

2.  Uncoupling of acetylation from phosphorylation regulates FoxO1 function independent of its subcellular localization.

Authors:  Li Qiang; Alexander S Banks; Domenico Accili
Journal:  J Biol Chem       Date:  2010-06-02       Impact factor: 5.157

3.  Homozygosity for an allele encoding deacetylated FoxO1 protects macrophages from cholesterol-induced inflammation without increasing apoptosis.

Authors:  Kyoichiro Tsuchiya; Alexander S Banks; Chien-Ping Liang; Ira Tabas; Alan R Tall; Domenico Accili
Journal:  Arterioscler Thromb Vasc Biol       Date:  2011-09-22       Impact factor: 8.311

4.  Diet-induced improvement of abnormalities in insulin and glucagon secretion and in insulin receptor binding in diabetes mellitus.

Authors:  P J Savage; L J Bennion; E V Flock; M Nagulesparan; D Mott; J Roth; R H Unger; P H Bennett
Journal:  J Clin Endocrinol Metab       Date:  1979-06       Impact factor: 5.958

5.  Dual role of transcription factor FoxO1 in controlling hepatic insulin sensitivity and lipid metabolism.

Authors:  Michihiro Matsumoto; Seongah Han; Tadahiro Kitamura; Domenico Accili
Journal:  J Clin Invest       Date:  2006-08-10       Impact factor: 14.808

6.  Redox control of exocytosis: regulatory role of NADPH, thioredoxin, and glutaredoxin.

Authors:  Rosita Ivarsson; Roel Quintens; Sandra Dejonghe; Katsura Tsukamoto; Peter in 't Veld; Erik Renström; Frans C Schuit
Journal:  Diabetes       Date:  2005-07       Impact factor: 9.461

7.  Pancreatic β cell dedifferentiation as a mechanism of diabetic β cell failure.

Authors:  Chutima Talchai; Shouhong Xuan; Hua V Lin; Lori Sussel; Domenico Accili
Journal:  Cell       Date:  2012-09-14       Impact factor: 41.582

8.  The obesity susceptibility gene Cpe links FoxO1 signaling in hypothalamic pro-opiomelanocortin neurons with regulation of food intake.

Authors:  Leona Plum; Hua V Lin; Roxanne Dutia; Jun Tanaka; Kumiko S Aizawa; Michihiro Matsumoto; Andrea J Kim; Niamh X Cawley; Ji-Hye Paik; Y Peng Loh; Ronald A DePinho; Sharon L Wardlaw; Domenico Accili
Journal:  Nat Med       Date:  2009-09-20       Impact factor: 53.440

9.  TGFβ Pathway Inhibition Redifferentiates Human Pancreatic Islet β Cells Expanded In Vitro.

Authors:  Ginat Toren-Haritan; Shimon Efrat
Journal:  PLoS One       Date:  2015-09-29       Impact factor: 3.240

10.  Expression of mesenchymal and α-cell phenotypic markers in islet β-cells in recently diagnosed diabetes.

Authors:  Michael G White; Helen L Marshall; Rebecca Rigby; Guo Cai Huang; Aimen Amer; Trevor Booth; Steve White; James A M Shaw
Journal:  Diabetes Care       Date:  2013-09-23       Impact factor: 19.112
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  36 in total

1.  Induction of α cell-restricted Gc in dedifferentiating β cells contributes to stress-induced β-cell dysfunction.

Authors:  Taiyi Kuo; Manashree Damle; Bryan J González; Dieter Egli; Mitchell A Lazar; Domenico Accili
Journal:  JCI Insight       Date:  2019-05-23

Review 2.  β-Cell Fate in Human Insulin Resistance and Type 2 Diabetes: A Perspective on Islet Plasticity.

Authors:  Teresa Mezza; Francesca Cinti; Chiara Maria Assunta Cefalo; Alfredo Pontecorvi; Rohit N Kulkarni; Andrea Giaccari
Journal:  Diabetes       Date:  2019-06       Impact factor: 9.461

3.  Chronic fractalkine administration improves glucose tolerance and pancreatic endocrine function.

Authors:  Matthew Riopel; Jong Bae Seo; Gautam K Bandyopadhyay; Pingping Li; Joshua Wollam; Heekyung Chung; Seung-Ryoung Jung; Anne Murphy; Maria Wilson; Ron de Jong; Sanjay Patel; Deepika Balakrishna; James Bilakovics; Andrea Fanjul; Artur Plonowski; Duk-Su Koh; Christopher J Larson; Jerrold M Olefsky; Yun Sok Lee
Journal:  J Clin Invest       Date:  2018-03-05       Impact factor: 14.808

Review 4.  Mechanisms controlling pancreatic islet cell function in insulin secretion.

Authors:  Jonathan E Campbell; Christopher B Newgard
Journal:  Nat Rev Mol Cell Biol       Date:  2021-01-04       Impact factor: 94.444

Review 5.  Pancreas regeneration.

Authors:  Qiao Zhou; Douglas A Melton
Journal:  Nature       Date:  2018-05-16       Impact factor: 49.962

Review 6.  Recent Insights Into Mechanisms of β-Cell Lipo- and Glucolipotoxicity in Type 2 Diabetes.

Authors:  Maria Lytrivi; Anne-Laure Castell; Vincent Poitout; Miriam Cnop
Journal:  J Mol Biol       Date:  2019-10-16       Impact factor: 5.469

7.  Conversion of the death inhibitor ARC to a killer activates pancreatic β cell death in diabetes.

Authors:  Wendy M McKimpson; Yun Chen; James A Irving; Min Zheng; Jeremy Weinberger; Wilson Lek Wen Tan; Zenia Tiang; Alistair M Jagger; Streamson C Chua; Jeffrey E Pessin; Roger S-Y Foo; David A Lomas; Richard N Kitsis
Journal:  Dev Cell       Date:  2021-03-04       Impact factor: 12.270

Review 8.  Human beta cell mass and function in diabetes: Recent advances in knowledge and technologies to understand disease pathogenesis.

Authors:  Chunguang Chen; Christian M Cohrs; Julia Stertmann; Robert Bozsak; Stephan Speier
Journal:  Mol Metab       Date:  2017-07-08       Impact factor: 7.422

9.  Microtubules and Gαo-signaling modulate the preferential secretion of young insulin secretory granules in islet β cells via independent pathways.

Authors:  Ruiying Hu; Xiaodong Zhu; Mingyang Yuan; Kung-Hsien Ho; Irina Kaverina; Guoqiang Gu
Journal:  PLoS One       Date:  2021-07-22       Impact factor: 3.240

Review 10.  Stress-Induced Translational Regulation Mediated by RNA Binding Proteins: Key Links to β-Cell Failure in Diabetes.

Authors:  Austin L Good; Doris A Stoffers
Journal:  Diabetes       Date:  2020-04       Impact factor: 9.337
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