Literature DB >> 26152724

miR-184 Regulates Pancreatic β-Cell Function According to Glucose Metabolism.

Sudhir G Tattikota1, Thomas Rathjen1, Jean Hausser2, Aditya Khedkar1, Uma D Kabra3, Varun Pandey4, Matthias Sury1, Hans-Hermann Wessels1, Inês G Mollet5, Lena Eliasson5, Matthias Selbach1, Robert P Zinzen1, Mihaela Zavolan2, Sebastian Kadener4, Matthias H Tschöp3, Martin Jastroch3, Marc R Friedländer6, Matthew N Poy7.   

Abstract

In response to fasting or hyperglycemia, the pancreatic β-cell alters its output of secreted insulin; however, the pathways governing this adaptive response are not entirely established. Although the precise role of microRNAs (miRNAs) is also unclear, a recurring theme emphasizes their function in cellular stress responses. We recently showed that miR-184, an abundant miRNA in the β-cell, regulates compensatory proliferation and secretion during insulin resistance. Consistent with previous studies showing miR-184 suppresses insulin release, expression of this miRNA was increased in islets after fasting, demonstrating an active role in the β-cell as glucose levels lower and the insulin demand ceases. Additionally, miR-184 was negatively regulated upon the administration of a sucrose-rich diet in Drosophila, demonstrating strong conservation of this pathway through evolution. Furthermore, miR-184 and its target Argonaute2 remained inversely correlated as concentrations of extracellular glucose increased, underlining a functional relationship between this miRNA and its targets. Lastly, restoration of Argonaute2 in the presence of miR-184 rescued suppression of miR-375-targeted genes, suggesting these genes act in a coordinated manner during changes in the metabolic context. Together, these results highlight the adaptive role of miR-184 according to glucose metabolism and suggest the regulatory role of this miRNA in energy homeostasis is highly conserved.
© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.

Entities:  

Keywords:  Argonaute; beta cell (B-cell); glucose metabolism; insulin; insulin secretion; microRNA (miRNA); microRNA mechanism; pancreatic islet

Mesh:

Substances:

Year:  2015        PMID: 26152724      PMCID: PMC4536436          DOI: 10.1074/jbc.M115.658625

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


  39 in total

1.  Compensatory growth of pancreatic beta-cells in adult rats after short-term glucose infusion.

Authors:  S Bonner-Weir; D Deery; J L Leahy; G C Weir
Journal:  Diabetes       Date:  1989-01       Impact factor: 9.461

2.  Glucokinase and IRS-2 are required for compensatory beta cell hyperplasia in response to high-fat diet-induced insulin resistance.

Authors:  Yasuo Terauchi; Iseki Takamoto; Naoto Kubota; Junji Matsui; Ryo Suzuki; Kajuro Komeda; Akemi Hara; Yukiyasu Toyoda; Ichitomo Miwa; Shinichi Aizawa; Shuichi Tsutsumi; Yoshiharu Tsubamoto; Shinji Hashimoto; Kazuhiro Eto; Akinobu Nakamura; Mitsuhiko Noda; Kazuyuki Tobe; Hiroyuki Aburatani; Ryozo Nagai; Takashi Kadowaki
Journal:  J Clin Invest       Date:  2007-01       Impact factor: 14.808

3.  Control of pancreatic β cell regeneration by glucose metabolism.

Authors:  Shay Porat; Noa Weinberg-Corem; Sharona Tornovsky-Babaey; Rachel Schyr-Ben-Haroush; Ayat Hija; Miri Stolovich-Rain; Daniela Dadon; Zvi Granot; Vered Ben-Hur; Peter White; Christophe A Girard; Rotem Karni; Klaus H Kaestner; Frances M Ashcroft; Mark A Magnuson; Ann Saada; Joseph Grimsby; Benjamin Glaser; Yuval Dor
Journal:  Cell Metab       Date:  2011-04-06       Impact factor: 27.287

Review 4.  MicroRNAs in stress signaling and human disease.

Authors:  Joshua T Mendell; Eric N Olson
Journal:  Cell       Date:  2012-03-16       Impact factor: 41.582

5.  miR-375 maintains normal pancreatic alpha- and beta-cell mass.

Authors:  Matthew N Poy; Jean Hausser; Mirko Trajkovski; Matthias Braun; Stephan Collins; Patrik Rorsman; Mihaela Zavolan; Markus Stoffel
Journal:  Proc Natl Acad Sci U S A       Date:  2009-03-16       Impact factor: 11.205

6.  The effect of fasting, diet, and actinomycin D on insulin secretion in the rat.

Authors:  N J Grey; S Goldring; D M Kipnis
Journal:  J Clin Invest       Date:  1970-05       Impact factor: 14.808

7.  Argonaute2 regulates the pancreatic β-cell secretome.

Authors:  Sudhir G Tattikota; Matthias D Sury; Thomas Rathjen; Hans-Hermann Wessels; Amit K Pandey; Xintian You; Clinton Becker; Wei Chen; Matthias Selbach; Matthew N Poy
Journal:  Mol Cell Proteomics       Date:  2013-01-28       Impact factor: 5.911

8.  MicroRNA directly enhances mitochondrial translation during muscle differentiation.

Authors:  Xiaorong Zhang; Xinxin Zuo; Bo Yang; Zongran Li; Yuanchao Xue; Yu Zhou; Jie Huang; Xiaolu Zhao; Jie Zhou; Yun Yan; Huiqiong Zhang; Peipei Guo; Hui Sun; Lin Guo; Yi Zhang; Xiang-Dong Fu
Journal:  Cell       Date:  2014-07-31       Impact factor: 41.582

9.  Polycomb protein Ezh2 regulates pancreatic beta-cell Ink4a/Arf expression and regeneration in diabetes mellitus.

Authors:  Hainan Chen; Xueying Gu; I-hsin Su; Rita Bottino; Juan L Contreras; Alexander Tarakhovsky; Seung K Kim
Journal:  Genes Dev       Date:  2009-04-15       Impact factor: 11.361

10.  microRNA target predictions across seven Drosophila species and comparison to mammalian targets.

Authors:  Dominic Grün; Yi-Lu Wang; David Langenberger; Kristin C Gunsalus; Nikolaus Rajewsky
Journal:  PLoS Comput Biol       Date:  2005-06-24       Impact factor: 4.475
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  24 in total

Review 1.  Epigenetics in β-cell adaptation and type 2 diabetes.

Authors:  Hyunki Kim; Rohit N Kulkarni
Journal:  Curr Opin Pharmacol       Date:  2020-11-21       Impact factor: 5.547

2.  Nutrient dependent miR-184 aids in the survival of Drosophila larvae during low food conditions.

Authors:  Jervis Fernandes; Elwina Thomas; Jishy Varghese
Journal:  MicroPubl Biol       Date:  2022-03-17

Review 3.  Regulatory Roles of MicroRNAs in Diabetes.

Authors:  Juan Feng; Wanli Xing; Lan Xie
Journal:  Int J Mol Sci       Date:  2016-10-17       Impact factor: 5.923

4.  Systematic Identification and Characterization of Long Non-Coding RNAs in the Silkworm, Bombyx mori.

Authors:  Yuqian Wu; Tingcai Cheng; Chun Liu; Duolian Liu; Quan Zhang; Renwen Long; Ping Zhao; Qingyou Xia
Journal:  PLoS One       Date:  2016-01-15       Impact factor: 3.240

Review 5.  MiRNAs in β-Cell Development, Identity, and Disease.

Authors:  Aida Martinez-Sanchez; Guy A Rutter; Mathieu Latreille
Journal:  Front Genet       Date:  2017-01-11       Impact factor: 4.599

Review 6.  MicroRNAs as stress regulators in pancreatic beta cells and diabetes.

Authors:  Mary P LaPierre; Markus Stoffel
Journal:  Mol Metab       Date:  2017-07-18       Impact factor: 7.422

7.  Curcumin represses mouse 3T3-L1 cell adipogenic differentiation via inhibiting miR-17-5p and stimulating the Wnt signalling pathway effector Tcf7l2.

Authors:  Lili Tian; Zhuolun Song; Weijuan Shao; William W Du; Lisa R Zhao; Kejing Zeng; Burton B Yang; Tianru Jin
Journal:  Cell Death Dis       Date:  2017-01-19       Impact factor: 8.469

Review 8.  A Brief Review of the Mechanisms of β-Cell Dedifferentiation in Type 2 Diabetes.

Authors:  Phyu-Phyu Khin; Jong-Han Lee; Hee-Sook Jun
Journal:  Nutrients       Date:  2021-05-10       Impact factor: 5.717

Review 9.  MicroRNAs in metabolism.

Authors:  S Vienberg; J Geiger; S Madsen; L T Dalgaard
Journal:  Acta Physiol (Oxf)       Date:  2016-04-05       Impact factor: 6.311

10.  Identification of Neuroendocrine Stress Response-Related Circulating MicroRNAs as Biomarkers for Type 2 Diabetes Mellitus and Insulin Resistance.

Authors:  Ying-Zhi Liang; Jing Dong; Jie Zhang; Shuo Wang; Yan He; Yu-Xiang Yan
Journal:  Front Endocrinol (Lausanne)       Date:  2018-03-28       Impact factor: 5.555
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