Literature DB >> 17026486

Catecholamine storage vesicles and the metabolic syndrome: The role of the chromogranin A fragment pancreastatin.

Kuixing Zhang1, Fangwen Rao, Gen Wen, Rany M Salem, Sucheta Vaingankar, Manjula Mahata, Nitish R Mahapatra, Elizabeth O Lillie, Peter E Cadman, Ryan S Friese, Bruce A Hamilton, Vivian Y Hook, Sushil K Mahata, Laurent Taupenot, Daniel T O'Connor.   

Abstract

Chromogranins or secretogranins (granins), present in secretory granules of virtually all neuroendocrine cells and neurones, are structurally related proteins encoded by different genetic loci: chromogranins A and B, and secretogranins II through VI. Compelling evidence supports both intracellular and extracellular functions for this protein family. Within the cells of origin, a granulogenic or sorting role in the regulated pathway of hormone or neurotransmitter secretion has been documented, especially for chromogranin A (CHGA). Granins also function as pro-hormones, giving rise by proteolytic processing to an array of peptide fragments for which diverse autocrine, paracrine, and endocrine activities have been demonstrated. CHGA measurements yield insight into the pathogenesis of such human diseases as essential hypertension, in which deficiency of the catecholamine release-inhibitory CHGA fragment catestatin may trigger sympathoadrenal overactivity as an aetiologic culprit in the syndrome. The CHGA dysglycaemic fragment pancreastatin is functional in humans in vivo, affecting both carbohydrate (glucose) and lipid (fatty acid) metabolism. Pancreastatin is cleaved from CHGA in hormone storage granules in vivo, and its plasma concentration varies in human disease. The pancreastatin region of CHGA gives rise to three naturally occurring human variants, one of which (Gly297Ser) occurs in the functionally important carboxy-terminus of the peptide, and substantially increases the peptide's potency to inhibit cellular glucose uptake. These observations establish a role for pancreastatin in human intermediary metabolism and disease, and suggest that qualitative hereditary alterations in pancreastatin's primary structure may give rise to interindividual differences in glucose disposition.

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Year:  2006        PMID: 17026486     DOI: 10.1111/j.1463-1326.2006.00575.x

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


  15 in total

1.  Molecular Mechanism for Hypertensive Renal Disease: Differential Regulation of Chromogranin A Expression at 3'-Untranslated Region Polymorphism C+87T by MicroRNA-107.

Authors:  Kuixing Zhang; Saiful A Mir; C Makena Hightower; Jose Pablo Miramontes-Gonzalez; Adam X Maihofer; Yuqing Chen; Sushil K Mahata; Caroline M Nievergelt; Nicholas J Schork; Barry I Freedman; Sucheta M Vaingankar; Daniel T O'Connor
Journal:  J Am Soc Nephrol       Date:  2014-11-12       Impact factor: 10.121

2.  Naturally occurring variants of the dysglycemic peptide pancreastatin: differential potencies for multiple cellular functions and structure-function correlation.

Authors:  Prasanna K R Allu; Venkat R Chirasani; Dhiman Ghosh; Anitha Mani; Amal K Bera; Samir K Maji; Sanjib Senapati; Ajit S Mullasari; Nitish R Mahapatra
Journal:  J Biol Chem       Date:  2013-12-12       Impact factor: 5.157

3.  Systematic polymorphism discovery after genome-wide identification of potential susceptibility loci in a hereditary rodent model of human hypertension.

Authors:  Ryan S Friese; Geert W Schmid-Schönbein; Daniel T O'Connor
Journal:  Blood Press       Date:  2011-03-23       Impact factor: 2.835

Review 4.  Chromogranin A and the tumor microenvironment.

Authors:  Angelo Corti
Journal:  Cell Mol Neurobiol       Date:  2010-11-16       Impact factor: 5.046

5.  Profiles of secreted neuropeptides and catecholamines illustrate similarities and differences in response to stimulation by distinct secretagogues.

Authors:  Sonia Podvin; Richard Bundey; Thomas Toneff; Michael Ziegler; Vivian Hook
Journal:  Mol Cell Neurosci       Date:  2015-06-16       Impact factor: 4.314

6.  Expression of Secretogranin III in Chicken Endocrine Cells: Its Relevance to the Secretory Granule Properties of Peptide Prohormone Processing and Bioactive Amine Content.

Authors:  Hiroshi Gomi; Satomi Morikawa; Naoki Shinmura; Hiroaki Moki; Tadashi Yasui; Azuma Tsukise; Seiji Torii; Tsuyoshi Watanabe; Yoshinori Maeda; Masahiro Hosaka
Journal:  J Histochem Cytochem       Date:  2015-02-11       Impact factor: 2.479

7.  Global metabolic consequences of the chromogranin A-null model of hypertension: transcriptomic detection, pathway identification, and experimental verification.

Authors:  Ryan S Friese; Jiaur R Gayen; Nitish R Mahapatra; Geert W Schmid-Schönbein; Daniel T O'Connor; Sushil K Mahata
Journal:  Physiol Genomics       Date:  2009-12-01       Impact factor: 3.107

Review 8.  Secretory granules in inositol 1,4,5-trisphosphate-dependent Ca2+ signaling in the cytoplasm of neuroendocrine cells.

Authors:  Seung Hyun Yoo
Journal:  FASEB J       Date:  2009-10-16       Impact factor: 5.191

9.  Functional genetic variants of the catecholamine-release-inhibitory peptide catestatin in an Indian population: allele-specific effects on metabolic traits.

Authors:  Bhavani S Sahu; Jagan M Obbineni; Giriraj Sahu; Prasanna K R Allu; Lakshmi Subramanian; Parshuram J Sonawane; Pradeep K Singh; Binu K Sasi; Sanjib Senapati; Samir K Maji; Amal K Bera; Balashankar S Gomathi; Ajit S Mullasari; Nitish R Mahapatra
Journal:  J Biol Chem       Date:  2012-10-26       Impact factor: 5.157

Review 10.  Circulating chromogranin A and its fragments as diagnostic and prognostic disease markers.

Authors:  Angelo Corti; Fabrizio Marcucci; Tiziana Bachetti
Journal:  Pflugers Arch       Date:  2017-10-10       Impact factor: 3.657

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