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Vol 68, No 5 (2017)
Review paper
Submitted: 2017-01-14
Accepted: 2017-01-20
Published online: 2017-11-03
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Glucocorticoids and beta-cell function

Marta Fichna, Piotr Fichna
DOI: 10.5603/EP.2017.0060
·
Pubmed: 29168546
·
Endokrynol Pol 2017;68(5):568-573.

open access

Vol 68, No 5 (2017)
Review Article
Submitted: 2017-01-14
Accepted: 2017-01-20
Published online: 2017-11-03

Abstract

Glucocorticoids (GCs) play a pivotal role in carbohydrate metabolism. They counteract insulin by decreasing peripheral glucose uptake and stimulating hepatic gluconeogenesis, although they are best known for inducing insulin resistance (IR). Moreover, GCs may attenuate the incretin effect. Nevertheless, their direct impact on beta cells is not fully defined. This review aims to present the current understanding of this subject.

Humans exposed to GC excess display IR, impaired glucose tolerance, and eventually develop diabetes. Although their insulin levels are elevated, they present lower insulin output in response to glucose than obese individuals. Rodent models demonstrate that GC-induced IR is accompanied by compensatory beta-cell hyperplasia. GC excess with high-fat diet leads to fasting hyperglycaemia and suppressed glucose-stimulated insulin secretion (GSIS) despite increased beta cell mass.

The majority of in vitro studies confirm an inhibitory GC effect on insulin secretion. The mechanism remains ambiguous but might involve its direct influence upon expression of molecules essential for glucose sensing and metabolism, enhanced glucose cycling, down-regulated insulin gene transcription, hampered insulin exocytosis, amplified alpha-adrenergic signalling, and/or increased beta-cell apoptosis. There are also reports that suggest increased GSIS after beta cell exposure to GCs in vitro. Transgenic mice with enhanced corticosterone regeneration within their beta cells present augmented secretory capacity of their islets.

To summarise, GCs exert a significant role in carbohydrate balance through various mechanisms, including direct impact on beta cell function. Observed discrepancies may arise from differences in study design. A thorough understanding of GC action will provide important clinical clues for disorders of glucose homeostasis.

Abstract

Glucocorticoids (GCs) play a pivotal role in carbohydrate metabolism. They counteract insulin by decreasing peripheral glucose uptake and stimulating hepatic gluconeogenesis, although they are best known for inducing insulin resistance (IR). Moreover, GCs may attenuate the incretin effect. Nevertheless, their direct impact on beta cells is not fully defined. This review aims to present the current understanding of this subject.

Humans exposed to GC excess display IR, impaired glucose tolerance, and eventually develop diabetes. Although their insulin levels are elevated, they present lower insulin output in response to glucose than obese individuals. Rodent models demonstrate that GC-induced IR is accompanied by compensatory beta-cell hyperplasia. GC excess with high-fat diet leads to fasting hyperglycaemia and suppressed glucose-stimulated insulin secretion (GSIS) despite increased beta cell mass.

The majority of in vitro studies confirm an inhibitory GC effect on insulin secretion. The mechanism remains ambiguous but might involve its direct influence upon expression of molecules essential for glucose sensing and metabolism, enhanced glucose cycling, down-regulated insulin gene transcription, hampered insulin exocytosis, amplified alpha-adrenergic signalling, and/or increased beta-cell apoptosis. There are also reports that suggest increased GSIS after beta cell exposure to GCs in vitro. Transgenic mice with enhanced corticosterone regeneration within their beta cells present augmented secretory capacity of their islets.

To summarise, GCs exert a significant role in carbohydrate balance through various mechanisms, including direct impact on beta cell function. Observed discrepancies may arise from differences in study design. A thorough understanding of GC action will provide important clinical clues for disorders of glucose homeostasis.

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Keywords

glucocorticoids, beta cell, insulin

About this article
Title

Glucocorticoids and beta-cell function

Journal

Endokrynologia Polska

Issue

Vol 68, No 5 (2017)

Article type

Review paper

Pages

568-573

Published online

2017-11-03

Page views

4501

Article views/downloads

5059

DOI

10.5603/EP.2017.0060

Pubmed

29168546

Bibliographic record

Endokrynol Pol 2017;68(5):568-573.

Keywords

glucocorticoids
beta cell
insulin

Authors

Marta Fichna
Piotr Fichna

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