MAFA controls genes implicated in insulin biosynthesis and secretion

Wang, H.; Brun, Thierry; Kataoka, Kohsuke; Sharma, Arun; Wollheim, Claes B.

doi:10.1007/s00125-006-0490-2

Cited by 182 publications

(153 citation statements)

References 65 publications

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“…In addition, Neurogenin3 has also been A portion of our phenotype observed may be due to an increase in the expression of MafA, which is known to control genes implicated in insulin secretion. [38][39][40] However, we have also identified ~135 differentially expressed genes from our microarray and were able to confirm an increase in expression in a subset of these genes by real-time PCR in islets of Pdx1 PB -Isl-1-Myc mice. These genes are implicated to function in protein trafficking and metabolism, and may play important roles in β-cell biology.…”

Section: Discussionmentioning

confidence: 91%

Elevation of transcription factor Islet-1 levels in vivo increases β-cell function but not β-cell mass

Liu

Walp

May

2012

Islets

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Section: Discussionmentioning

confidence: 91%

Elevation of transcription factor Islet-1 levels in vivo increases β-cell function but not β-cell mass

Liu

Walp

May

2012

Islets

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“…During development, MafA was shown to be exclusively produced in insulinpositive cells and essential for insulin gene transcription [19]. In addition, MafA was shown to be a master regulator of genes implicated in maintaining beta cell function [47]. In mice lacking MafA, reduced insulin 1 and 2 gene transcription, glucose intolerance and development of diabetes mellitus was observed [12].…”

Section: Discussionmentioning

confidence: 99%

Inhibition of MafA transcriptional activity and human insulin gene transcription by interleukin-1β and mitogen-activated protein kinase kinase kinase in pancreatic islet beta cells

et al. 2007

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Aims/hypothesis Inappropriate insulin secretion and biosynthesis are hallmarks of beta cell dysfunction and contribute to the progression from a prediabetic state to overt diabetes mellitus. During the prediabetic state, beta cells are exposed to elevated levels of proinflammatory cytokines. In the present study the effect of these cytokines and mitogen-activated protein kinase kinase kinase 1 (MEKK1), which is known to be activated by these cytokines, on human insulin gene (INS) transcription was investigated. Methods Biochemical methods and reporter gene assays were used in a beta cell line and in primary pancreatic islets from transgenic mice. Results IL-1β and MEKK1 specifically inhibited basal and membrane depolarisation and cAMP-induced INS transcription in the beta cell line. Also, in primary islets of reporter gene mice, IL-1β reduced glucose-stimulated INS transcription. A 5′-and 3′-deletion and internal mutation analysis revealed the rat insulin promoter element 3b (RIPE3b) to be a decisive MEKK1-responsive element of the INS. RIPE3b conferred strong transcriptional activity to a heterologous promoter, and this activity was markedly inhibited by MEKK1 and IL-1β. RIPE3b is also known to recruit the transcription factor MafA. We found here that MafA transcription activity is markedly inhibited by MEKK1 and IL-1β. Conclusions/interpretation These data suggest that IL-1β through MEKK1 inhibits INS transcription and does so, at least in part, by decreasing MafA transcriptional activity at the RIPE3b control element. Since inappropriate insulin biosynthesis contributes to beta cell dysfunction, inhibition of MEKK1 might decelerate or prevent progression from a prediabetic state to diabetes mellitus.

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“…MAFA is a master regulator of genes implicated in beta cell function, including proinsulin processing (prohormone convertase 1/3) in INS1 cells [28], glucose sensing (Slc2a2), vesicle maturation (Slc30a8), Ca 2+ signalling (Camk2b) and insulin secretion (Nnat) [14,29]. Accordingly, Mafa overexpression enhances GSIS in neonatal rat beta cells [15].…”

Section: Discussionmentioning

confidence: 99%

Growth arrest specific protein (GAS) 6: a role in the regulation of proliferation and functional capacity of the perinatal rat beta cell

et al. 2013

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Aims/hypothesis Maternal low-protein (LP) diet during gestation results in a reduced beta cell mass in the offspring at birth and this may hamper the ability to adapt to high-energy food and sedentary lifestyle later in life. To investigate the biology behind the LP-offspring phenotype, this study aimed to identify differentially expressed genes in the pancreas and their potential role in the fetal programming. Methods Wistar rats were given either an LP diet or normalchow (NC) diet during gestation and differentially expressed genes in the offspring around the time of birth were identified using RNA microarray and quantitative PCR. The role of a differentially expressed gene, growth arrest specific protein 6 (GAS6), was evaluated in vitro using neonatal rat islets.Results The mRNA level of Gas6, known to be mitogenic in other tissues, was reduced in LP offspring. The mRNA content of Mafa was increased in LP offspring suggesting an early maturation of beta cells. When applied in vitro, GAS6 increased proliferation of neonatal pancreatic beta cells, while reducing glucose-stimulated insulin secretion without changing the total insulin content of the islets. In addition, GAS6 decreased the mRNA content of Mafa. Conclusions/interpretation We propose a role for GAS6 in the regulation of pancreatic beta cells in the critical period around the time of birth. Our results support the hypothesis that the reduced beta cell mass seen in LP offspring is caused by a change in the intra-uterine environment that favours premature maturation of the beta cells.Keywords Fetal programming . Growth arrest specific protein 6 (GAS6) . Pancreatic beta cells

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MAFA controls genes implicated in insulin biosynthesis and secretion

Cited by 182 publications

References 65 publications

Elevation of transcription factor Islet-1 levels in vivo increases β-cell function but not β-cell mass

Elevation of transcription factor Islet-1 levels in vivo increases β-cell function but not β-cell mass

Inhibition of MafA transcriptional activity and human insulin gene transcription by interleukin-1β and mitogen-activated protein kinase kinase kinase in pancreatic islet beta cells

Growth arrest specific protein (GAS) 6: a role in the regulation of proliferation and functional capacity of the perinatal rat beta cell

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