Induction of insulin and islet amyloid polypeptide production in pancreatic islet glucagonoma cells by insulin promoter factor 1.

Serup, Palle; Jensen, Jan; Andersen, Frank G.; Jørgensen, Mette C.; Blume, Niels; Holst, Jens J.; Madsen, Ole

doi:10.1073/pnas.93.17.9015

Cited by 129 publications

(95 citation statements)

References 46 publications

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“…The MSL AN697C1 subclone gave rise to two derived cell lines, namely the glucagon-secreting AN-glu, and after stable transfection with the transcription factor pancreatic duodenal homeobox factor-1, the insulin secreting ANins (27). Despite having similar rates of NO synthesis, we found that the AN-ins cells were more susceptible to apoptosis elicited by IL-1␤.…”

mentioning

confidence: 49%

IB1 Reduces Cytokine-induced Apoptosis of Insulin-secreting Cells

Bonny¹,

Oberson²,

Steinmann³

et al. 2000

Journal of Biological Chemistry

120

109

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IB1/JIP-1 are recently characterized mammalian scaffold proteins involved in the regulation of the JNK 1 signaling pathway (1-3). These two isoforms bind to and associate in a single transduction complex three kinases, MLK3, MKK7, and JNK, which together constitute an ordered unit of sequential signaling molecules transducing a variety of stress signals (2, 3). To date, five different isoforms of the protein have been cloned, which are mainly N-terminal splice variants that arise from expression of one single gene on human chromosome 11p11.2-p12 (1, 4, 5). A S59N mutation close to the JNK binding domain of IB1 has recently been associated with a late onset type 2 diabetes (6). Functionally, this mutation led to an increased susceptibility of JNK-mediated apoptosis in different cell systems, implying a presumably important functional role of IB1 in controlling the cell response to proapoptotic stimuli (6).Interleukin 1 (IL-1␤), which activates JNK essentially through the MKK7 pathway in several cells and tissues (7-10), is believed to play a key role in the process of selective ␤ cell destruction observed in type 1 diabetes. Chronic exposure of pancreatic islets or of ␤-derived cell lines to IL-1␤ had been shown to lead to the selective death of the ␤ cells, whereas non-␤ cells such as glucagon-producing cells appeared more resistant to the action of the cytokine (reviewed in Refs. 11-15). The molecular basis for the preferential killing of pancreatic ␤ versus ␣ cells by IL-1␤ is not fully understood. One important player in this phenomenon is the inducible nitric-oxide synthase gene iNOS, which is specifically expressed in the ␤ cells upon IL-1␤ treatment (16 -20). A number of reports have indeed clearly shown that ␤ cell apoptosis is NO-dependent (see for example two recent reports (21, 22)). In line with this, pancreatic islets from iNOS KO mice show a better resistance to IL-1␤ cytotoxicity (23).This NO-dependent killing of ␤ cells has been, however, challenged by several reports pointing to the existence of NOindependent death signaling pathways (24, 25). For example, there is no direct correlation between expression of iNOS and sensitivity to IL-1␤ between ␤ cells at different stages of differentiation (26). Importantly, the iNOS inhibitor L-NMMA does not prevent IL-1␤-induced ␤ cell death in rat or human islets (24,25). It is also possible to block NO synthesis by blocking the extracellular signal-regulated kinase and p38 MAP kinase pathways, however, without any positive effect on cell survival (17).To better understand the molecular mechanisms that specifically sensitize ␤ cells to IL-1␤-induced death, we recently used two different subclones of the pluripotent pancreatic endocrine stem cell clone (MSL). The MSL AN697C1 subclone gave rise to two derived cell lines, namely the glucagon-secreting AN-glu, and after stable transfection with the transcription factor pancreatic duodenal homeobox factor-1, the insulin secreting ANins (27). Despite having similar rates of NO synthesis, we found that the AN-ins c...

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mentioning

confidence: 49%

IB1 Reduces Cytokine-induced Apoptosis of Insulin-secreting Cells

Bonny¹,

Oberson²,

Steinmann³

et al. 2000

Journal of Biological Chemistry

120

109

View full text Add to dashboard Cite

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“…The in vivo study on mice with ␤-cell-specific deletion of PDX-1 (36) and our in vitro work on INS-1 cells expressing DN-Pdx-1 (31) indicate that PDX-1 promotes the ␤-cell phenotype by maintaining the expression of ␤-cell-specific genes while suppressing glucagon levels. Suppression of glucagon expression by PDX-1 requires synergism with other ␤-cell-specific transcription factors because ectopic expression of PDX-1 in glucagonoma cells failed to eliminate glucagon (40). We also showed that maximum induction of Brain-4, an ␣-cell-specific transcription factor, initiated detectable levels of glucagon but did not attenuate the expression of ␤-cell-specific genes in INS-1 cells (31).…”

Section: Experimental Models Of Modymentioning

confidence: 62%

Experimental Models of Transcription Factor-Associated Maturity-Onset Diabetes of the Young

Wang¹,

Hagenfeldt-Johansson²,

Otten

et al. 2002

Diabetes

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“…A similar expression profile results from dominant negative suppression of Pdx1 in INS1 beta cells [85]. In vitro binding and transient transfection studies suggest that Pdx1 interacts directly with the 5′ flanking regions of these four genes [86,87,88,89], while ChIP experiments have confirmed that Pdx1 binds in vivo to the insulin and IAPP genes in cultured beta cell lines [90,91].…”

Section: Neurogenin 3 Orchestrates a Network That Drives Endocrine DImentioning

confidence: 65%

Transcriptional networks controlling pancreatic development and beta cell function

2004

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Transcription factors provide the genetic instructions that drive pancreatic development and enable mature beta cells to function properly. To understand fully how this is accomplished, it is necessary to unravel the regulatory networks formed by transcription factors acting on their genomic targets. This article discusses recent advances in our understanding of how transcriptional networks control early pancreas organogenesis, embryonic endocrine cell formation and the differentiated function of adult beta cells. We discuss how mutations in several transcription factor genes involved in such networks cause Maturity onset diabetes of the young (MODY). Finally, we propose that pancreatic gene programs might be manipulated to generate beta cells or to enhance the function of existing beta cells, thereby providing a possible treatment of different forms of diabetes.

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Induction of insulin and islet amyloid polypeptide production in pancreatic islet glucagonoma cells by insulin promoter factor 1.

Cited by 129 publications

References 46 publications

IB1 Reduces Cytokine-induced Apoptosis of Insulin-secreting Cells

IB1 Reduces Cytokine-induced Apoptosis of Insulin-secreting Cells

Experimental Models of Transcription Factor-Associated Maturity-Onset Diabetes of the Young

Transcriptional networks controlling pancreatic development and beta cell function

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