The role of tumour suppressor PDCD4 in beta cell death in hypoxia.

Objective: Hypoxia is known to induce pancreatic beta cell dysfunction and apoptosis. Changes in Programmed Cell Death Gene 4 (PDCD4) expression have previously been linked with beta cell neogenesis and function. Our aim was to investigate the effects of hypoxia on cell viability, PDCD4 expression and subcellular localisation.

Pseudoislets as primary islet replacements for research: report on a symposium at King's College London, London UK.

Laboratory-based research aimed at understanding processes regulating insulin secretion and mechanisms underlying β-cell dysfunction and loss in diabetes often makes use of rodents, as these processes are in many respects similar between rats/mice and humans. Indeed, a rough calculation suggests that islets have been isolated from as many as 150,000 rodents to generate the data contained within papers published in 2009 and the first four months of 2010. Rodent use for islet isolation has been mitigated, to a certain extent, by the availability of a variety of insulin-secreting cell lines that are used by researchers world-wide.

Tumor suppressor Pdcd4 is a major transcript that is upregulated during in vivo pancreatic islet neogenesis and is expressed in both beta-cell and ductal cell lines.

Objectives: We wished to identify a major transcript that is upregulated during in vivo pancreatic islet neogenesis and examine the expression of the gene in beta and ductal cells.

Methods: Differential display polymerase chain reaction was used to identify upregulated transcripts after islet neogenesis was stimulated in the rat by brief occlusion of the main pancreatic duct. The expression of this major transcript, namely PDCD4 (programmed cell death gene 4), was measured in beta and ductal cells after stimulation with the incretin hormone glucagon-like peptide 1, mitogenic insulin, the thiazolidinedione rosiglitazone, and by high glucose concentrations.

Selenium stimulates pancreatic beta-cell gene expression and enhances islet function.

The present study investigated the role of selenium in the regulation of pancreatic beta-cell function. Utilising the mouse beta-cell line Min6, we have shown that selenium specifically upregulates Ipf1 (insulin promoter factor 1) gene expression, activating the -2715 to -1960 section of the Ipf1 gene promoter. Selenium increased both Ipf1 and insulin mRNA levels in Min6 cells and stimulated increases in insulin content and insulin secretion in isolated primary rat islets of Langerhans.