MicroRNA-124a regulates Foxa2 expression and intracellular signaling in pancreatic beta-cell lines.

MicroRNAs (miRNAs) are short non-coding RNAs that have been implicated in fine-tuning gene regulation, although the precise roles of many are still unknown. Pancreatic development is characterized by the complex sequential expression of a gamut of transcription factors. We have performed miRNA expression profiling at two key stages of mouse embryonic pancreas development, e14.5 and e18.5. miR-124a2 expression was strikingly increased at e18.5 compared with e14.5, suggesting a possible role in differentiated beta-cells. Among the potential miR-124a gene targets identified by biocomputation, Foxa2 is known to play a role in beta-cell differentiation. To evaluate the impact of miR-124a2 on gene expression, we overexpressed or down-regulated miR-124a2 in MIN6 beta-cells. As predicted, miR-124a2 regulated Foxa2 gene expression, and that of its downstream target, pancreatic duodenum homeobox-1 (Pdx-1). Foxa2 has been described as a master regulator of pancreatic development and also of genes involved in glucose metabolism and insulin secretion, including the ATP-sensitive K(+) (K(ATP)) channel subunits, Kir6.2 and Sur-1. Correspondingly, miR-124a2 overexpression decreased, and anti-miR-124a2 increased Kir6.2 and Sur-1 mRNA levels. Moreover, miR-124a2 modified basal and glucose- or KCl-stimulated intracellular free Ca(2+) concentrations in single MIN6 and INS-1 (832/13) beta-cells, without affecting the secretion of insulin or co-transfected human growth hormone, consistent with an altered sensitivity of the beta-cell exocytotic machinery to Ca(2+). In conclusion, whereas the precise role of microRNA-124a2 in pancreatic development remains to be deciphered, we identify it as a regulator of a key transcriptional protein network in beta-cells responsible for modulating intracellular signaling.

The mesenchyme controls the timing of pancreatic beta-cell differentiation.

The importance of mesenchymal-epithelial interactions in the proliferation of pancreatic progenitor cells is well established. Here, we provide evidence that the mesenchyme also controls the timing of beta-cell differentiation. When rat embryonic pancreatic epithelium was cultured without mesenchyme, we found first rapid induction in epithelial progenitor cells of the transcription factor neurogenin3 (Ngn3), a master gene controlling endocrine cell-fate decisions in progenitor cells; then beta-cell differentiation occurred. In the presence of mesenchyme, Ngn3 induction was delayed, and few beta-cells developed. This effect of the mesenchyme on Ngn3 induction was mediated by cell-cell contacts and required a functional Notch pathway. We then showed that associating Ngn3-expressing epithelial cells with mesenchyme resulted in poor beta-cell development via a mechanism mediated by soluble factors. Thus, in addition to its effect upstream of Ngn3, the mesenchyme regulated beta-cell differentiation downstream of Ngn3. In conclusion, these data indicate that the mesenchyme controls the timing of beta-cell differentiation both upstream and downstream of Ngn3.

Mutant ras-induced proliferation of human thyroid epithelial cells requires three effector pathways.

Ras mutations occur as an early event in many human tumours of epithelial origin, including thyroid. Using primary human thyroid epithelial cells to model tumour initiation by Ras, we have shown previously that activation of both the MAP kinase (MAPK) and phosphatidylinositol 3-kinase (PI3K) effector pathways are necessary, but even when activated together are not sufficient, for Ras-induced proliferation. Here, we show that a third effector, RalGEF, is also activated by Ras in these cells, that this activation is necessary for Ras-induced proliferation, and furthermore that in combination with the MAPK and PI3K effectors, it is able to reproduce the proliferative effect of activated Ras. The requirement for three effector pathways indicates a more robust control of cell proliferation in this normal human epithelial cell type than has been displayed in previous similar studies using rodent and human cell lines. Our findings highlight the importance of the appropriate cellular context in models of Ras-induced tumour development.

Opposing effects of mutant ras oncoprotein on human fibroblast and epithelial cell proliferation: implications for models of human tumorigenesis.

Using microinjection of recombinant protein to directly control 'expression' levels, we have compared the proliferative response to ras oncogene activation in two normal cell types--fibroblast and thyroid epithelial cell--which give rise to human tumours with very low and high frequencies of ras mutation respectively. A concentration-dependent stimulation of DNA synthesis was observed in thyrocytes, matched by an almost perfectly reciprocal inhibition in fibroblasts. A concentration-dependent induction of the cyclin-dependent kinase (CDK) inhibitor p21WAF1 was observed in both cell types, but p16Ink4a was induced by ras only in fibroblasts. This difference could not account for the fibroblast specificity of the growth-inhibitory response, however, since proliferation of p16-deficient fibroblasts was also inhibited by mutant ras. We conclude that the striking contrast in proliferative response to ras between fibroblasts and thyroid epithelial cells cannot readily be explained by differential induction of either of the two key CDK inhibitors, p16Ink4a and p21WAF1, but is consistent with a differential ability of p21WAF1 to antagonize ras-induced mitogenic signals in the two cell types. Such tissue-specific differences provide an attractive explanation for the observed specificity of ras mutation for particular human tumour types, and emphasize the inappropriateness of fibroblasts as a model for ras-induced tumorigenesis.