Movassat Jamileh, Beattie Gillian M, Lopez Ana D, Hayek Alberto
Whittier Institute and Department of Pediatrics, University of California, San Diego, La Jolla, California 92037, USA.
J Clin Endocrinol Metab. 2002 Oct;87(10):4775-81. doi: 10.1210/jc.2002-020137.
In addition to stimulating insulin secretion, glucagon-like peptide and its long-acting analog exendin 4 have been reported to increase beta-cell mass by both differentiation/neogenesis of precursor cells and enhanced replication of existing beta-cells. Here, we investigated the effect of exendin 4 in the growth and differentiation of beta-cells from undifferentiated precursors in islet-like cell clusters (ICCs) derived from human fetal pancreases. Our results show that the addition of exendin 4 to the culture media stimulates PDX 1 expression in ICCs as shown by immunofluorescence staining. The up-regulation of PDX 1 was not accompanied by changes in insulin expression because we did not find a significant difference in the number of insulin-positive cells in the exendin 4-treated ICCs, compared with controls. We also tested the effects of exendin 4 in the glucose-induced insulin secretion of human ICCs transplanted under the kidney capsule of athymic rats. In the exendin 4-treated rats (given ip during 10 d) 8 wk after the beginning of the treatment, insulin was released in response to glucose as detected by the measurement of circulating human C-peptide. In control (saline-treated) rats, the basal levels of human C-peptide did not change significantly after glucose stimulation. Thus, exendin 4 induces functional maturation of fetal beta-cells in response to glucose. In these rats, serial sections of the kidney-bearing grafts were examined histologically for insulin containing cells. We found a significant increase in beta-cell number, compared with the control rats. Overall, these results show that in vivo exendin 4 causes growth and differentiation of human fetal beta-cells from undifferentiated precursor cells. It also accelerates the functional maturation of fetal beta-cells as evidenced by their glucose-stimulated insulin secretion.
除了刺激胰岛素分泌外,胰高血糖素样肽及其长效类似物艾塞那肽-4还被报道可通过前体细胞的分化/新生以及增强现有β细胞的复制来增加β细胞量。在此,我们研究了艾塞那肽-4对源自人胎儿胰腺的胰岛样细胞簇(ICC)中未分化前体细胞生长和分化为β细胞的影响。我们的结果表明,向培养基中添加艾塞那肽-4可刺激ICC中PDX 1的表达,免疫荧光染色显示了这一点。PDX 1的上调并未伴随胰岛素表达的变化,因为与对照组相比,我们在经艾塞那肽-4处理的ICC中未发现胰岛素阳性细胞数量有显著差异。我们还测试了艾塞那肽-4对移植到无胸腺大鼠肾被膜下的人ICC葡萄糖诱导的胰岛素分泌的影响。在治疗开始8周后,对经艾塞那肽-4处理的大鼠(腹腔注射给药10天),通过检测循环中的人C肽发现,胰岛素可对葡萄糖作出反应而释放。在对照(盐水处理)大鼠中,葡萄糖刺激后,人C肽的基础水平没有显著变化。因此,艾塞那肽-4可诱导胎儿β细胞对葡萄糖作出反应而实现功能成熟。在这些大鼠中,对带有移植肾的组织切片进行组织学检查以寻找含胰岛素的细胞。与对照大鼠相比,我们发现β细胞数量显著增加。总体而言,这些结果表明,体内艾塞那肽-4可使未分化的前体细胞生长并分化为人类胎儿β细胞。它还加速了胎儿β细胞的功能成熟,葡萄糖刺激胰岛素分泌证明了这一点。