The insulin receptor and the insulin-like growth factor-1 receptor are widely expressed tyrosine kinases that mediate insulin and insulin-like growth factor-1 signaling. Both receptors are expressed in many cells in which insulin stimulation does not result in an increase in glucose transport, and the distinct role of the insulin receptor in these tissues, is not known. We have studied the regulation of insulin receptor and insulin-like growth factor-1 receptor in the differentiation of cultured murine keratinocytes. Both receptors are expressed in skin keratinocytes and their expression was unchanged in all stages of calcium-induced differentiation. Insulin binding to skin keratinocytes, however, increased during calcium-induced differentiation, whereas insulin-like growth factor-1 binding decreased. Ligand-induced autophosphorylation was also changed during differentiation. In proliferating keratinocytes both receptors became phosphorylated upon ligand binding, insulin-like growth factor-1 receptor to a greater extent. Terminal differentiation resulted in a decrease in insulin receptor autophosphorylation, whereas insulin-like growth factor-1 receptor autophosphorylation was abolished. There was no change in the cellular localization of the proteins, their intrinsic activity, or their internal structure. Finally, due to the change in the receptor's activity during keratinocyte differentiation, the role of insulin and insulin-like growth factor-1 in the differentiation process was examined. The expected increase in the expression of keratins 1 and 10 during calcium-induced differentiation was facilitated in the presence of insulin, whereas this induction was inhibited in the presence of insulin-like growth factor-1. In conclusion, these results demonstrate that insulin and insulin-like growth factor-1 signaling pathways are differentially involved in skin differentiation, suggesting that abnormal insulin signaling, as occurs in diabetes, may lead to skin pathology.
Ferrocene, a stable, synthetic, iron-containing compound induces in vitro and in vivo activation of mouse lymphocytes and macrophages. Ferrocene also has a marked antitumor effect in mice, upon its administration intraperitoneally and in drinking water. Ferrocene's antitumor activity is attributed to its immune-stimulatory property. This conclusion is supported by adoptive transfer experiments demonstrating that immune cells from ferrocene-treated tumor-bearing mice elicit an antitumor effect in mice not treated with ferrocene. We postulate that the immune stimulatory effect of ferrocene is mediated by redox-sensitive signaling such as activation of p21ras. This postulation is supported by the following findings: Ferrocene generates H2O2 by autooxidation; N-acetylcysteine, a free-radical scavenger, reduces its antitumor effect; and it stimulates GTPase activity catalyzed by pure recombinant p21ras and activates ERK 1/2 in wild Jurkat T cells but fails to do so in the Jurkat T cells expressing p21ras in which cysteine 118 was replaced by serine. Lastly, ferrocene activates and translocates NF-kappaB in human PBM, a pathway which is mediated by ras. It is most plausible that additional redox-sensitive signaling proteins mediate the biological effects of ferrocene.
Secretory granule formation in pancreatic acinar cells is known to involve massive membrane flow. In previous studies we have undertaken morphometry of the regranulation mechanism in these cells and in mast cells as a model for cellular membrane movement. In our current work, electron micrographs of pancreatic acinar cells from ICR mice were taken at several time points after extensive degranulation induced by pilocarpine injection in order to investigate the volume changes of rough endoplasmic reticulum (RER), nucleus, mitochondria and autophagosomes. At 2-4 h after stimulation, when the pancreatic cells demonstrated a complete loss of granules, this was accompanied by an increased proportion of autophagosomal activity. This change primarily reflected a greatly increased proportion of profiles retaining autophagic vacuoles containing recognisable cytoplasmic structures such as mitochondria, granule profiles and fragments of RER. The mitochondrial structures reached a significant maximal size 4 h following injection (before degranulation 0.178p0.028 µm$ ; at 4 h peak value, 0.535p0.109 µm$). Nucleus size showed an early volume increase approaching a maximum value 2 h following degranulation. The regranulation span was thus divided into 3 stages. The first was the membrane remodelling stage (0-2 h). During this period the volume of the RER and secretory granules was greatly decreased. At the intermediate stage (2-4 h) a significant increase of the synthesis zone was observed within the nucleus. The volume of the mitochondria was increasing. At the last step, the major finding was a significant granule accumulation in parallel with an active Golgi zone.
NCTR-Balb/c mice are afflicted with a cholesterol lysosomal storage disorder stemming from a defect in intracellular cholesterol processing. The clinical and biochemical abnormalities expressed in the mice resemble Niemann-Pick type C and D disorders in humans. One of the proposed mechanisms to explain the pathophysiology of the disorder implies a defect in the process of membrane transport that normally takes place in the vesicular movement of cholesterol to specific target sites in the cell. Secretory granule formation in pancreatic acinar cells is one of the biological processes known to involve massive membrane flow. Thus, we have undertaken a morphometric study of the regranulation mechanism in the pancreatic acinar cells of the mutant mice, as a way of studying cellular membrane movement. Electron micrographs of pancreatic acinar cells from mutant and normal mice were taken at several time points after extensive degranulation induced by pilocarpine injection. Two hours after stimulation the pancreatic cells demonstrated a complete loss of granules, and at later time points newly formed granules appeared. Identical unit granule volumes were observed in both groups, indicating that the progranules were of normal size. However, the rate of granule formation and maturation was reduced in the mutant mice, which might be the result of a defect in membrane function.
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