Increased protein kinase C (PKC) activity in malignant breast tissue and positive correlations between PKC activity and expression of a more aggressive phenotype in breast cancer cell lines suggest a role for this signal transduction pathway in the pathogenesis and/or progression of breast cancer. To examine the role of PKC in the progression of breast cancer, human MCF-7 breast cancer cells were transfected with PKC-a, and a group of heterogenous cells stably overexpressing PKC-a were isolated (MCF-7-PKCa). MCF-7-PKC-a cells expressed fivefold higher levels of PKC-a as compared to parental or vector-transfected MCF-7 cells. MCF-7-PKC-a cells also displayed a substantial increase in endogenous expression of PKC-8 and decreases in expression of the novel 6-and q-PKC isoforms.MCF-7-PKC-a cells displayed an enhanced proliferative rate, anchorage-independent growth, dramatic morphologic alterations including loss of an epithelioid appearance, and increased tumorigenicity in nude mice. MCF-7-PKCa cells exhibited a significant reduction in estrogen receptor expression and decreases in estrogen-dependent gene expression. These findings suggest that the PKC pathway may modulate progression of breast cancer to a more aggressive neoplastic process. (J. Clin. Invest. 1995. 95:1906-1915
Pregnancy coordinately alters the contractile properties of both vascular and uterine smooth muscles reducing systemic blood pressure and maintaining uterine relaxation. The precise molecular mechanisms underlying these pregnancy-induced adaptations have yet to be fully defined but are likely to involve changes in the expression of proteins regulating myosin phosphorylation. Here we show that smoothelin like protein 1 (SMTNL1) is a key factor governing sexual development and pregnancy induced adaptations in smooth and striated muscle. A primary target gene of SMTNL1 in these muscles is myosin phosphatase-targeting subunit 1 (MYPT1). Deletion of SMTNL1 increases expression of MYPT1 30 -40-fold in neonates and during development expression of both SMTNL1 and MYPT1 increases over 20-fold. Pregnancy also regulates SMTNL1 and MYPT1 expression, and deletion SMTNL1 greatly exaggerates expression of MYPT1 in vascular smooth muscle, producing a profound reduction in force development in response to phenylephrine as well as sensitizing the muscle to acetylcholine. We also show that MYPT1 is expressed in Type2a muscle fibers in mice and humans and its expression is regulated during pregnancy, suggesting unrecognized roles in mediating skeletal muscle plasticity in both species. Our findings define a new conserved pathway in which sexual development and pregnancy mediate smooth and striated muscle adaptations through SMTNL1 and MYPT1.
Class A2 and B gestational diabetes are associated with suppressed levels of adiponectin, similar to that found in other insulin-resistant states (type II diabetes and obesity).
Background: Pregnancy promotes physiological adaptations throughout the body mediated by the female sex hormones. Results: Pregnancy promotes switching of skeletal muscle to a glycolytic phenotype through the smoothelin-like protein 1 transcriptional cofactor. Conclusion: Deletion of SMTNL1 is able to mimic the effect of pregnancy in mice. Significance: Novel mechanism to explain insulin resistance during pregnancy.
Previous studies have shown that T3 coordinately stimulates GLUT4-glucose transporter messenger RNA (mRNA) and protein expression in mixed fiber-type skeletal muscle of the rat and produces a concomitant elevation in basal (noninsulin mediated) glucose uptake. The aim of the present study was to 1) determine the precise mechanism(s) for the T3-induced expression of GLUT4 in skeletal muscle, and 2) investigate the potential benefits of T3 on noninsulin dependent diabetes mellitus (NIDDM). Ten daily ip injections of T3 (100 micrograms/100 g BW) administered to hypothyroid male Sprague-Dawley rats, increased both GLUT4 mRNA and transcription approximately 70% (P < 0.05) in mixed fiber-type hindlimb skeletal muscle. Transcriptional induction was subsequently defined to be restricted to red (oxidative) muscle fibers (2.5-fold; P < 0.05), whereas GLUT4 protein was increased in both red and white (glycolytic) skeletal muscle. GLUT4 mRNA and protein expression were similarly inducible in the skeletal muscle of insulin-resistant Zucker rats. More importantly, T3 treatment totally ameliorated hyperinsulinemia in obese animals (P < 0.001), although their moderately elevated plasma glucose levels were not significantly altered. In conclusion, regulation of GLUT4 expression by T3 was shown to lie at the transcriptional level in red skeletal muscle, whereas in white muscle fiber types, it appears to operate via an alternative posttranscriptional mechanism. These data also support the potential of hormonally inducing glucose transporter expression in insulin-resistant muscle. However, high levels of T3 are associated with a number of adverse side-effects, in particular the stimulation of hepatic gluconeogenesis. Nevertheless, future studies may demonstrate, e.g. subthyrotoxic levels, to be similarly effective but without side effects, and thus perhaps find a clinical application in reducing both hyperinsulinemia and hyperglycemia in NIDDM.
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