Jara Adam, Liu Xingbo, Sim Don, Benner Chance M, Duran-Ortiz Silvana, Qian Yanrong, List Edward O, Berryman Darlene E, Kim Jason K, Kopchick John J
Edison Biotechnology Institute (A.J., X.L., D.S., C.M.B., S.D.-O., Y.Q., E.O.L., D.E.B., J.J.K.), Departments of Biomedical Sciences (A.J., D.E.B., J.J.K.) and Specialty Medicine (E.O.L.), Heritage College of Osteopathic Medicine, Department of Biological Sciences (S.D.-O., J.J.K.), School of Applied Health Sciences and Wellness (X.L., C.M.B., D.E.B.), College of Health Sciences and Professions, Department of Social and Public Health (D.S.), Ohio University, Athens, Ohio 45701; and Program in Molecular Medicine (J.K.K.), University of Massachusetts Medical School, Worcester, Massachusetts 01605.
Endocrinology. 2016 May;157(5):1929-41. doi: 10.1210/en.2015-1686. Epub 2016 Apr 1.
GH is considered necessary for the proper development and maintenance of several tissues, including the heart. Studies conducted in both GH receptor null and bovine GH transgenic mice have demonstrated specific cardiac structural and functional changes. In each of these mouse lines, however, GH-induced signaling is altered systemically, being decreased in GH receptor null mice and increased in bovine GH transgenic mice. Therefore, to clarify the direct effects GH has on cardiac tissue, we developed a tamoxifen-inducible, cardiac-specific GHR disrupted (iC-GHRKO) mouse line. Cardiac GH receptor was disrupted in 4-month-old iC-GHRKO mice to avoid developmental effects due to perinatal GHR gene disruption. Surprisingly, iC-GHRKO mice showed no difference vs controls in baseline or postdobutamine stress test echocardiography measurements, nor did iC-GHRKO mice show differences in longitudinal systolic blood pressure measurements. Interestingly, iC-GHRKO mice had decreased fat mass and improved insulin sensitivity at 6.5 months of age. By 12.5 months of age, however, iC-GHRKO mice no longer had significant decreases in fat mass and had developed glucose intolerance and insulin resistance. Furthermore, investigation via immunoblot analysis demonstrated that iC-GHRKO mice had appreciably decreased insulin stimulated Akt phosphorylation, specifically in heart and liver, but not in epididymal white adipose tissue. These changes were accompanied by a decrease in circulating IGF-1 levels in 12.5-month-old iC-GHRKO mice. These data indicate that whereas the disruption of cardiomyocyte GH-induced signaling in adult mice does not affect cardiac function, it does play a role in systemic glucose homeostasis, in part through modulation of circulating IGF-1.
生长激素(GH)被认为是包括心脏在内的多种组织正常发育和维持所必需的。在生长激素受体缺失小鼠和牛生长激素转基因小鼠中进行的研究已经证明了特定的心脏结构和功能变化。然而,在每一种小鼠品系中,生长激素诱导的信号传导在全身都发生了改变,在生长激素受体缺失小鼠中降低,而在牛生长激素转基因小鼠中增加。因此,为了阐明生长激素对心脏组织的直接作用,我们构建了一种他莫昔芬诱导的、心脏特异性生长激素受体破坏(iC-GHRKO)小鼠品系。在4个月大的iC-GHRKO小鼠中破坏心脏生长激素受体,以避免围产期生长激素受体基因破坏带来的发育影响。令人惊讶的是,iC-GHRKO小鼠在基线或多巴酚丁胺负荷试验超声心动图测量中与对照组没有差异,在纵向收缩压测量中也没有差异。有趣的是,6.5月龄的iC-GHRKO小鼠脂肪量减少,胰岛素敏感性提高。然而,到12.5月龄时,iC-GHRKO小鼠的脂肪量不再显著减少,并且出现了葡萄糖不耐受和胰岛素抵抗。此外,通过免疫印迹分析研究表明,iC-GHRKO小鼠胰岛素刺激的Akt磷酸化明显降低,特别是在心脏和肝脏中,但在附睾白色脂肪组织中没有降低。这些变化伴随着12.5月龄iC-GHRKO小鼠循环中胰岛素样生长因子-1(IGF-1)水平的降低。这些数据表明,虽然成年小鼠心肌细胞生长激素诱导的信号传导破坏不影响心脏功能,但它确实在全身葡萄糖稳态中起作用,部分是通过调节循环中的IGF-1来实现的。
