Protein kinases, transcription factors and other apoptosis- and proliferation-related proteins can regulate reproduction, but their involvement in sexual maturation remains to be elucidated. The general aim of the in vivo and in vitro experiments with porcine ovarian granulosa cells was to identify possible intracellular regulators of female sexual maturation. For this purpose, proliferation (expression of proliferating cell nuclear antigen - PCNA, mitogen-activated protein kinases - ERK 1,2 related MAPK and cyclin B1), apoptosis (expression of the apoptotic protein Bax and apoptosis regulator Bcl-2 protein), expression of some protein kinases (cAMP dependent protein kinase - PKA, cGMPdependent protein kinase - PKG, tyrosine kinase - TK) and cAMP responsive element binding protein 1 (CREB-1) was examined in granulosa cells isolated from ovaries of immature and mature gilts. Expression of PCNA, ERK1,2 related MAPK, cyclin B1, Bcl-2, Bax, PKA, CREB-1, TK and PKG in porcine granulosa cells were detected by immunocytochemistry. Sexual maturation was associated with significant increase in the expression of Bcl-2, Bax, PKA, CREB-1 and TK and with decrease in the expression of ERK1,2 related MAPK, cyclin B1 and PKG in granulosa cells. No significant difference in PCNA expression was noted. The present data obtained from in vitro study indicate that sexual maturation in females is influenced by puberty-related changes in porcine ovarian signaling substances: increase in Bcl-2, Bax, PKA, CREB-1, TK and decrease in ERK1,2 related MAPK, cyclin B1 and PKG. It suggests that these signaling molecules could be potential regulators of porcine sexual maturation., A. Kolesarova, A. V. Sirotkin, M. Mellen, S. Roychoudhury., and Obsahuje bibliografii
Akt kinase regulates numerous cell functions including glucose metabolism, cell growth, survival, protein synthesis, and control of local hemodynamics. mTOR is one of down-stream effectors of Akt involved in the initiation of protein translation. However, renal Akt signaling in Type 1 diabetes (DM) in vivo, in particular under the conditions reflecting differences in metabolic control, has received less attention. Renal cortical activity and expression of Akt and mTOR (kinase assay, western blotting) were determined in streptozotocin-diabetic rats (D) with different levels of glycemic control (blood glucose 22.0± 1.0, 13.4±1.5, 8.1±0.4 mmol/l, p<0.05 between the groups), achieved by varying insulin treatment (0,4 and 12 IU/day), and in control rats with (C4) or without (C) chronic insulin administration. Renal Akt activity was reduced in D rats without insulin treatment and severe hyperglycemia (D-0, -62 %, p<0.01 vs. C), partially restored in moderately hypergly cemic rats (D-4, -30 %, p<0.05 vs. C), and normalized in D rats with intensive insulin and tight metabolic control (D-12). Expression of active mTOR paralleled Akt activity in D-0 (-51 %, p<0.01 vs. C), but not in D-4 and D- 12 that demonstrated increases in active mTOR (+55 %, +80 % resp., p<0.05) as compared to C. Moreover, insulin activated renal Akt (+82 %, p<0.01), but not mTOR in C4. In conclusion, glycemic control and intensity of insulin treatment are important modulators of renal Akt and mTOR activity in diabetes. While Akt activity is reversible by tight metabolic control, combination of hyperglycemia and insulin treatment resulted in enhancement of mTOR activity. In addition to Akt, other signaling pathways likely contribute to regulation of renal mTOR activity in diabetes., J. Ždychová, J. Veselá, L. Kazdová, R. Komers., and Obsahuje bibliografii a bibliografické odkazy
The purpose of this review is to analyze the involvement of protein kinases in the cardioprotective mechanism induced by chronic hypoxia. It has been reported that chronic intermittent hypoxia contributes to increased expression of the following kinases in the myocardium: PKCδ, PKCα, p-PKCε, p-PKCα, AMPK, p-AMPK, CaMKII, p-ERK1/2, p-Akt, PI3-kinase, p-p38, HK-1, and HK-2; whereas, chronic normobaric hypoxia promotes increased expression of the following kinases in the myocardium: PKCε, PKCβII, PKCη, CaMKII, p-ERK1/2, p-Akt, p-p38, HK-1, and HK-2. However, CNH does not promote enhanced expression of the AMPK and JNK kinases. Adaptation to hypoxia enhances HK-2 association with mitochondria and causes translocation of PKCδ, PKCβII, and PKCη to the mitochondria. It has been shown that PKCδ, PKCε, ERK1/2, and MEK1/2 are involved in the cardioprotective effect of chronic hypoxia. The role of other kinases in the cardioprotective effect of adaptation to hypoxia requires further research.