Transcriptome and proteome analysis of pregnancy and postpartum anoestrus ovaries in yak

Background@#Domestic yaks are the most important livestock species on the Qinghai-Tibetan Plateau. Adult female yaks normally breed in the warm season (July to September) and enter anestrous in the cold season (November to April). Nevertheless, it is unclear how ovarian activity is regulated at the molecular level. @*Objectives@#The peculiarities of yak reproduction were assessed to explore the molecular mechanism of postpartum anestrus ovaries in yaks after pregnancy and parturition. @*Methods@#Sixty female yaks with calves were observed under natural grazing in Haiyan County, Qinghai Province. Three yak ovaries in pregnancy and postpartum anestrus were collected. RNA sequencing and quantitative proteomics were employed to analyze the pregnancy and postpartum ovaries after hypothermia to identify the genes and proteins related to the postpartum ovarian cycle. @*Results@#The results revealed 841 differentially expressed genes during the postpartum hypoestrus cycle; 347 were up-regulated and 494 genes were down-regulated. Fifty-seven differential proteins were screened: 38 were up-regulated and 19 were down-regulated. The differential genes and proteins were related to the yak reproduction process, rhythm process, progesterone-mediated oocyte maturation, PI3K/AKT signaling pathway, and MAPK signaling pathway categories. @*Conclusions@#Transcriptome and proteomic sequencing approaches were used to investigate postpartum anestrus and pregnancy ovaries in yaks. The results confirmed that BHLHE40, SF1IX1, FBPX1, HSPCA, LHCGR, BMP15, and ET-1R could affect postpartum hypoestrus and control the state of estrus.

FSH receptor binding inhibitor influences estrogen production, receptor expression and signal pathway during in vitro maturation of sheep COCs.

Follicle-stimulating hormone (FSH) promotes secretion of follicle fluid and follicle development. FSH acts via cognate FSH receptor (FSHR). It remains unknown whether the supplement of FSH-receptor binding inhibitor (FRBI) into the in vitro maturation (IVM)medium influence the estrogen receptor expression and signal pathway of oocytes in sheep. The present study aimed to investigate FRBI effects on inositol trisphosphate (IP3) of oocytes and protein kinase A (PKA) of sheep granulosa cells, further to elucidate the signal pathway of FRBI effects. Cumulus-oocyte complexes (COCs) were recovered from antral follicles. COCs were cultured for 24 h in the IVM medium supplemented with varying concentrations of FRBI (0, 10, 20, 30 and 40 µg/mL) and FSH (10IU/mL). ELISA was used to measure the concentrations of estradiol (E2) and IP3 in the IVM medium. Western blotting was utilized to detect protein expression of ERß of COCs and protein kinase A (PKA) of granulosa cells. The results showed IP3 concentrations of FRBI-3 and FRBI-4 groups were less than that of CG and FSH groups at 22 h and 24 h (P < 0.05). PKA levels of FRBI-3 and FRBI-4 groups were significantly less than that of CG and FSH group (P < 0.05 or P < 0.01). Expression levels of ERß mRNA and protein of FRBI-treated groups were gradually decreased in comparison to CG and FSH group. The minimum value was detected in the FRBI-4 group. ERß protein level of the FRBI-4 group was significantly less than that of FSH group (P < 0.05). E2 concentrations of FRBI-treated groups were elevated as compared to CG, with the highest increment of FRBI-2 group (P < 0.05). Our results revealed a higher dose of FRBI reduced IP3 production. FRBI could suppress slightly expression levels of ERß mRNA and protein of COCs and PKA of granulosa cells, additionally increased E2 production of sheep COCs.

Glucose and Insulin Stimulate Lipogenesis in Porcine Adipocytes: Dissimilar and Identical Regulation Pathway for Key Transcription Factors.

Lipogenesis is under the concerted action of ChREBP, SREBP-1c and other transcription factors in response to glucose and insulin. The isolated porcine preadipocytes were differentiated into mature adipocytes to investigate the roles and interrelation of these transcription factors in the context of glucose- and insulin-induced lipogenesis in pigs. In ChREBP-silenced adipocytes, glucose-induced lipogenesis decreased by ~70%, however insulin-induced lipogenesis was unaffected. Moreover, insulin had no effect on ChREBP expression of unperturbed adipocytes irrespective of glucose concentration, suggesting ChREBP mediate glucose-induced lipogenesis. Insulin stimulated SREBP-1c expression and when SREBP-1c activation was blocked, and the insulin-induced lipogenesis decreased by ~55%, suggesting SREBP-1c is a key transcription factor mediating insulin-induced lipogenesis. LXRα activation promoted lipogenesis and lipogenic genes expression. In ChREBP-silenced or SREBP-1c activation blocked adipocytes, LXRα activation facilitated lipogenesis and SREBP-1c expression, but had no effect on ChREBP expression. Therefore, LXRα might mediate lipogenesis via SREBP-1c rather than ChREBP. When ChREBP expression was silenced and SREBP-1c activation blocked simultaneously, glucose and insulin were still able to stimulated lipogenesis and lipogenic genes expression, and LXRα activation enhanced these effects, suggesting LXRα mediated directly glucose- and insulin-induced lipogenesis. In summary, glucose and insulin stimulated lipogenesis through both dissimilar and identical regulation pathway in porcine adipocytes.