Porcine growth hormone induces the nuclear localization of porcine growth hormone receptor in vivo

The effect of heat stress on the epidermal growth factor (EGF)-mediated intracellular signaling, and changes cell behavior on swine testicular cell

At present, high environmental temperature is the main factor endangering animal production, growth and development. Therefore, the harmful effects of heat stress led by hot environment on livestock have attracted much attention. In this work, the cellar property and signaling property of epidermal growth factor (EGF) below heat stress remains unclear in swine testicular cells. Here, the effect of heat stress on EGF-induced intracellular signaling and cell behavior was explored in the ST (a porcine testis cell line). A series of experiments were done to study the cellular behavior and signaling properties of EGF under heat stress. It can be discovered which high ambient temperature changed the cellular characteristics of EGF/EGFR. The eventuates displayed when cells were exposed to thermal environment, EGF/EGFR basically did not internalize, mainly gathered on the cell membrane. Our group also researched the effect of EGF's signaling properties, and the results showed that the ability of EGF to activate EGFR-mediated intracellular signaling decreased significantly under heat stress. Finally, this study illustrated that EGF's cell behavior and signaling profile are obviously altered, indicating that heat stress seriously affected the biological activity of EGF/EGFR, which establish a solid foundation for studying the effect of the EGF on testicular tissue under heat environment.

The growth hormone receptor interacts with transcriptional regulator HMGN1 upon GH-induced nuclear translocation

Growth hormone (GH) actions are mediated through binding to its cell-surface receptor, the GH receptor (GHR), with consequent activation of downstream signalling. However, nuclear GHR localisation has also been observed and is associated with increased cancer cell proliferation. Here we investigated the functional implications of nuclear translocation of the GHR in the human endometrial cancer cell-line, RL95-2, and human mammary epithelial cell-line, MCF-10A. We found that following GH treatment, the GHR rapidly translocates to the nucleus, with maximal localisation at 5-10 min. Combined immunoprecipitation-mass spectrometry analysis of RL95-2 whole cell lysates identified 40 novel GHR binding partners, including the transcriptional regulator, HMGN1. Moreover, microarray analysis demonstrated that the gene targets of HMGN1 were differentially expressed following GH treatment, and co-immunoprecipitation showed that HMGN1 associates with the GHR in the nucleus. Therefore, our results suggest that GHR nuclear translocation might mediate GH actions via interaction with chromatin factors that then drive changes in specific downstream transcriptional programs.

The effect of heat stress on the cellular behavior, intracellular signaling profile of porcine growth hormone (pGH) in swine testicular cells

At present, heat stress caused by the thermal environment is the main factor that endangers the reproductive function of animals. Growth hormone (GH) is a polypeptide hormone, the biological function of reproductive organs has been reported, and it has many important physiological functions in the body. However, so far, the behavior and signal transduction of GH in testicular cells under heat stress are still unclear. To this end, in the current work, we use a swine testicular cell line (ST) as an in vitro model to explore the cell behavior and intracellular signaling profile of porcine growth hormone (pGH) under heat stress; the results showed that when cells were under heat stress, pGH and GHR were basically not internalized, and a large number of them accumulated on the cell membrane. In addition, we also studied the effect of pGH on the JAK2-STATs signaling pathway and IGF-1 expression under heat stress, we found that the ability of pGH to activate the JAK-STATs signaling pathway and IGF-1 under heat stress was greatly reduced (p < 0.05). In conclusion, our research shows that when cells undergo heat stress, the internalization of pGH and GHR were inhibited, and the activation of the JAK2-STATs signaling pathway and IGF-1 expression were reduced; this lays a solid foundation for further research on the effect of pGH on swine testicular tissue under thermal environment.

The Cellular Behavior, Intracellular Signaling Profile and Nuclear-Targeted Potential Functions of Porcine Growth Hormone (pGH) in Swine Testicular Cells

Porcine growth hormone (pGH) has many important biological functions and roles, and the biological activity of pGH is closely related with its cell behavior and characteristics. However, so far, the behavior of pGH in swine testicular cell remains unclear. For this, in the current work, the swine testicular cell line (ST) was used as an in vitro model, and CLSM (Confocal laser scanning microscope), IFA (Indirect immunofluorescence assay), FCM (Flow cytometry) and WB (Western-blotting) were used to explore the pGH's cell behivior and function, and the results showed that pGH and GHR could internalize into ST cell and transported to the nucleus. Furthermore, we studied the internalization kinetics of pGH and GHR on ST cell, and found that pGH and GHR internalizes into ST cell in a time-dependent manner. More importantly, we also investigated the potential molecular functions of pGH-GHR after it entered into the cell nuclei. The results indicated that nuclear-localized GHR could participate in cell proliferation by regulating the signal intensity of STAT5. In summary, our current research shows that the nuclear-localized pGH-GHR participates in the cell proliferation of ST cell, which lays a solid foundation for further research on the regulatory effect of pGH on testicular tissue.

Transcriptome profiling of different developmental stages of corpus luteum during the estrous cycle in pigs

To better understand the molecular basis of corpus luteum (CL) development and function RNA-Seq was utilized to identify differentially expressed genes (DEGs) in porcine CL during different physiological stages of the estrous cycle viz. early (EL), mid (ML), late (LL) and regressed (R) luteal. Stage wise comparisons obtained 717 (EL vs. ML), 568 (EL vs. LL), 527 (EL vs. R), 786 (ML vs. LL), 474 (ML vs. R) and 534 (LL vs. R) DEGs with log₂(FC) ≥1 and p < 0.05. The process of angiogenesis, steroidogenesis, signal transduction, translation, cell proliferation and tissue remodelling were significantly (p < 0.05) enriched in EL, ML and LL stages, where as apoptosis was most active in regressed stage. Pathway analysis revealed that most annotated genes were associated with lipid metabolism, translation, immune and endocrine system pathways depicting intra-luteal control of diverse CL function. The network analysis identified genes AR, FOS, CDKN1A, which were likely the novel hub genes regulating CL physiology.

The Role of Growth Hormone on Ovarian Functioning and Ovarian Angiogenesis

Although not yet well-understood, today it is clear that Growth Hormone (GH) exerts a relevant role in the regulation of ovulation and fertility; in fact, fertility is lower in women with GH deficiency (GHD), and GH receptors (GHR) and GH mRNA have been found in the ovary since the onset of follicular development in humans. However, despite the strong evidence of GH in the regulation of fertility, many aspects of GH actions at this level are still not well-established, and it is likely that some controversial data depend on the species analyzed, the dose of the hormone and the duration of use of GH. Folliculogenesis, ovulation, and corpus luteum formation and maintenance are processes that are critically dependent on angiogenesis. In the ovary, new blood vessel formation facilitates oxygen, nutrients, and hormone substrate delivery, and also secures transfer of different hormones to targeted cells. Some growth factors and hormones overlap their actions in order to control the angiogenic process for fertility. However, we still know very little about the factors that play a critical role in the vascular changes that occur during folliculogenesis or luteal regression. To promote and maintain the production of VEGF-A in granulosa cells, the effects of local factors such as IGF-I and steroids are needed; that VEGF-A-inducing effect cannot be induced by luteinizing hormone (LH) or chorionic gonadotropin (CG) alone. As a result of the influences that GH exerts on the hypothalamic-pituitary-gonadal axis, facilitating the release of gonadotropins, and given the relationship between GH and local ovarian factors such as VEGF-A, FGF-2, IGF-1, or production of sex steroids, we assume that GH has to be a necessary factor in ovarian angiogenesis, as it happens in other vascular beds. In this review we will discuss the actions of GH in the ovary, most of them likely due to the local production of the hormone and its mediators.