SEX DIFFERENCES IN BLOOD PRESSURE RESPONSE TO CONTINUOUS ANG II INFUSION: ARE ONLY SEX HORMONES TO BLAME?

To investigate the involvement of the sex chromosome complement (SCC), organizational and activational hormonal effects in changes in mean arterial pressure during acute Ang II infusion, we used gonadectomized (GDX) mice of the "four core genotypes" model, which dissociates the effect of gonadal sex and SCC, allowing comparisons of sexually dimorphic traits between XX and XY females as well as XX and XY males. Additionally, β-estradiol and testosterone propionate (2ug/g) were daily injected for 4 days to evaluate activational hormonal effects. Statistical analysis of the changes in mean arterial pressure revealed an interaction of SCC, organizational and activational hormonal effects during Ang II infusion {F(7,39=2,60 p<0.01)}. Our results indicate that, in absence of activational hormonal effects, interaction between the SCC and organizational hormonal action differentially modulates changes in arterial pressure. In GDX mice without hormone replacement, Ang II infusion resulted in an increase in mean arterial pressure in XX-male, XX-female and XY-female mice, while no changes were observed in XY-male mice. Furthermore, β-estradiol replacement (GDX+E2 group) resulted in a decrease in blood pressure in XX-males, XX-females and XY-females (indicating an activational β-estradiol effect), while no changes were observed in the XY-male group. Moreover, testosterone propionate replacement (GDX+TP group) showed a greater increase in blood pressure in XY-male mice than in XX-males and XX-females, demonstrating an activational hormonal effect of testosterone in XY-male mice. Our data isolates and highlights the contribution and interaction of SCC, activational and organizational hormonal effects in sex differences in Ang II blood pressure regulation.

Impact of Incretin-Based Therapies on Adipokines and Adiponectin

Adipokines are a family of hormones and cytokines with both pro- and anti-inflammatory effects released into the circulation to exert their hormonal effects. Adipokines are closely involved in most metabolic pathways and play an important modulatory role in lipid and carbohydrate homeostasis as they are involved in the pathophysiology of most metabolic disorders. Incretin-based therapy is a newly introduced class of antidiabetic drugs that restores euglycemia through several cellular processes; however, its effect on adipokines expression/secretion is not fully understood. In this review, we propose that incretin-based therapy may function through adipokine modulation that may result in pharmacologic properties beyond their direct antidiabetic effects, resulting in better management of diabetes and diabetes-related complications.

RBM20-Mediated Pre-mRNA Splicing Has Muscle-Specificity and Differential Hormonal Responses between Muscles and in Muscle Cell Cultures

Pre-mRNA splicing plays an important role in muscle function and diseases. The RNA binding motif 20 (RBM20) is a splicing factor that is predominantly expressed in muscle tissues and primarily regulates pre-mRNA splicing of Ttn, encoding a giant muscle protein titin that is responsible for muscle function and diseases. RBM20-mediated Ttn splicing has been mostly studied in heart muscle, but not in skeletal muscle. In this study, we investigated splicing specificity in different muscle types in Rbm20 knockout rats and hormonal effects on RBM20-mediated splicing both in cellulo and in vivo studies. The results revealed that RBM20 is differentially expressed across muscles and RBM20-mediated splicing is muscle-type specific. In the presence of RBM20, Ttn splicing responds to hormones in a muscle-type dependent manner, while in the absence of RBM20, Ttn splicing is not affected by hormones. In differentiated and undifferentiated C2C12 cells, RBM20-mediated splicing in response to hormonal effects is mainly through genomic signaling pathway. The knowledge gained from this study may help further understand muscle-specific gene splicing in response to hormone stimuli in different muscle types.