ABSTRACT
Tunica dartos smooth muscle (TDSM) lies beneath the scrotal skin, and its contraction leads to scrotum wrinkling upon cooling. However, neither the nature of TDSM cold-sensitivity nor the underlying molecular sensors are well understood. Here we have investigated the role of cold/menthol-sensitive TRPM8 channel in TDSM temperature-dependent contractility. The contraction of isolated male rat TDSM strips was studied by tensiometry. TRPM8 expression was assayed by RT-PCR and fluorescence immunochemistry. Isolated TDSM strips responded to cooling from 33 °C to 20 °C by enhancement of basal tension, and increase of the amplitude and duration of electric field stimulated (EFS) contractions. The effects of cold on basal tension, but not on EFS-contractions, could be 80% inhibited by TRPM8 blockers, capsazepine and BCTC [N-(4tert-butylphenyl)-4-(3-chloropyridin-2-yl)piperazine-1-carboxamide], and could be partially mimicked by menthol. RT-PCR and immunolabeling showed TRPM8 mRNA and protein expression in TDSM cells with protein labelling being predominantly localized to intracellular compartments. Chemical castration of male rats consequent to the treatment with androgen receptor blocker, flutamide, led to the abrogation of cold effects on TDSM basal tension, but not on EFS-contractions, and to the disappearance of TRPM8 protein expression. We conclude that TRPM8 is involved in the maintenance of basal cold-induced TDSM tonus, but not in sympathetic nerve-mediated contractility, by acting as endoplasmic reticulum Ca2+ release channel whose expression in TDSM cells requires the presence of a functional androgen receptor. Thus, TRPM8 plays a crucial role in scrotal thermoregulation which is important for maintaining normal spermatogenesis and male fertility.
ABSTRACT
AIMS: The urinary bladder is a mechanosensitive organ that accumulates, stores, and expels considerable amounts of fluid. While the neuronal bladder control via the CNS is well defined, the data on the mechanisms of local mechanical sensitivity of the bladder wall are either insufficient or contradictory. Here we compared the mechanical properties of bladder wall of normal rats and rats with modeled type 2 diabetes (T2D). METHODS: T2D was modeled in 3-month-old Wistar male rats by combined administration of nicotinamide (230 mg/kg) and streptozotocin (65 mg/kg). Cystometry of isolated, denervated whole bladders and stress-strain tensiometry on detrusor smooth muscle (DSM) strips were used to assess the mechanical properties of bladder wall tissues from control and diabetic animals on 10th week after induction. RESULTS: The pressure-volume cystometrograms of both control and T2D bladders featured a quasi plateau between ascending sections. T2D cystometrograms revealed markedly elevated intravesicular pressure (~100% at 1 ml) and a shortened plateau, consistent with decreased bladder wall elasticity and reduced structural bladder capacity versus control. Experiments on urothelium-intact and urothelium-devoid DSM strips have shown that the decrease of bladder walls elasticity in T2D can be explained by the switch of stretched urothelium from inducing DSM relaxation to inducing DSM contraction due to a change in the prevalent release of contractile versus relaxing urothelial factor(s). CONCLUSIONS: The decreased elasticity of the bladder walls in T2D results from alterations in urothelium-dependent mechanosensory mechanisms. Elevated intravesical pressure in T2D may contribute to urge incontinence and/or symptoms of upper urinary tract damage.
