Effects of denervation and reserpine on nexuses in the rat vas deferens

Mechanisms of adaptive supersensitivity in vas deferens

Adaptive supersensitivity is a phenomenon characteristic of excitable tissues and discloses as a compensatory adjustment of tissue's response to unrelated stimulatory endogenous and exogenous substances after chronic interruption of excitatory neurotransmission. The mechanisms underlying such higher postjunctional sensitivity have been postulated for a variety of cell types. In smooth muscles, especially the vas deferens with its rich sympathetic innervation, the mechanisms responsible for supersensitivity are partly understood and appear to be different from one species to another. The present review provides a general understanding of adaptive supersensitivity and emphasizes early and recent information about the putative mechanisms involved in this phenomenon in rodent vas deferens.

Independence of connexin expression and vasomotor conduction from sympathetic innervation in hamster feed arteries

OBJECTIVE

Vasomotor responses can travel along the wall of resistance microvessels by two distinct mechanisms: cell-to-cell conduction through gap junctions or the release of neurotransmitter along perivascular nerves. It is unknown whether vascular innervation influences the expression of connexin molecules which comprise gap junctions, or the conduction of vasomotor responses. In feed arteries of the hamster retractor muscle (RFA), the authors tested whether sympathetic denervation would alter the expression of connexin isoforms and the conduction of vasomotor responses.

METHODS

Using intact vessels with sympathetic innervation and those 7-8 days following denervation surgery, mRNA expression was quantified using real-time PCR, cellular localization of Cx protein was characterized using immunohistochemistry, and vasomotor responses to dilator and constrictor stimuli were evaluated in isolated pressurized RFA.

RESULTS

Connexin protein localization and mRNA expression were similar between innervated and denervated vessels. mRNA levels were Cx43 = Cx37 > Cx45 >> Cx40. Vasodilation to acetylcholine conducted >/=2000 microm along innervated and denervated vessels, as did the biphasic conduction of vasoconstriction and vasodilation in response to KCl. Vasoconstriction to phenylephrine conducted <500 microm and was attenuated (p <.05) in denervated vessels.

CONCLUSIONS

The profile of connexin expression and the conduction of vasomotor responses are largely independent of sympathetic innervation in feed arteries of the hamster retractor muscle (RFA).

A role for protein kinase C in the supersensitivity of the rat vas deferens following chronic surgical denervation

Chronic surgical denervation of the rat vas deferens leads to an enhanced contractile response of the tissue to norepinephrine in vitro. Norepinephrine produces a higher rate of protein kinase C translocation to the particulate fraction of denervated tissues as compared with the paired, control vas deferens. Diacylglycerol generation in response to norepinephrine and contractile responses to phorbol diacetate were not altered by chronic denervation of the vas deferens. However, the contractile response to norepinephrine in these tissues was less susceptible to the inhibitory effects of the calcium channel blocker nifedipine. A potential role of protein kinase C in sensitizing the contractile apparatus to mobilized calcium in denervation supersensitivity is discussed.

Regional regulation of choroidal blood flow by autonomic innervation in the rat

Regional influences of parasympathetic and sympathetic innervation on choroidal blood flow were investigated in anesthetized rats. Parasympathetic pterygopalatine neurons were activated by electrically stimulating the superior salivatory nucleus, whereas sympathetic neurons were activated by cervical sympathetic trunk stimulation and uveal blood flow was measured by laser Doppler flowmetry. Parasympathetic stimulation increased flux in the anterior choroid and nasal vortex veins but not in the posterior choroid. Vasodilation was blocked completely by the neuronal nitric oxide synthase inhibitor 1-(2-trifluoromethylphenyl)imidazole but was unaffected by atropine. Sympathetic stimulation decreased flux in all regions, and this was blocked by prazosin. Parasympathetic stimulation did not affect vasoconstrictor responses to sympathetic stimulation in the posterior choroid but attenuated the decrease in blood flow through the anterior choroid and vortex veins via a nitrergic mechanism. We conclude that sympathetic alpha-noradrenergic vasoconstriction occurs throughout the choroid, whereas parasympathetic nitrergic vasodilation plays a selective role in modulating blood flow in anterior tissues of the eye.

Absence of denervation supersensitivity to neurokinin A in the rat vas deferens

1. Unilateral denervation of the rat vas deferens (RVD) was performed under anesthesia. The animals were allowed to recover 4 or 10 days and then concentration-effect (C-E) curves to noradrenaline (NA) and neurokinin A (NKA) were constructed in denervated and control RVD. 2. Tissues denervated 4 or 10 days produced NA responses shifted 20-fold to the left with maxima 130% of control. 3. NKA C-E curves in denervated RVD were not significantly different from control. 4. Phenylephrine exhibited a 6-fold increase in tissue sensitivity after denervation. 5. Chronic denervation of the vas deferens resulted in significant postsynaptic supersensitivity to alpha 1-adrenoceptor agonists but not to NKA.

Involvement of postjunctional purinergic mechanisms in the facilitatory action of bradykinin in neurotransmission in the rat vas deferens

To investigate the nature of the bradykinin-induced potentiation of electrically driven muscle twitches in the isolated vas deferens, bradykinin, noradrenaline and adenosine 5'-triphosphate (ATP) concentration-response curves were made with control, reserpinized and chemically sympathectomized rats. Bradykinin potentiated the ATP- but not the noradrenaline-induced contractions in the epididymal and prostatic segments of the ductus. The epididymal segment of the ductus did not respond to transmural electrical stimulation following reserpine treatment. Bradykinin potentiated the muscular contractions caused by exogenous ATP but not by noradrenaline. In contrast, the transmurally evoked twitches of the prostatic portion of the ductus remained almost unaltered; bradykinin increased the motor effect of ATP without modifying the potency of noradrenaline. All neuronally induced contractile activity was absent in sympathectomized rats; bradykinin potentiated the contractile effect of ATP without altering the noradrenaline-induced contractions. These results suggest that bradykinin potentiates the ATP-evoked contractions by acting postjunctionally.

Hyperactivity of Ca channels in vasa deferentia smooth muscle of diabetic rats

Contractile responses of strips of the prostatic end of vasa deferentia isolated from streptozotocin-treated diabetic rats were investigated with five agonists. Agonists induced similar biphasic responses in vasa deferentia from diabetic and age-matched control rats six to seven weeks after streptozotocin. Twitches were observed superimposed on contractions induced by the adrenergic agonists in strips from most of the diabetic rats. Strips from the diabetic rats developed significantly greater tension than those from the controls. Especially, strips from diabetics had remarkably greater dose-related responses to Ca, and greater Ca influx, than controls when tested in the presence of either KCl or clonidine. The results suggest that both voltage-dependent Ca channels and receptor-operated Ca channels contribute to potentiation of contractile responses in diabetes.

Hormonal influence on the neurogenic response of the hamster vas deferens

The effect of castration on in vitro contractility of smooth muscle of the vas deferens and body of the bladder has been studied in the hamster. Castration produced supersensitivity to in vitro electrical stimulation and norepinephrine in the vas deferens, but had no effect on the body of the bladder. Castration also increased the maximum contractile response of the vas deferens to electrical stimulation, norepinephrine, ATP, acetylcholine and histamine. The changes in contractility of smooth muscle of the vas deferens developed slowly and may be explained by specific effects upon adrenergic and purinergic neurotransmission and/or non-specific effects upon smooth muscle cell membranes.

On the abnormalities of contractile responses of rat vasa deferentia to norepinephrine in genetic hypertension

Contractile responses to norepinephrine (NE) of strips of vasa deferentia from prostatic end isolated from rats with genetic hypertension and deoxycorticosterone (DOC)-salt induced hypertension were examined. Maximum responses to NE of vasa deferentia from all hypertensive and corresponding normotensive control rats were biphasic. Spontaneous rhythmic activities superimposed on the NE-induced contraction were observed in most of the SHR (spontaneously hypertensive rat) strips, some of the WKY (Wistar-Kyoto normotensive rat) strips and none of the NWR (regular normotensive Wistar rat) strips. Neither the fast- nor the slow-component of the maximum contractile response to NE was altered in the vasa deferentia from SHR compared to those from WKY and in vasa deferentia from DOC-salt hypertensive rats (DHR) compared to those from the corresponding DOC-salt treated but normotensive controls (DNR). However, the strips from NWR developed significantly greater tension than those from WKY and DNR. Our findings suggest that interpretation of studies on hypertension in rats should take into account differences between tissues related to the strain of the rats used as controls for genetic hypertension.

Effects of ovarian steroids and pregnancy on adrenergic nerves of uterus and oviduct

This review concerns the influence of ovarian steroids and of pregnancy on norepinephrine (NE) metabolism in the adrenergic neurons of the female reproductive tract and speculates on the physiological consequences of this influence. Estrogen and progesterone affect not only the NE content of these nerves but also the turnover of NE, the activity of its synthetic enzyme, and releases of NE from nerve terminals. During pregnancy additional factors including stretch-induced hypertrophy come into play and cause degeneration of the nerves in the uterine corpus. This degeneration makes the muscle supersensitive to NE and may also induce morphological changes in the muscle cell membrane. As a result there may be a withdrawal of neural inhibitory influences on the corpus, allowing spontaneous myogenic contractions to intensify. Although the physiological significance of the steroid-transmitter interactions are still unclear, these nerves per se are of interest because they represent a model system for the study of neuroendocrine regulation in the peripheral nervous system.