Alpha(1D)-adrenoceptors mediate nerve and agonist-evoked contractions in mouse vas deferens: evidence obtained from knockout technology.

1 It has been demonstrated that nerve-evoked contractions of the rat vas deferens involve alpha(1D)-adrenoceptors. Definitive evidence for a similar alpha(1D)-adrenoceptor-mediated response in mouse vas deferens has been more difficult to obtain. In this study, we have used alpha(1D)-adrenoceptor knockout (alpha(1D)-KO) mice to aid in the pharmacological characterization. 2 Mouse whole vas deferens was stimulated with a single pulse every 5 min. Once a stable response had been obtained, vehicle or antagonist was administered cumulatively at 5-min intervals and a response to stimulation obtained 5 min later. Cumulative concentration-response curves were also obtained for noradrenaline. 3 In vas deferens from alpha(1D)-KO mice, the contractile response to low concentrations of noradrenaline and the contractile response to a single stimulus were significantly reduced as compared to wild type (WT). 4 The alpha(1D)-adrenoceptor selective antagonist, BMY 7378, produced a concentration-dependent inhibition of single pulse-evoked contractions of vas deferens from WT and alpha(1D)-KO mice. BMY 7378 was significantly less potent in inhibiting stimulation-evoked contractions in vas deferens from alpha(1D)-KO mice. 5 It is concluded that alpha(1D)-adrenoceptors mediate a component of nerve- and agonist-evoked contractions of the vas deferens of WT mice.

The alpha (1D)-adrenoceptor antagonist BMY 7378 is also an alpha (2C)-adrenoceptor antagonist.

1 We have investigated the actions of the alpha(1D)-adrenoceptor selective antagonist BMY 7378 in comparison with yohimbine at alpha(1)- and alpha(2)-adrenoceptors. 2 In rat aorta (alpha(1D)-adrenoceptor), BMY 7378 (pA(2) of 8.67) was about 100 times more potent than yohimbine (pA(2) of 6.62) at antagonizing the contractile response to noradrenaline. 3 In human saphenous vein (alpha(2C)-adrenoceptor), BMY 7378 (pA(2) of 6.48) was approximately 10 times less potent than yohimbine (pA(2) of 7.56) at antagonizing the contractile response to noradrenaline. 4 In prostatic portions of rat vas deferens, BMY 7378 (10 mum) did not significantly affect the concentration-dependent inhibition of single pulse nerve stimulation-evoked contractions by xylazine (an action at prejunctional alpha(2D)-adrenoceptors). 5 In ligand-binding studies, BMY 7378 showed 10-fold selectivity for alpha(2C)-adrenoceptors (pK(i) of 6.54) over other alpha(2)-adrenoceptors. 6 It is concluded that BMY 7378, in addition to alpha(1D)-adrenoceptor selectivity in terms of alpha(1)-adrenoceptors, shows selectivity for alpha(2C)-adrenoceptors in terms of alpha(2)-adrenoceptors.

Actions of R- and S-verapamil and nifedipine on rat vascular and intestinal smooth muscle.

1 We have investigated the actions of the calcium entry blockers nifedipine, R-verapamil and S-verapamil in rat aorta, colon and vas deferens. 2 In aorta and colon, these agents produced concentration-dependent relaxations of KCl (80 mM)-induced contractions. In both tissues, the order of potency was nifedipine > S-verapamil > R-verapamil. However, nifedipine showed selectivity for aorta (potency ratio, colon/aorta: 4.36), S-verapamil showed no selectivity (0.62), but R-verapamil showed selectivity for colon (0.19). 3 In prostatic portions of rat vas deferens, nifedipine (10 microM) abolished the contraction to a single electrical stimulus, but R- and S-verapamil were without effect. In epididymal portions of rat vas deferens, R- and S-verapamil inhibited alpha1-adrenoceptor-mediated contractions to a single electrical stimulus at concentrations of 10 microM and above. 4 In conclusion, R-verapamil may prove useful as an intestinal selective calcium entry blocker in the treatment of intestinal disease with a hypermotility component, e.g. irritable bowel syndrome.

Transforming growth factor beta1 alters synapsin distribution and modulates synaptic depression in Aplysia.

Transforming growth factor beta1 (TGF-beta1) induces long-term synaptic facilitation and long-term increases in excitability in Aplysia. Here we report that this growth factor has acute effects as well. Treatment of pleural-pedal ganglia with TGF-beta1 for 5 min activated mitogen-activated protein kinase (MAPK) and stimulated the phosphorylation of synapsin in a MAPK-dependent manner. This phosphorylation appeared to modulate synapsin distribution in cultured sensory neurons. Control neurons exhibited a punctate distribution of synapsin along neurites, which appeared to represent high concentration aggregates of synapsin. TGF-beta1-treated sensory neurons showed a significant reduction in the number of these puncta, an effect that was blocked by the MAP/ERK kinase inhibitor U0126. The functional consequence of TGF-beta1 was tested by examining its effects on synaptic transmission at the sensorimotor synapse. Application of TGF-beta1 reduced the magnitude of synaptic depression. This effect was dependent on MAPK, consistent with the hypothesis that TGF-1 mobilizes synaptic vesicles through the phosphorylation of synapsin.

TGF-beta1 in Aplysia: role in long-term changes in the excitability of sensory neurons and distribution of TbetaR-II-like immunoreactivity.

Exogenous recombinant human transforming growth factor beta-1 (TGF-beta1) induced long-term facilitation of Aplysia sensory-motor synapses. In addition, 5-HT-induced facilitation was blocked by application of a soluble fragment of the extracellular portion of the TGF-beta1 type II receptor (TbetaR-II), which presumably acted by scavenging an endogenous TGF-beta1-like molecule. Because TbetaR-II is essential for transmembrane signaling by TGF-beta, we sought to determine whether Aplysia tissues contained TbetaR-II and specifically, whether neurons expressed the receptor. Western blot analysis of Aplysia tissue extracts demonstrated the presence of a TbetaR-II-immunoreactive protein in several tissue types. The expression and distribution of TbetaR-II-immunoreactive proteins in the central nervous system was examined by immunohistochemistry to elucidate sites that may be responsive to TGF-beta1 and thus may play a role in synaptic plasticity. Sensory neurons in the ventral-caudal cluster of the pleural ganglion were immunoreactive for TbetaR-II, as well as many neurons in the pedal, abdominal, buccal, and cerebral ganglia. Sensory neurons cultured in isolation and cocultured sensory and motor neurons were also immunoreactive. TGF-beta1 affected the biophysical properties of cultured sensory neurons, inducing an increase of excitability that persisted for at least 48 hr. Furthermore, exposure to TGF-beta1 resulted in a reduction in the firing threshold of sensory neurons. These results provide further support for the hypothesis that TGF-beta1 plays a role in long-term synaptic plasticity in Aplysia.

Cellular correlates of long-term sensitization in Aplysia.

Although in vitro analyses of long-term changes in the sensorimotor connection of Aplysia have been used extensively to understand long-term sensitization, relatively little is known about the ways in which the connection is modified by learning in vivo. Moreover, sites other than the sensory neurons might be modified as well. In this paper, several different biophysical properties of sensory neurons, motor neurons, and LPl17, an identified interneuron, were examined. Membrane properties of sensory neurons, which were expressed as increased excitability and increased spike afterdepolarization, were affected by the training. The biophysical properties of motor neurons also were affected by training, resulting in hyperpolarization of the resting membrane potential and a decrease in spike threshold. These results suggest that motor neurons are potential loci for storage of the memory in sensitization. The strength of the connection between sensory and motor neurons was affected by the training, although the connection between LPl17 and the motor neuron was unaffected. Biophysical properties of LPl17 were unaffected by training. The results emphasize the importance of plasticity at sensory-motor synapses and are consistent with the idea that there are multiple sites of plasticity distributed throughout the nervous system.

Role of transforming growth factor-beta in long-term synaptic facilitation in Aplysia.

The role of transforming growth factor-beta (TGF-beta) in long-term synaptic facilitation was examined in isolated Aplysia ganglia. Treatment with TGF-beta1 induced long-term facilitation (24 and 48 hours), but not short-term (5 to 15 minutes) or intermediate-term (2 to 4 hours) facilitation. The long-term effects of TGF-beta1 were not additive with those of serotonin. Moreover, serotonin-induced facilitation was blocked by an inhibitor of TGF-beta. Thus, activation of TGF-beta may be part of the cascade of events underlying long-term sensitization, consistent with the hypothesis that signaling molecules that participate in development also have roles in adult neuronal plasticity.

A developmental gene (Tolloid/BMP-1) is regulated in Aplysia neurons by treatments that induce long-term sensitization.

Long-term sensitization training, or procedures that mimic the training, produces long-term facilitation of sensory-motor neuron synapses in Aplysia. The long-term effects of these procedures require mRNA and protein synthesis (Montarolo et al., 1986; Castellucci et al., 1989). Using the techniques of differential display reverse transcription PCR (DDRT-PCR) and ribonuclease protection assays (RPA), we identified a cDNA whose mRNA level was increased significantly in sensory neurons by treatments of isolated pleural-pedal ganglia with serotonin for 1.5 hr or by long-term behavioral training of Aplysia. The effects of serotonin and behavioral training on this mRNA were mimicked by treatments that elevate cAMP. The aplysia mRNA increased by serotonin and behavioral training was 41-45% identical to a developmentally regulated gene family which includes Drosophila tolloid and human bone morphogenetic protein-1 (BMP-1). Both tolloid and BMP-1 encode metalloproteases that might activate TGF-beta (transforming growth factor beta)-like molecules or process procollagens. Aplysia tolloid/BMP-1-like protein (apTBL-1) might regulate the morphology and efficacy of synaptic connections between sensory and motor neurons, which are associated with long-term sensitization.

Long-term structural remodeling in Aplysia sensory neurons requires de novo protein synthesis during a critical time period.

Long-term sensitization training induces persistent changes in both electrophysiological properties and specific structural features of sensory neurons in Aplysia californica. Previously, we found that transient elevation of intracellular cAMP could also modify these features in sensory neurons located in the pleural ganglion. In the present study we examined the role of protein synthesis in structural remodeling induced by cAMP. When applied during the intracellular injection of cAMP, anisomycin blocked increases in both the number of varicosities and the number of branch points in single sensory neurons. Exposure to anisomycin during different time periods, from as early as 12 hr prior to cAMP injection to periods as late as 15 hr after, indicated that the requirement for protein synthesis starts at the time of cAMP injection and extends for at least seven hours afterwards. Because it is metabolized rapidly, cAMP probably triggers a cascade of protein synthesis whose products continue to be synthesized for several hours after cAMP levels have returned to baseline. Thus, the present results suggest that the induction of long-term structural changes in sensory neurons has an extended but finite requirement for protein synthesis.

Modulation of an inhibitory interneuron in the neural circuitry for the tail withdrawal reflex of Aplysia.

1. Serotonin (5-HT), small cardioactive peptide B (SCPB) and FMRFamide have well-established facilitatory and inhibitory effects on sensory neurons and their connections with motor neurons mediating withdrawal reflexes in Aplysia. Little is known, however, about their effects on interneurons contributing to those reflexes. As a first step, we examined the effects of these three transmitters on the identified inhibitory interneuron RP14 in isolated pleural-pedal ganglia. 2. Bath application of 5-HT hyperpolarized RP14, inhibited its spontaneous activity and decreased its excitability. In addition, 5-HT decreased the amplitude of inhibitory postsynaptic potentials produced by RP14 in tail sensory and motor neurons. 3. In contrast, bath application of SCPB increased spontaneous activity in RP14. Subsequent application of 5-HT to the bath, which still contained SCPB, inhibited RP14. Therefore, the effects of SCPB were essentially opposite to those of 5-HT on this inhibitory interneuron. 4. FMRFamide had little effect on RP14. It did not produce an obvious change in its resting membrane potential and produced only a transient increase in its spontaneous activity. 5. These results suggest that various neuromodulators have differential effects on elements of the neuronal circuit underlying the tail-withdrawal reflex of Aplysia. Differential modulation may determine the overall behavioral manifestations associated with sensitization.

Occupational low back disability: effective strategies for reducing lost work time.

1. The important variables related to lost work time in this study are: back diagnosis (lumbar disc displacement), history of back surgery, job satisfaction, and employee reluctance to report low back pain to supervisor. 2. The findings support the complexity of low back disability. Lost work time related to low back pain must be managed using a "holistic" approach by addressing all dimensions of a person (physical, emotional, and environmental). 3. To minimize low back disability, occupational health providers should be part of a community task force with representatives from other disciplines who can plan and develop low back disability guidelines and standards of care.

Acute interstitial nephritis with renal failure associated with propylthiouracil therapy.

Propylthiouracil therapy is associated with a variety of adverse reactions. Renal involvement, although rare, has occurred, but neither acute interstitial nephritis nor severe acute renal failure has been reported previously. We report a case of fulminant acute interstitial nephritis with renal failure following treatment with propylthiouracil.

Identification and characterization of pleural neurons that inhibit tail sensory neurons and motor neurons in Aplysia: correlation with FMRFamide immunoreactivity.

Neurons on the rostral edge of the ventral surface of the right pleural ganglion were identified as elements of the circuit mediating the defensive tail withdrawal reflex of Aplysia. These neurons produced IPSPs in tail sensory neurons and were classified into two groups, RPI4 and RPI5, according to their affinity for an antibody directed against FMRFamide. RPI4 was not FMRFamide immunoreactive, and RPI5 was. RPI4 and RPI5 were found to have different electrophysiological profiles. The summated IPSPs in sensory neurons produced by RPI4 developed more rapidly and had a shorter duration than those produced by RPI5. In addition, RPI4 produced IPSPs in the tail motor neurons, whereas RPI5 did not. Both RPI4 and RPI5 received excitatory synaptic inputs from stimulation of the pleural-abdominal connective as well as peripheral nerves P8 and P9, which innervate the tail and posterior part of the animal's body. These inputs were sufficient to elicit spikes. In RPI4, the excitatory synaptic inputs were followed by short and transient hyperpolarization, whereas in RPI5, the excitatory synaptic inputs were followed by slow and long-lasting hyperpolarization. Excitatory inputs elicited in RPI4 by stimulation of peripheral nerves appeared to be mediated, at least in part, by activation of tail sensory neurons. Intracellular stimulation of sensory neurons produced EPSPs in RPI4 that appeared to be monosynaptic. These results suggest that inhibitory interneurons underlying the circuit of the tail withdrawal reflex may play roles in mediating or modulating neuronal responses to tail stimulation. By inhibiting tail sensory and motor neurons, these interneurons may reduce the effectiveness of an animal's response to stimulation of the tail.