Modulation of the Aplysia gill withdrawal reflex by dopamine

The ability of dopamine to modulate gill contractions was tested in Aplysia. When dopamine was perfused through the gill vasculature, gill contractions caused by siphon stimulation (gill withdrawal reflex) and by depolarization of the gill motor neuron L7 were increased in amplitude, as compared with those evoked during seawater perfusion. Habituation of gill movements, brought about by repetitive stimulation of the siphon or of L7, was prevented by dopamine. Despite the absence of reflex habituation, the number of action potentials in central gill motor neurons, evoked by siphon stimulation, showed normal decrement. Dopamine's effects were blocked when the ctenidial nerve was cut or when L7 hyperpolarized. These data suggest that dopamine acts peripherally to increase the efficacy of L7's synaptic transmission onto gill muscle or elements of the gill neural plexus.     

L9 modulation of gill withdrawal reflex habituation in Aplysia

Repeated tactile stimulation of the siphon in Aplysia normally results in habituation of the gill withdrawal reflex and a concomitant decrease in the amplitude of the excitatory synaptic input to gill motor neurons in the abdominal ganglion. It was found, however, that induced low-level tonic activity in motor neuron L₉, which does not itself elicit a gill withdrawal movement, prevented habituation of the reflex from occurring. Further, in preparations already habituated, this tonic low-level activity brought about a reversal of habituation. Although tonic L₉ activity prevented the occurrence of habituation or brought about its reversal, it did not interfere with the synaptic decremental process which normally accompanies gill reflex habituation. Motor neurons L₇ and LDG₁ were found not to possess this ability of L₉ to modulate gill reflex habituation. Evidence suggests that L₉'s modulatory effect is mediated in the periphery, in the gill and not centrally in the abdominal ganglion.     

L9 modulation of gill withdrawal reflex habituation in Aplysia.

Repeated tactile stimulation of the siphon in Aphysia normally results in habituation of the gill withdrawal reflex and a concomitant decrease in the amplitude of the excitatory synaptic input ot gill motor neurons in the abdominal ganglion. It was found, however, that induced low-level tonic activity in motor neuron L9, which does not itself elicit a gill withdrawal movement, prevented habituation of the reflex from occurring. Further, in preparations already habituated, this tonic low-level activity brought about a reversal of habituation. Although tonic L9 activity prevented the occurrence of habituation or brought about its reversal, it did not interfere with the synaptic decremental process which normally accompanies gill reflex habituation. Motor neurons L7 and LDG1 were found not to possess this ability of L9 to modulate gill reflex habituation. Evidence suggests that L9's modulatory effect is mediated in the periphery, in the gill and not centrally in the abdominal ganglion.     

FMRFamide prevents habituation and potentiates the gill withdrawal reflex in the isolated gill preparation of Aplysia

Perfusion of the endogenous neuropeptide, FMRFamide, through the isolated gill of Aplysia facilitated the amplitude of the gill withdrawal reflex (GWR) evoked by tactile stimulation of the gill. The GWR was facilitated in a dose-dependent manner. The facilitation of the GWR produced by FMRFamide perfusion was reversible. In addition to facilitating GWR amplitude, FMRFamide perfusion could also prevent habituation of the reflex. It is hypothesized that FMRFamide may play a role in the peripheral nervous system (PNS) in the gill in the mediation of behavioral state and modulation of adaptive gill behaviors.     

Dopamine modulation of gill reflex behavior in Aplysia.

We have studied the effects of dopamine on the gill withdrawal reflex evoked by tactile siphon stimulation in the margine mollusc Aplysia. Physiological concentrations of dopamine (diluted in seawater) were perfused through the gill during siphon stimulation series. The amplitude of the reflex was potentiated by dopamine and habituation of the reflex was prevented. This occurred with no change in the activity evoked in central motor neurons. These results lead us to conclude that the dopaminergic motor neuron L9 is modulating habituation in the periphery and that the central nervous system facilitatory control of the peripheral nervous system may act via a dopaminergic pathway.     

In vitro classical conditioning of a gill withdrawal reflex in Aplysia: neural correlates and possible neural mechanisms

An in vitro preparation consisting of the siphon, mantle, gill, and abdominal ganglion undergoes classical conditioning when a weak tactile stimulus (CS) applied to the siphon is paired with a strong tactile stimulus to the gill (UCS). When the stimuli are paired, the CS comes to evoke a gill withdrawal reflex (GWR) which increases in amplitude with training. Only when the stimuli are paired in a classical conditioning paradigm does the CS come to evoke a GWR. With classical conditioning training there is an alteration in the synaptic efficacy between central sensory neurons and central gill motor neurons. Moreover, these changes can be observed in sensory neurons not activated by the CS. The changes observed, as evidence by the number of action potentials evoked in the gill motor neuron do not completely parallel the observed behavioral changes. It is suggested that in addition to changes in the synaptic efficacy at the sensory-motor neuron synapse, other changes in neuronal activity occur at other loci which lead to the observed behavioral changes.     

Some receptor properties in motor neurons of an Aplysia withdrawal reflex.

Glutamate or a glutamate-related substance is the neurotransmitter used at the majority of the excitatory junctions of the neuronal network mediating the gill and siphon withdrawal reflex in Aplysia. In this report, we have studied some receptor properties of the major postsynaptic elements of the network, the motor neurons. We have examined the effect of a compound interfering with glutamate receptor, concanavalin A (con A). We found that con A treatment transforms the mainly hyperpolarizing responses to L-glutamate in motor neurons to prolonged depolarizing ones; these latter responses are sensitive to CNQX. We have also examined whether con A could enhance the CNQX sensitive excitatory postsynaptic potentials in these motor neurons. We found, by contrast, that con A did not alter the synaptic responses. The possible implications of the differential effect of con A on the glutamate responses and the synaptic responses are discussed.     

Cholinergic receptors in the Aplysia gill

Acetylcholine has been suggested as a neurotransmitter released in the Aplysia gill by peripheral afferents of central neurons and by peripheral neurons within the gill. The perfused gill, isolated from the abdominal ganglion, was examined. At concentrations greater than 1 microM, acetylcholine elicited a slowly developing tonic contraction of the afferent vein that reversed upon washout. This effect was observed on both quiescent and active preparations. At concentrations less than 1 microM, acetylcholine perfusion resulted in a reduction of gill tone. The excitatory effect of acetylcholine was reduced 80 and 60% by the cholinergic antagonists atropine and hexamethonium, respectively. The acetylcholine-evoked contraction was potentiated 2.5-fold when curare was coinfused. Carbachol did not mimic the excitatory effects of acetylcholine. At all concentrations examined (1-100 microM), carbachol infusion reduced baseline tension, the amplitude of spontaneous contractions and contractions evoked by FMRFamide and dopamine. Contractions evoked by perfusion of p-chlorophenylthiocyclic AMP were greatly reduced when carbachol was added to the perfusate. Further addition of curare reversibly blocked carbachol inhibition of the cyclic AMP-evoked contractions. These findings suggest that excitatory and inhibitory cholinergic receptors are involved in the regulation of gill contractile behavior by acetylcholine.     

Transfer of habituation between stimulation sites of the siphon withdrawal reflex in Aplysia californica

Habituation of the siphon withdrawal reflex (SWR) can be evoked by iterative tactile stimuli presented to one of several sites, including the siphon and gill. The SWR evoked at an arbitrary "test" site did not habituate when stimuli were presented at 20-min intervals. However, there was a large decrease in the reflex evoked at the test site when the trial was preceded by 10 repetitive stimuli (interstimuli interval = 30 s) presented to the opposite "habituation" site. Transfer of habituation occurred from gill to siphon stimulation sites, and vice versa. There was a concomitant decrease in the excitatory input evoked in the central siphon motor neurons LDS1 and LDS3. Moreover, transfer of habituation occurred after the abdominal ganglion (central nervous system) was removed. There was little change in the magnitude of the control responses or transfer of habituation after deganglionation. Since transfer of habituation between stimulation sites of the SWR was similar to that reported previously for the gill withdrawal reflex, it was suggested that a common mechanism may underlie the two behaviors.     

Muscle mechanosensitive reflex is suppressed in the conscious condition: effect of anesthesia.

To test the hypothesis that a muscle mechanosensitive reflex is suppressed in the conscious condition, we examined the effect of anesthesia on the cardiovascular responses to passive mechanical stretch of the hindlimb triceps surae muscle in six conscious cats. The triceps surae muscle was manually stretched for 30 s by extending the hip and knee joints and subsequently by dorsiflexing the ankle joint; the lateral gastrocnemius muscle was lengthened by 19 +/- 2.6 mm. Heart rate (HR) and mean arterial blood pressure (MAP) did not change significantly during passive stretch of the muscle in the conscious condition. At 10-40 min after intravenously administering pentobarbital sodium (20-25 mg/kg), the identical passive stretch of the triceps surae muscle was able to induce the cardiovascular responses; HR and MAP were increased by 14 +/- 1.3 beats/min and 14 +/- 1.4 mmHg, respectively, and the cardiovascular responses were sustained throughout the passive stretch. In contrast, stretching skin on the triceps surae muscle evoked no significant changes in HR and MAP in the anesthetized condition. When anesthesia became light 40-90 min after injection of pentobarbital and the animals started to show spontaneous body movement, the cardiovascular response to passive muscle stretch tended to be blunted again. It is therefore concluded that passive mechanical stretch of skeletal muscle is capable of evoking the reflex cardiovascular response, which is suppressed in the conscious condition but exaggerated by anesthesia.     

Adult hippocampal cell proliferation is suppressed with estrogen withdrawal after a hormone-simulated pregnancy

Estradiol withdrawal after pregnancy is hypothesized to precipitate depressive symptoms in vulnerable women. A hormone-simulated pregnancy was induced in female rats and the effects of a ‘postpartum’ drop in estradiol on hippocampal cell proliferation were examined. All groups were ovariectomized or given sham surgery prior to treatment. Rats were randomly assigned to ‘postpartum’, ‘postpartum’ + EB (estradiol benzoate), ‘postpartum’ + DPN (diarylpropionitrile; an ERβ agonist), ‘postpartum’ + IMI (imipramine; a tricyclic antidepressant), sham, ovariectomized (OVX), sham + IMI or OVX + IMI groups. All ‘postpartum’ groups received hormone injections (estradiol and progesterone) over 23 days to simulate pregnancy, while IMI groups also received daily imipramine injections. After day 23, ‘postpartum’ rats were withdrawn from the hormone-simulated pregnancy (mimicking the postpartum drop in gonadal hormones), while other ‘postpartum’ treatment groups received daily injections of DPN, EB or IMI. On day 3 ‘postpartum’ all rats were injected with bromodeoxyuridine (BrdU; a DNA synthesis marker) and perfused 24 h later to assess cell proliferation and cell death in the dentate gyrus. ‘Postpartum’ hormone withdrawal decreased hippocampal cell proliferation in the ‘postpartum’ and ‘postpartum’ + EB groups only. Chronic imipramine significantly increased hippocampal cell proliferation in sham + IMI, but not OVX + IMI rats suggesting that imipramine's effects to increase hippocampal cell proliferation in female rats is related to reproductive status. Cell death (pyknotic cells) was decreased only in the ‘postpartum’ group. Together, these results suggest an important, though complex, role for gonadal hormones in the cellular changes accompanying this model of postpartum depression.     

The influence of sexually active non-reproductive groups on persistent sexually transmitted diseases

We describe several population models exposed to a mild life-long sexually transmitted disease, i.e. without significant increased mortality among infected individuals and providing no immunity/recovery. We then modify these models to include non-reproductive groups consisting of those isolated from sexual contact and those who are sexually active but infertile due to choice, medical or other reasons. We analyse the potential effect on the dynamics of the population. We are interested in how the isolated class may curb the growth of the infected group while keeping the healthy population at acceptable levels. We also analyse the difference between being sexually active and abstained within the non-reproductive class and its impact on the epidemic reproductive number and the nature of the bifurcation around the disease-free equilibrium. We provide a comparison with our models introduced in a previous article, which include only the isolated from sexual contact class.     

The influence of sexually active non-reproductive groups on persistent sexually transmitted diseases

We describe several population models exposed to a mild life-long sexually transmitted disease, i.e. without significant increased mortality among infected individuals and providing no immunity/recovery. We then modify these models to include non-reproductive groups consisting of those isolated from sexual contact and those who are sexually active but infertile due to choice, medical or other reasons. We analyse the potential effect on the dynamics of the population. We are interested in how the isolated class may curb the growth of the infected group while keeping the healthy population at acceptable levels. We also analyse the difference between being sexually active and abstained within the non-reproductive class and its impact on the epidemic reproductive number and the nature of the bifurcation around the disease-free equilibrium. We provide a comparison with our models introduced in a previous article, which include only the isolated from sexual contact class.     

Rhombic particle arrays in gill epithelium of a mollusc, Aplysia californica.

Gill epithelia from adult and juvenile Aplysia were examined by conventional thin section and freeze-fracture methods. Freeze-fracture replicas of adult gill epithelium revealed septate and gap junctions, which served as membrane markers for the epithelial cells. In these same cell membranes, non-junctional rhombic arrays of intramembranous particles were observed on prominent ridges on the membrane P fracture face of some epithelial cells. In thin sections of adult epithelium, nerve terminals were observed abutting the lateral plasma membranes near the basal lamina of some epithelial cells. Correlative areas of plasma membrane in freeze-fracture replicas showed a close association between rhombic particle arrays and abutting nerve terminals. In thin sections of juvenile Aplysia, nerve terminals abutting the epithelial cells were not recognizable, and rhombic arrays were not observed in freeze-fracture replicas. This suggested that a developmental association existed between the appearance of rhombic arrays in adult epithelia and their innervation. It is not known with certainty if, in invertebrates, rhombic arrays are an essential structural entity of all innervated cell membranes; however, in the cells thus far studied, there appears to be an associative condition. In the case of the gill epithelium of Aplysia, rhombic arrays are located in the same vicinity as the abutting nerve terminals. Similar arrays of intramembranous particles have been observed in myoneural postjunctional complexes of other invertebrates and have been interpreted to be the morphological expression of neurotransmitter receptors. An analogous explanation is put forth, namely that rhombic arrays may represent the structural correlates of neurotransmitter receptors and/or ionic channels in innervated membranes of invertebrates.     

The effects of small cardioactive peptide B on the isolated heart and gill of Aplysia californica

Effects of small cardioactive peptide B on the physiology of the isolated heart and gill preparations from the mollusc Aplysia californica were examined. In addition, the effects of small cardioactive peptide B and FMRFamide (Phe-Met-Arg-Phe-NH2) on adenylate cyclase activity were compared in particulate fractions of heart and gill tissues, respectively. Small cardioactive peptide B was found to exert dose-dependent, reversible changes in cardiac activity when perfused through the isolated heart. The EC50 values effecting changes in heart rate and force of contraction were 3 X 10(-11) and 3 X 10(-10) M, respectively; minimum concentrations found to effect changes in heart rate and force of contraction were normally 10(-15) and 10(-12) M, respectively. However, some winter hearts demonstrated threshold sensitivity to small cardioactive peptide B at concentrations as low as 10(-17) M. When perfused through the isolated gill, small cardioactive peptide B was found to suppress the gill withdrawal response amplitude with a threshold concentration of 10(-14) M and an EC50 value of 3 X 10(-11) M. Suppression of the gill withdrawal response amplitude by small cardioactive peptide B was found to be dose dependent and reversible up to a concentration of 10(-9) M. At higher concentrations, the suppression tended to persist irreversibly. Small cardioactive peptide B stimulated adenylate cyclase activity in particulate fractions of both heart and gill tissues with an EC50 of 0.1 and 1.0 microM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)