Neural pathways to cardioaccelerator neurons in the isopod crustacean Bathynomus doederleini: Cholinergic activation by somatic movements.

We investigated the excitatory and inhibitory input to cardioaccelerator (CA) and cardioinhibitor (CI) neurons located in the thoracic ganglia of the isopod crustacean Bathynomus doederleini by extracellular and intracellular recording. Electrical stimuli applied to the anterior and posterior connectives of single-ganglion preparations, containing either the 2nd or 3rd thoracic ganglion alone, and each of three paired ganglionic nerve roots produced excitatory postsynaptic potentials (EPSPs) in the cell body of a CA neuron. Artificial movements of appendages, such as the thoracic limbs and the swimmerets, also evoked EPSPs in the CA neuron. Electrical stimuli applied to the peripheral nerves running to appendages induced inhibitory postsynaptic potentials (IPSPs) in a CI neuron. Since artificial movements of the appendages caused decrease of CI impulse rate, these IPSPs in the CI neuron may be caused by mechanoproprioceptors in the appendages. Since tachycardia was accompanied by excitation of CA neurons and inhibition of CI neurons, activation of the mechanoproprioceptors may be responsible for tachycardia. EPSPs in CA neurons produced by stimulation of peripheral nerves were augumented by eserinization and blocked by curarization. The activation of CA neurons by ganglionic roots may be mediated by cholinergic processes ascending from mechanoproprioceptors.

A neural analysis of avoidance conditioning with the feeding attractant glycine in Pleurobranchaea japonica.

Glycine (Gly) is one of the amino acids that most strongly provoke feeding behavior in the carnivorous opisthobranch sea slug Pleurobranchaea japonica. Placing of an aliquot of a Gly solution in front of the anterior end of this animal induced feeding responses such as orientation to the origin of the stimulus and extrusion of the proboscis. In contrast, light stimulation of the body of the animal with a glass-fiber light guide evoked aversive responses involving the gill withdrawal response. Animals were trained by pairing a Gly solution stimulus (conditioned) and a light stimulus (unconditioned). After training with repetitive paired stimuli, we found that animals exhibited aversive responses to the Gly solution. We confirmed achievement of a conditioned Gly-aversive reflex in intact animals by recording of motor impulses with an electrode implanted on the branchial nerve responsible for the gill withdrawal response, the most reliable index of the reflex. Motor discharge of the branchial nerve associated with the conditioned Gly-aversive reflex persisted even in a preparation isolated from an animal which had previously acquired the reflex. This study provides an experimental model for neural analysis with in vivo long-term nerve recording using an electrode implanted in a nerve of an intact animal for neuroethological training.

Excitatory neural control of posterograde heartbeat by the frontal ganglion in the last instar larva of a lepidopteran, Bombyx mori.

The frontal ganglion of the silkworm (Bombyx mori) gives rise to a visceral nerve, branches of which include a pair of anterior cardiac nerves and a pair of the posterior cardiac nerves. Forward-fill of the visceral nerve with dextran labeled with tetramethyl rhodamine shows the anterior cardiac nerves innervate the anterior region of the dorsal vessel. Back-fill of the anterior cardiac nerves with Co(2+) and Ni(2+) ions and the fluorescent dye reveals that the cell bodies of two motor neurons are located in the frontal ganglion. Injection of 5, 6-carboxyfluorescein into the cell body of an identified motor neuron shows that the neuron gives rise to an axon running to the visceral nerve. Unitary excitatory junctional potentials (EJPs) were recorded from a myocardial cell at the anterior end of the heart. They responded in a one-to-one manner to electrical stimuli applied to the visceral nerve, or to impulses generated by a depolarizing current injected into the cell body. EJPs induced by stimuli at higher than 0.5 Hz showed facilitation while those induced at higher than 2 Hz showed summation. Individual EJPs without summation, or a train of EJPs with summation, caused acceleration in the phase of posterograde heartbeat and heart reversal from anterograde heartbeat to posterograde heartbeat. It is likely that the innervation of the anterior region of the dorsal vessel by the motor neurons, through the anterior cardiac nerves is responsible for the control of heartbeat in Lepidoptera, at least in part.

Neuronal and neurohormonal control of the heart in the stomatopod crustacean, Squilla oratoria.

The heart of Squilla oratoria contains a cardiac ganglion that consists of 15 intrinsic neurons, supplied by a pair of inhibitory nerves and two pairs of excitatory nerves, arising from the central nervous system. These comprise the extrinsic cardiac innervation. The paired cardio-inhibitor (CI) nerves run out in the 10th pair of nerve roots emerging from the subesophageal ganglion (SEG). The cell bodies of the CI neurons are found in the hemisphere of the 1st segment of the SEG contralateral to the nerve roots in which the CI axons emerge. The two pairs of 1st and 2nd cardio-accelerator (CA1 and CA2) nerves run out in the 16th and 19th pairs of nerve roots of the SEG. The cell bodies of the CA1 and CA2 neurons are found in the hemispheres of the 3rd and 4th segments of the SEG ipsilateral to the nerve roots in which the CA1 and CA2 axons are found. The heartbeat was activated by application of glutamate, serotonin, dopamine, octopamine or acetylcholine, which were applied to the heart by perfusion into an organ bath. Joro-spider toxin (JSTX) blocked myocardial excitatory junctional potentials evoked by the cardiac ganglion. Neuronal cell bodies and processes in the heart were examined using immunocytochemical techniques. All 15 neurons of the cardiac ganglion showed glutamate-like immunoreactivity. Glutamate may be a neurotransmitter of the cardiac ganglion neurons. JSTX also blocked cardiac acceleration by activation of CA1 and CA2 axons. CA1 and CA2 axons showed glutamate-like immunoreactivity. It is likely that glutamate is a neurotransmitter for the cardio-acceleratory neurons. The heartbeat was inhibited by application of gamma-amino-butyric acid (GABA). Cardiac inhibition induced by activation of CI axons was blocked by picrotoxin. CI axons showed GABA-like immunoreactivity. These results may support the identification of GABA as an extrinsic inhibitory neurotransmitter.

Neurohormonal and glutamatergic neuronal control of the cardioarterial valves in the isopod crustacean Bathynomus doederleini.

The heart of Bathynomus doederleini gives rise to an anterior median artery (AMA), one pair of anterior lateral arteries (ALAs) and five pairs of lateral arteries (LAs). Cardioarterial valves are located at the junctions between the heart and arteries, each composed of a pair of muscular flaps. All valves of the AMA and the ALAs receive valve excitatory (constrictor) nerves (VEs). The valves of the ALAs receive dual innervation from both constrictor and inhibitor (dilator) nerves, while the valves of the AMA receive innervation from a constrictor nerve alone. The effects of candidate neurohormones on cardioarterial valves were examined by measuring the pressure in each artery at which haemolymph flows out of the heart through the valve. Serotonin, octopamine, norepinephrine, glutamate (Glu) and proctolin constricted the cardioarterial valves and thus decreased the arterial pressure in all the arteries. Dopamine also decreased the arterial pressure of arteries except for the ALAs, in which pressure was increased. Among the neurohormones exerting excitatory effects on the valves, only Glu depolarized the membrane potential of valve muscle cells. The glutamatergic agonists kainate and quisqualate also depolarized the valve muscle cells of the AMA. Excitatory junctional potentials produced in the valves of the AMA in response to the stimulation of a VE were blocked by the glutamatergic antagonists Joro spider toxin and MK-801. Glu is the likeliest candidate for a neurotransmitter for the VEs.

Biogenic amines evoke heartbeat reversal in larvae of the sweet potato hornworm, Agrius convolvuli.

The sweet potato hornworm, Agrius convolvuli, possesses a pair of anterior cardiac nerves innervating the dorsal vessel. The anterior cardiac nerves branch off the visceral nerve that arises posteriorly from the frontal ganglion. Heartbeat reversal from anterograde heartbeat to posterograde heartbeat is triggered by the anterior cardiac nerves. Application of octopamine (OA) during the anterograde heartbeat phase reverses the anterograde heartbeat to the posterograde heartbeat, while application of OA during the phase of posterograde heartbeat accelerates heartbeat. The heartbeat reversal from anterograde heartbeat to posterograde heartbeat evoked by stimuli applied to the visceral nerve is blocked by application of the octopaminergic antagonists, phentolamine and chlorpromazine. The results suggest that OA may be a neurotransmitter for the anterior cardiac nerve. The alary muscle of the second segment receives excitatory innervation from the posterior cardiac nerve and from the nerve which extends from the second abdominal ganglion. Activation of the alary muscle results in acceleration of posterograde heartbeat. Other neurotransmitters, besides OA, may take part in the resultant acceleration.