Evidence for GABAAReceptor-mediated Inhibition in Ambiguous Motoneurons

Vagal gustatory reflex circuits for intraoral food sorting behavior in the goldfish: cellular organization and neurotransmitters

The sense of taste is crucial in an animal's determination as to what is edible and what is not. This gustatory function is especially important in goldfish, who utilize a sophisticated oropharyngeal sorting mechanism to separate food from substrate material. The computational aspects of this detection are carried out by the medullary vagal lobe, which is a large, laminated structure combining elements of both the gustatory nucleus of the solitary tract and the nucleus ambiguus. The sensory layers of the vagal lobe are coupled to the motor layers via a simple reflex arc. Details of this reflex circuit were investigated with histology and calcium imaging. Biocytin injections into the motor layer labeled vagal reflex interneurons that have radially directed dendrites ramifying within the layers of primary afferent terminals. Axons of reflex interneurons extend radially inward to terminate onto both vagal motoneurons and small, GABAergic interneurons in the motor layer. Functional imaging shows increases in intracellular Ca++ of vagal motoneurons following electrical stimulation in the sensory layer. These responses were suppressed under Ca(++)-free conditions and by interruption of the axons bridging between the sensory and motor layers. Pharmacological experiments showed that glutamate acting via (+/-)-alpha-amino-3-hydroxy- 5-ethylisoxazole-4-propioinc acid (AMPA)/kainate and N-methyl-D-aspartic acid (NMDA) receptors mediate neurotransmission between reflex interneurons and vagal motoneurons. Thus, the vagal gustatory portion of the viscerosensory complex is linked to branchiomotor neurons of the pharynx via a glutamatergic interneuronal system.

Ambiguous respiratory neurons are modulated by GABA(A) receptor-mediated inhibition

A group of respiratory neurons in the rostral nucleus ambiguus complex is known to generate the inspiratory and expiratory drives which enable spontaneous respiration to be sustained. Since previous studies indicated that mutual synaptic inhibition is required to produce oscillations between inspiratory and expiratory neurons, it may implicate GABAergic synaptic transmission between each group of neurons. In this study we tried to determine whether most ambiguous respiratory neurons are influenced by GABA(A) receptor-mediated inhibition. Eighty-eight respiratory interneurons showing rhythmic activity in synchrony with the spontaneous respiration were recorded in urethane-chloralose anesthetized Wistar rats. Multibarrel iontophoretic application of GABA(A) antagonist bicuculline produced a remarkable facilitation in maximum burst discharge rate, whereas the agonist muscimol reversed this effect completely. Simultaneous application of GABA and bicuculline increased the discharge rate more than in any single application or in the simultaneous application of GABA and muscimol. These results were statistically significant. These findings suggest strongly that GABA(A) receptors in the ambiguous respiratory neurons may have an inhibitory role in the synaptic transmission for maintaining the respiratory oscillation in the nucleus ambiguus.