Evidence for glutamatergic mechanisms in the vagal sensory pathway initiating cardiorespiratory reflexes in the shorthorn sculpin Myoxocephalus scorpius

doi:10.1242/jeb.00179

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The Journal of Experimental Biology 206, 867-876 (2003)
doi: 10.1242/jeb.00179

Evidence for glutamatergic mechanisms in the vagal sensory pathway initiating cardiorespiratory reflexes in the shorthorn sculpin Myoxocephalus scorpius

L. Sundin¹^,*, J. Turesson¹ and E. W. Taylor²

^¹ Department of Zoology, Göteborg University, Box 463, S-40530 Gothenburg, Sweden
^² School of Biosciences, University of Birmingham, Edgbaston, Birmingham, B15 2TT, UK

^{^*} Author for correspondence (e-mail: lena.sundin{at}zool.gu.se)

Accepted 25 November 2002

Glutamate is a major neurotransmitter of chemoreceptor and baroreceptor afferentpathways in mammals and therefore plays a central role in the developmentof cardiorespiratory reflexes. In fish, the gills are the major sitesof these receptors, and, consequently, the terminal field (sensoryarea) of their afferents (glossopharyngus and vagus) in themedulla must be an important site for the integration of chemoreceptorand baroreceptor signals. This investigation explored whetherfish have glutamatergic mechanisms in the vagal sensory area(Xs) that could be involved in the generation of cardiorespiratoryreflexes.

The locations of the vagal sensory and motor (Xm) areas in themedulla were established by the orthograde and retrograde axonaltransport of the neural tract tracer Fast Blue following itsinjection into the ganglion nodosum. Glutamate was then microinjectedinto identified sites within the Xs in an attempt to mimic chemoreceptor-and baroreceptor-induced reflexes commonly observed in fish.By necessity, the brain injections were performed on anaesthetisedanimals that were fixed by `eye bars' in a recirculating water system.Blood pressure and heart rate were measured using an arterialcannula positioned in the afferent branchial artery of the 3rdgill arch, and ventilation was measured by impedance probessutured onto the operculum.

Unilateral injection of glutamate (40-100 nl, 10 mmol l^-1) into theXs caused marked cardiorespiratory changes. Injection (0.1-0.3mm deep) in different rostrocaudal, medial-lateral positionsinduced a bradycardia, either increased or decreased blood pressure,ventilation frequency and amplitude and, sometimes, an initialapnea. Often these responses occurred simultaneously in variousdifferent combinations but, occasionally, they appeared singly,suggesting specific projections into the Xs for each cardiorespiratoryvariable and local determination of the modality of the response.Response patterns related to chemoreceptor reflex activationwere predominantly located rostral of obex, whereas patternsrelated to baroreceptor reflex activation were more caudal,around obex.

The glutamate-induced bradycardia was N-methyl-D-aspartate (NMDA) receptordependent and atropine sensitive. Taken together, our data provide evidencethat glutamate is a putative player in the central integrationof chemoreceptor and baroreceptor information in fish.

Key words: fish, vagus, reflex control, ventilation, bradycardia, blood pressure, glutamate, NMDA, chemoreceptor, baroreceptor

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