Physiology of Photoreceptor Neurons in the Abdominal Nerve Cord of the Crayfish

doi:10.1085/jgp.46.3.551

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ARTICLE

Physiology of Photoreceptor Neurons in the Abdominal Nerve Cord of the Crayfish

Donald Kennedy ¹

¹ From the Department of Biological Sciences, Stanford University, Stanford

Nerve fibers which respond to illumination of the sixth abdominalganglion were isolated by fine dissection from connectives atdifferent levels in the abdominal nerve cord of the crayfish.Only a single photosensitive neuron is found in each connective;its morphological position and pattern of peripheral connectionsare quite constant from preparation to preparation. These cellsare "primary" photoreceptor elements by the following criteria:(1) production of a graded depolarization upon illuminationand (2) resetting of the sensory rhythm by interpolated antidromicimpulses. They are also secondary interneurons integrating mechanicalstimuli which originate from appendages of the tail. Volleysin ipsilateral afferent nerves produce short-latency gradedexcitatory postsynaptic potentials which initiate dischargeof one or two impulses; there is also a higher threshold inhibitorypathway of longer latency and duration. Contralateral afferentsmediate only inhibition. Both inhibitory pathways are effectiveagainst both spontaneous and evoked discharges. In the dark,spontaneous impulses arise at frequencies between 5 and 15 persecond with fairly constant intervals if afferent roots arecut. Since this discharge rhythm is reset by antidromic or orthodromicimpulses, it is concluded that an endogenous pacemaker potentialis involved. It is postulated that the increase in dischargefrequency caused by illumination increases the probability thatan inhibitory signal of peripheral origin will be detected.

Submitted on July 25, 1962

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