Structural and functional characterization of a muscle tendon proprioceptor in lobster
Autor: | John Simmers, Denis Combes, Maurice Moulins |
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Rok vydání: | 1995 |
Předmět: |
General Neuroscience
Stimulation Dendrites Stimulus (physiology) Biology Proprioception Biomechanical Phenomena Nephropidae Tendon Cell biology Tendons Mechanoreceptor medicine.anatomical_structure Stomatogastric nervous system medicine Animals Neurons Afferent Neuron medicine.symptom Mechanotransduction Gastrointestinal Motility Neuroscience Muscle contraction |
Zdroj: | The Journal of Comparative Neurology. 363:221-234 |
ISSN: | 1096-9861 0021-9967 |
DOI: | 10.1002/cne.903630205 |
Popis: | A morphological and electrophysiological study was made on a unique primary mechanosensory neuron, the anterior gastric receptor (AGR), previously shown to arise from powerstroke muscle gm1 of the gastric mill system in the lobster foregut. Ultrastructural analysis of horseradish peroxidase injected AGR demonstrated that its peripheral dendrites do not ramify in muscle but are confined strictly to the connective tissue/epidermal interface in the tendon of gm1. These terminals are rich in mitochondria and at their very endings are free of glial cell wrapping, suggesting that they are the site at which mechanotransduction occurs. Extracellular axonal recordings from an in vitro neuromuscular preparation consisting of the gm1 muscle still attached to the stomatogastric nervous system, revealed that AGR is activated by passive stretch of gm1. The response to ramp stimuli displays dynamic and static components, both of which increase with the amplitude of applied stretch, while the dynamic component is also velocity sensitive. AGR is also activated by muscle contraction here elicited either by application of exogenous acetyicholine, the excitatory neurotransmitter for gm 1, or by electrical stimulation of the motoneurons (GM) themselves. Consistent with a receptor lying in-series with its muscle, therefore, the effective stimulus of AGR in vivo is probably an increase in tension exerted on the tendon during active muscle contraction. In neuromuscular preparations including the bilateral commissural ganglia, stretching gm1 reflexly activates GM motoneurons at low stimulus strengths but leads to an inactivation of GM motoneurons at high stimulus strengths. This is consistent with earlier findings that both responses can be elicited by direct electrical stimulation of AGR. The functional implications of AGR's anatomical relationship with muscle gm 1, the receptor's response properties, and its central effeet8 on motor output to gm1 are discussed. Comparison is also drawn between this first reported example of a true tendon receptor in invertebrates and muscle receptors of vertebrates. © 1995 Wiley-Liss, Inc. |
Databáze: | OpenAIRE |
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