Abstract
Intracellular recordings were made from the P fibre, the smallest of the three afferent neurones innervating the thoracic-coxal muscle receptor organ of the crab (Carcinus maenas). While the two larger afferents are nonspiking, the response of the P fibre to a trapezoidal change in receptor muscle length consists of a single action potential signalling the onset of stretch superimposed on a graded amplitude receptor potential. The P fibre is sensitive to the velocity of the applied stretch, but is insensitive to static joint position, stretch amplitude and the velocity of the release phase. The presence and amplitude of the action potential depends on the initial length of the receptor muscle, the tension caused by efferent activation of the receptor muscle prior to receptor stretch, and on the velocity of stretch. Length constant (1.9 mm) and specific membrane resistance (76 KΩ · cm2) values obtained for the P fibre, together with its small diameter (7 μm) suggest that this neurone is less well adapted to conveying passive signals to the thoracic ganglion than are the S and T fibres. It is likely that the P fibre complements the length sensitivity of the S fibre and the tension and velocity sensitivity of the T fibre by signalling the onset of receptor stretch via single action potentials.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- TCMRO :
-
thoracic-coxal muscle receptor organ
- TTX :
-
tetrodotoxin
References
Alexandrowicz JS, Whitear W (1957) Receptor elements in the coxal region of decapod Crustacea. J Mar Biol Assoc UK 36: 603–628
Barrio LC, Araque A, Buño W (1994) Participation of voltage-gated conductances on the response succeeding inhibitory synaptic potentials in the crayfish slowly adapting stretch receptor neuron. J Neurophysiol 72: 1140–1151
Berger CS, Bush BMH (1979) A non-linear mechanical model of a non-spiking muscle receptor. J Exp Biol 83: 339–343
Blight AR, Llinás R (1980) The non-impulsive stretch-receptor complex of the crab: a study of depolarization-release coupling at a tonic sensorimotor synapse. Phil Trans R Soc Lond B 290: 219–276
Bush BMH (1976) Non-impulsive thoracic-coxal receptors in crustaceans. In: Mill PJ (ed) Structure and function of proprioceptors in the invertebrates. Chapman and Hall, London, pp 115–151
Bush BMH (1981) Non-impulsive stretch receptors in crustaceans. In: Roberts A, Bush BMH (eds) Neurones without impulses. Cambridge University Press, Cambridge, pp 147–176
Bush BMH, Cannone AJ (1974) A positive feed-back reflex to a crustacean muscle receptor. J Physiol (Lond) 236: 37–39P
Bush BMH, Laverack MS (1982) Mechanoreception. In: Atwood HL, Sandeman DC (eds) The biology of Crustacea, vol 3. Acdemic Press, New York, pp 399–468
Bush BMH, Roberts A (1968) Resistance reflexes from a crab muscle receptor without impulses. Nature 218: 1171–1173
Bush BMH, Roberts A (1971) Coxal muscle receptors in the crab: the receptor potentials of S and T fibres in response to ramp stretches. J Exp Biol 55: 813–832
Cannone AJ (1987) Crustacean elastic strand receptors that function without impulses. I. The depressor receptor in the shore crab, Carcinus maenas. J Comp Physiol A 160: 599–611
Cannone AJ, Bush BMH (1980a) Reflexes mediated by non-impulsive afferent neurones of thoracic-coxal muscle receptor organs in the crab, Carcinus maenas. I. Receptor potentials and promotor motoneurone responses. J Exp Biol 86: 275–303
Cannone AJ, Bush BMH (1980b) Reflexes mediated by non-impulsive afferent neurones of thoracic-coxal muscle receptor organs in the crab, Carcinus maenas. II. Reflex discharge evoked by current injection. J Exp Biol 86: 305–331
Cannone AJ, Bush BMH (1981) Reflexes mediated by non-impulsive afferent neurones of thoracic-coxal muscle receptor organs in the crab, Carcinus maenas. III. Positive feedback to the receptor muscle. J Comp Physiol 142: 103–112
Cannone AJ, Bush BMH (1982) Dual reflex motor control of non-spiking crab muscle receptor. I. Positive feedback tonically reduced and dynamically stabilized by concurrent inhibition of Rm1. J Comp Physiol 148: 365–377
Cannone AJ, Bush BMH (1983) Dual reflex motor control of non-spiking crab muscle receptor. II. Reinforcement of Rm1 mediated positive feedback by dual afferent excitation of Rm2. J Comp Physiol 153: 309–320
Cannone AJ, Nijland MJM (1989) Crustacean elastic strand receptors that function without impulses. II. The levator receptor in the shore crab, Carcinus maenas. J Comp Physiol A 165: 801–809
Crepel F, Penit-Soria J (1986) Inward rectification and low threshold calcium conductance in rat cerebellar Purkinje cells. An in vitro study. J Physiol (Lond) 372: 1–23
Davis RE, Stretton AOW (1989a) Passive membrane properties of motorneurons and their role in long-distance signaling in the nematode Ascaris. J Neurosci 9: 403–414
Davis RE, Stretton AOW (1989b) Signaling properties of Ascaris motorneurons: Graded active responses, graded synaptic transmission, and tonic transmitter release. J Neurosci 9: 415–425
Elson RC, Sillar KT, Bush BMH (1992) Identified proprioceptive afferents and motor rhythm entrainment in the crayfish walking system. J Neurophysiol 67: 530–546
Engelhardt JK, Morales FR, Castillo PE, Pedroarena C, Pose I, Chase MH (1995) Experimental analysis of the method of ‘peeling’ exponentials for measuring passive electrical properties of mammalian motoneurons. Brain Res 675: 241–248
Graubard K (1978) Synaptic transmission without action potentials: input-output properties of a non-spiking presynaptic neuron. J Neurophysiol 41: 1014–1025
Hodgkin AL, Rushton WA (1946) The electrical constants of a crustacean nerve fibre. Proc R Soc Lond B 133: 444–479
Hofmann T, Koch UT (1985) Acceleration receptors in the femoral chordotonal organ of the stick insect, Cuniculina impigra. J Exp Biol 114: 225–237
Holmes WR, Rall W (1992a) Electrotonic length estimates in neurons with dendritic tapering or somatic shunt. J Neurophysiol 68: 1421–1437
Holmes WR, Rall W (1992b) Estimating the electrotonic structure of neurons with compartmental models. J Neurophysiol 68: 1438–1452
Holmes WR, Segev I, Rall W (1992) Interpretation of time constant and electrotonic length estimates in multicylinder or branched neuronal structures. J Neurophysiol 68: 1401–1420
Hudspeth AJ, Poo MM, Stuart AE (1977) Passive signal propagation and membrane properties in median photoreceptors of the giant barnacle. J Physiol (Lond) 272: 25–43
Krauhs JM, Mirolli M (1975) Morphological changes associated with stretch in a mechano-receptor. J Neurocytol 4: 231–246
Laurent G (1990) Voltage-dependent nonlinearities in the membrane of locust nonspiking local interneurons, and their significance for synaptic integration. J Neurosci 10: 2268–2280
Lowe DA, Bush BMH, Ripley SH (1978) Pharmacological evidence for fast sodium channels in nonspiking neurones. Nature 274: 289–290
Matthews PBC (1972) Mammalian muscle receptors and their central actions. Edward Arnold, London
Mirolli M (1979) The electrical properties of a crustacean sensory dendrite. J Exp Biol 78: 1–27
Mirolli M (1981) Fast inward and outward current channels in a nonspiking neurone. Nature 292: 251–253
Mirolli M (1983) Inward and outward currents in isolated dendrites of crustacean coxal receptors. Cell Mol Neurobiol 3: 355–370
Pasztor VM, Bush BMH (1983) Graded potentials and spiking in single units of the oval organ, a mechanoreceptor in the lobster ventilatory system. I. Characteristics of dual afferent signalling. J Exp Biol 107: 431–449
Pearson KG (1976) Nerve cells without action potentials. In: Fentress JC (ed) Simpler networks and behaviour. Sinauer Associates. Sunderland Massachusetts, pp 99–110
Rall W (1969) Time constants and electrotonic length of membrane cylinders and neurons. Biophys J 9: 1483–1508
Rall W (1977) Core conductor theory and cable properties of neurons. In: Brookhart J, Mountcastle VB (eds) Handbook of physiology. The nervous system. Cellular biology of neurons, Section 1, Vol. 1. American Physiological Society, Bethseda, pp 39–97
Ripley SH, Bush BMH, Roberts A (1968) Crab muscle receptor which responds without impulses. Nature 218: 1170–1171
Roberts A, Bush BMH (1971) Coxal muscle receptors in the crab: the receptor current and some properties of the receptor nerve fibres. J Exp Biol 54: 515–524
Rudy B (1988) Diversity and ubiquity of K channels. Neuroscience 25: 729–749
Sillar KT, Skorupski P, Elson RC, Bush BMH (1986) Two identified afferent neurones entrain a central locomotor rhythm generator. Nature 323: 440–443
Whitear M (1965) The fine structure of crustacean proprioceptors. II. The thoracico-coxal organs in Carcinus, Pagurus and Astacus. Phil Trans R Soc Lond B 248: 437–456
Wildman MH, Cannone AJ (1990) Action potentials in a non-spiking neurone: graded responses and spikes in the afferent P fibre of the crab thoracic-coxal muscle receptor organ. Brain Res 509: 339–342
Wildman MH, Cannone AJ (1991) Interaction between afferent neurones in a crab muscle receptor organ. Brain Res 565: 175–178
Wildman MH, Cannone AJ (1996) Sensory feedback and central afferent interaction in the muscle receptor organ of the crab, Carcinus maenas. J Neurophysiol in press
Wilson M (1978) Generation of graded potential signals in the second order cells of locust ocellus. J Comp Physiol 124: 317–331
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Wildman, M.H., Cannone, A.J. Sensory characteristics of the P afferent neurone of the crab thoracic-coxal muscle receptor organ. J Comp Physiol A 179, 277–289 (1996). https://doi.org/10.1007/BF00222794
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00222794