Intracellular recordings from spinal neurons during 'swimming' in paralysed amphibian embryos.

Intracellular microelectrode recordings have been made from probable motoneurons in the spinal cord of Xenopus laevis embryos during fictive 'swimming' in preparations paralysed with the neuromuscular blocking agent tubocurarine. These cells had resting potentials of -50 mV or more. During spontaneous or stimulus-evoked 'swimming' episodes: (a) the cells were tonically excited; the level of tonic synaptic excitation and the conductance increase underlying it were both inversely related to the 'swimming' cycle period; (b) the cells usually fired one spike per cycle in phase with the motor root burst on the same side; spikes did not overshoot zero and were evoked by phasic excitatory synaptic input on each cycle, superimposed on the tonic excitation; (c) in phase with motor root discharge on the opposite side of the body, the cells were hyperpolarized by a chloride-dependent inhibitory postsynaptic potential. The nature of synaptic potentials during 'swimming' was evaluated by means of intracellular current injections. The 'swimming' activity could be controlled by natural stimuli. The results provide clear evidence on the relation of tonic excitation to rhythmic locomotory pattern generation, and indirect evidence for reciprocal inhibitory coupling between antagonistic motor systems.

[1]  T. Brown,et al.  The Factors in Rhythmic Activity of the Nervous System , 1912 .

[2]  G. Coghill The primary ventral roots and somatic motor column of amblystoma , 1913 .

[3]  T. Brown On the nature of the fundamental activity of the nervous centres; together with an analysis of the conditioning of rhythmic activity in progression, and a theory of the evolution of function in the nervous system , 1914, The Journal of physiology.

[4]  G. E. Coghill,et al.  Anatomy and the Problem of Behaviour , 1929, Nature.

[5]  E. Holst Die relative Koordination , 1939 .

[6]  T. Araki,et al.  Response of single motoneurons to direct stimulation in toad's spinal cord. , 1955, Journal of neurophysiology.

[7]  J. Eccles,et al.  The specific ionic conductances and the ionic movements across the motoneuronal membrane that produce the inhibitory post‐synaptic potential , 1955, The Journal of physiology.

[8]  A. Hughes Studies in embryonic and larval development in Amphibia. II. The spinal motor-root. , 1959, Journal of embryology and experimental morphology.

[9]  A. Hughes Studies in embryonic and larval development in Amphibia. I. The embryology Eleutherodactylus ricordil, with special reference to the spinal cord. , 1959, Journal of embryology and experimental morphology.

[10]  J. M. Brookhart,et al.  Monosynaptic activation of different portions of the motor neuron membrane. , 1960, The American journal of physiology.

[11]  J. Eccles,et al.  Inhibitory Phasing of Neuronal Discharge , 1962, Nature.

[12]  G SZEKELY,et al.  LOGICAL NETWORK FOR CONTROLLING LIMB MOVEMENTS IN URODELA. , 1965, Acta physiologica Academiae Scientiarum Hungaricae.

[13]  F. Dodge,et al.  Co‐operative action of calcium ions in transmitter release at the neuromuscular junction , 1967, The Journal of physiology.

[14]  Donald M. Wilson The Nervous Control of Insect Flight and Related Behavior , 1968 .

[15]  B. Katz,et al.  Further study of the role of calcium in synaptic transmission , 1970, The Journal of physiology.

[16]  D. Perkel,et al.  Motor Pattern Production in Reciprocally Inhibitory Neurons Exhibiting Postinhibitory Rebound , 1974, Science.

[17]  A. Roberts,et al.  Anatomy, physiology and behavioural rôle of sensory nerve endings in the cement gland of embryonic Xenopus , 1975, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[18]  S. Grillner Locomotion in vertebrates: central mechanisms and reflex interaction. , 1975, Physiological reviews.

[19]  S. Grillner,et al.  Central Generation of Locomotion in Vertebrates , 1976 .

[20]  N. Spitzer The ionic basis of the resting potential and a slow depolarizing response in Rohon‐Beard neurones of Xenopus tadpoles. , 1976, The Journal of physiology.

[21]  P. Schwindt Electrical Properties of Spinal Motoneurons , 1976 .

[22]  Siegler Mv Motor neurone coordination and sensory modulation in the feeding system of the mollusc Pleurobranchaea californica. , 1977 .

[23]  A. Blight Golgi‐staining of “primary” and “secondary” motoneurons in the developing spinal cord of an amphibian , 1978, The Journal of comparative neurology.

[24]  W. W. Stewart,et al.  Functional connections between cells as revealed by dye-coupling with a highly fluorescent naphthalimide tracer , 1978, Cell.

[25]  W. O. Friesen,et al.  Neural circuits for generating rhythmic movements. , 1978, Annual review of biophysics and bioengineering.

[26]  A. Roberts Pineal eye and behaviour in Xenopus tadpoles , 1978, Nature.

[27]  R. M. Rose,et al.  Central generation of bursting in the feeding system of the snail, Lymnaea stagnalis. , 1979, The Journal of experimental biology.

[28]  J. Clarke,et al.  The neuroanatomy of an amphibian embryo spinal cord. , 1982, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[29]  A. Roberts,et al.  Experiments on the central pattern generator for swimming in amphibian embryos. , 1982, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[30]  A. Roberts,et al.  The central nervous origin of the swimming motor pattern in embryos of Xenopus laevis. , 1982, The Journal of experimental biology.

[31]  A. Roberts,et al.  The neuromuscular basis of swimming movements in embryos of the amphibian Xenopus laevis. , 1982, The Journal of experimental biology.