Partly shared spinal cord networks for locomotion and scratching.

Animals produce a variety of behaviors using a limited number of muscles and motor neurons. Rhythmic behaviors are often generated in basic form by networks of neurons within the central nervous system, or central pattern generators (CPGs). It is known from several invertebrates that different rhythmic behaviors involving the same muscles and motor neurons can be generated by a single CPG, multiple separate CPGs, or partly overlapping CPGs. Much less is known about how vertebrates generate multiple, rhythmic behaviors involving the same muscles. The spinal cord of limbed vertebrates contains CPGs for locomotion and multiple forms of scratching. We investigated the extent of sharing of CPGs for hind limb locomotion and for scratching. We used the spinal cord of adult red-eared turtles. Animals were immobilized to remove movement-related sensory feedback and were spinally transected to remove input from the brain. We took two approaches. First, we monitored individual spinal cord interneurons (i.e., neurons that are in between sensory neurons and motor neurons) during generation of each kind of rhythmic output of motor neurons (i.e., each motor pattern). Many spinal cord interneurons were rhythmically activated during the motor patterns for forward swimming and all three forms of scratching. Some of these scratch/swim interneurons had physiological and morphological properties consistent with their playing a role in the generation of motor patterns for all of these rhythmic behaviors. Other spinal cord interneurons, however, were rhythmically activated during scratching motor patterns but inhibited during swimming motor patterns. Thus, locomotion and scratching may be generated by partly shared spinal cord CPGs. Second, we delivered swim-evoking and scratch-evoking stimuli simultaneously and monitored the resulting motor patterns. Simultaneous stimulation could cause interactions of scratch inputs with subthreshold swim inputs to produce normal swimming, acceleration of the swimming rhythm, scratch-swim hybrid cycles, or complete cessation of the rhythm. The type of effect obtained depended on the level of swim-evoking stimulation. These effects suggest that swim-evoking and scratch-evoking inputs can interact strongly in the spinal cord to modify the rhythm and pattern of motor output. Collectively, the single-neuron recordings and the results of simultaneous stimulation suggest that important elements of the generation of rhythms and patterns are shared between locomotion and scratching in limbed vertebrates.

[1]  Jonathan E Rubin,et al.  Strong interactions between spinal cord networks for locomotion and scratching. , 2011, Journal of neurophysiology.

[2]  J. Nielsen,et al.  Reciprocal Ia inhibition contributes to motoneuronal hyperpolarisation during the inactive phase of locomotion and scratching in the cat , 2011, The Journal of physiology.

[3]  Chie Satou,et al.  Functional role of a specialized class of spinal commissural inhibitory neurons during fast escapes in zebrafish , 2009, Neuroscience Research.

[4]  J. Fetcho,et al.  Shared versus Specialized Glycinergic Spinal Interneurons in Axial Motor Circuits of Larval Zebrafish , 2008, The Journal of Neuroscience.

[5]  Kevin L. Briggman,et al.  Multifunctional pattern-generating circuits. , 2008, Annual review of neuroscience.

[6]  Ari Berkowitz,et al.  Physiology and morphology of shared and specialized spinal interneurons for locomotion and scratching. , 2008, Journal of neurophysiology.

[7]  D. McCrea,et al.  Organization of mammalian locomotor rhythm and pattern generation , 2008, Brain Research Reviews.

[8]  A. Roberts,et al.  Reconfiguration of a Vertebrate Motor Network: Specific Neuron Recruitment and Context-Dependent Synaptic Plasticity , 2007, The Journal of Neuroscience.

[9]  K. Nakazawa,et al.  Multifunctional Laryngeal Premotor Neurons: Their Activities during Breathing, Coughing, Sneezing, and Swallowing , 2007, The Journal of Neuroscience.

[10]  A. Berkowitz Spinal Interneurons That Are Selectively Activated during Fictive Flexion Reflex , 2007, The Journal of Neuroscience.

[11]  D. McCrea,et al.  Modelling spinal circuitry involved in locomotor pattern generation: insights from deletions during fictive locomotion , 2006, The Journal of physiology.

[12]  Kevin L. Briggman,et al.  Imaging Dedicated and Multifunctional Neural Circuits Generating Distinct Behaviors , 2006, The Journal of Neuroscience.

[13]  A. Berkowitz,et al.  Somato-dendritic morphology predicts physiology for neurons that contribute to several kinds of limb movements. , 2006, Journal of neurophysiology.

[14]  A. Berkowitz Physiology and morphology indicate that individual spinal interneurons contribute to diverse limb movements. , 2005, Journal of neurophysiology.

[15]  P. Stein Neuronal control of turtle hindlimb motor rhythms , 2005, Journal of Comparative Physiology A.

[16]  P. Lutz,et al.  Negotiating brain anoxia survival in the turtle , 2004, Journal of Experimental Biology.

[17]  J. Jing,et al.  The Construction of Movement with Behavior-Specific and Behavior-Independent Modules , 2004, The Journal of Neuroscience.

[18]  William B Kristan,et al.  Evidence for Sequential Decision Making in the Medicinal Leech , 2002, The Journal of Neuroscience.

[19]  P. Stein,et al.  Modular Organization of Turtle Spinal Interneurons during Normal and Deletion Fictive Rostral Scratching , 2002, The Journal of Neuroscience.

[20]  A. Berkowitz Both shared and specialized spinal circuitry for scratching and swimming in turtles , 2002, Journal of Comparative Physiology A.

[21]  Irving Kupfermann,et al.  Motor program selection in simple model systems , 2001, Current Opinion in Neurobiology.

[22]  E. Marder,et al.  Central pattern generators and the control of rhythmic movements , 2001, Current Biology.

[23]  J. Fetcho,et al.  In Vivo Imaging of Zebrafish Reveals Differences in the Spinal Networks for Escape and Swimming Movements , 2001, The Journal of Neuroscience.

[24]  J. Jing,et al.  Neural Mechanisms of Motor Program Switching inAplysia , 2001, The Journal of Neuroscience.

[25]  A. Berkowitz Rhythmicity of spinal neurons activated during each form of fictive scratching in spinal turtles. , 2001, Journal of neurophysiology.

[26]  A. Berkowitz,et al.  Broadly tuned spinal neurons for each form of fictive scratching in spinal turtles. , 2001, Journal of neurophysiology.

[27]  J. Ramirez,et al.  Reconfiguration of the neural network controlling multiple breathing patterns: eupnea, sighs and gasps , 2000, Nature Neuroscience.

[28]  J. Jing,et al.  Escape swim network interneurons have diverse roles in behavioral switching and putative arousal in Pleurobranchaea. , 2000, Journal of neurophysiology.

[29]  E Marder,et al.  Coordination of Fast and Slow Rhythmic Neuronal Circuits , 1999, The Journal of Neuroscience.

[30]  W. Kristan,et al.  Behavioral hierarchy in the medicinal leech, Hirudo medicinalis: feeding as a dominant behavior , 1998, Behavioural Brain Research.

[31]  M. P. Nusbaum,et al.  Intercircuit Control of Motor Pattern Modulation by Presynaptic Inhibition , 1997, The Journal of Neuroscience.

[32]  Brian K. Shaw,et al.  The Neuronal Basis of the Behavioral Choice between Swimming and Shortening in the Leech: Control Is Not Selectively Exercised at Higher Circuit Levels , 1997, The Journal of Neuroscience.

[33]  E. Marder,et al.  Principles of rhythmic motor pattern generation. , 1996, Physiological reviews.

[34]  K R Svoboda,et al.  Interactions between the neural networks for escape and swimming in goldfish , 1996, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[35]  P. S. Dickinson,et al.  Interactions among neural networks for behavior , 1995, Current Opinion in Neurobiology.

[36]  J. Jing,et al.  Neuronal elements that mediate escape swimming and suppress feeding behavior in the predatory sea slug Pleurobranchaea. , 1995, Journal of neurophysiology.

[37]  A. Selverston Modulation of circuits underlying rhythmic behaviors , 1995, Journal of Comparative Physiology A.

[38]  H. Chiel,et al.  Neural architectures for adaptive behavior , 1994, Trends in Neurosciences.

[39]  E. Marder,et al.  Switching neurons are integral members of multiple oscillatory networks , 1994, Current Biology.

[40]  P. Stein,et al.  Activity of descending propriospinal axons in the turtle hindlimb enlargement during two forms of fictive scratching: broad tuning to regions of the body surface , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[41]  A. Berkowitz,et al.  Activity of descending propriospinal axons in the turtle hindlimb enlargement during two forms of fictive scratching: phase analyses , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[42]  S. Soffe,et al.  Two distinct rhythmic motor patterns are driven by common premotor and motor neurons in a simple vertebrate spinal cord , 1993, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[43]  M. Moulins,et al.  Construction of a pattern-generating circuit with neurons of different networks , 1991, Nature.

[44]  R. M. Hennig Neuronal control of the forewings in two different behaviours: Stridulation and flight in the cricket, Teleogryllus commodus , 1990, Journal of Comparative Physiology A.

[45]  P. Stein,et al.  Spinal cord segments containing key elements of the central pattern generators for three forms of scratch reflex in the turtle , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[46]  Charles F. Stevens Neural Control of Rhythmic Movements in Vertebrates , 1989 .

[47]  P. Stein,et al.  Interruptions of fictive scratch motor rhythms by activation of cutaneous flexion reflex afferents in the turtle , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[48]  P. Stein,et al.  Electrical activation of the pocket scratch central pattern generator in the turtle. , 1988, Journal of neurophysiology.

[49]  K G Pearson,et al.  Generation of motor patterns for walking and flight in motoneurons supplying bifunctional muscles in the locust. , 1988, Journal of neurobiology.

[50]  G. A. Robertson,et al.  Blends of rostral and caudal scratch reflex motor patterns elicited by simultaneous stimulation of two sites in the spinal turtle , 1986, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[51]  J L Smith,et al.  Simultaneous control of two rhythmical behaviors. II. Hindlimb walking with paw-shake response in spinal cat. , 1986, Journal of neurophysiology.

[52]  J L Smith,et al.  Simultaneous control of two rhythmical behaviors. I. Locomotion with paw-shake response in normal cat. , 1986, Journal of neurophysiology.

[53]  Allen I. Selverston,et al.  Model Neural Networks and Behavior , 1985, Springer US.

[54]  G. A. Robertson,et al.  Three forms of the scratch reflex in the spinal turtle: central generation of motor patterns. , 1985, Journal of neurophysiology.

[55]  P. Stein,et al.  Three forms of the scratch reflex in the spinal turtle: movement analyses. , 1985, Journal of neurophysiology.

[56]  G. A. Robertson,et al.  Motor neuron synaptic potentials during fictive scratch reflex in turtle , 1982, Journal of comparative physiology.

[57]  Paul S. G. Stein,et al.  Central program for scratch reflex in turtle , 1980, Journal of comparative physiology.

[58]  C. Pratt,et al.  Renshaw cell activity and recurrent effects on motoneurons during fictive locomotion. , 1980, Journal of neurophysiology.

[59]  G. Orlovsky,et al.  Activity of Ia inhibitory interneurons during fictitious scratch reflex in the cat , 1980, Brain Research.

[60]  I. Gelfand,et al.  Generation of scratching. II. Nonregular regimes of generation. , 1978, Journal of neurophysiology.

[61]  P. R. Lennard,et al.  Swimming movements elicited by electrical stimulation of turtle spinal cord. I. Low-spinal and intact preparations. , 1977, Journal of neurophysiology.

[62]  G. Orlovsky,et al.  Activity of interneurons mediating reciprocal 1a inhibition during locomotion , 1975, Brain Research.

[63]  T. Brown STUDIES IN THE PHYSIOLOGY OF THE NERVOUS SYSTEM. XXVI.: ON THE PHENOMENON OF FACILITATION. 5: ADDITIONAL NOTE ON “SECONDARY FACILITATION” IN THE CORTICAL MOTOR MECHANISM IN MONKEYS , 1916 .

[64]  T. Brown STUDIES IN THE PHYSIOLOGY OF THE NERVOUS SYSTEM. VII.: MOVEMENTS UNDER NARCOSIS IN THE PIGEON. MOVEMENTS UNDER NARCOSIS IN THE RABBIT‐PROGRESSION — SCRATCHING — FLEXION , 1911 .

[65]  T. G. Deliagina,et al.  Activity of renshaw cells during fictive scratch reflex in the cat , 2004, Experimental Brain Research.

[66]  S. Currie,et al.  Right Left Hindlimb Alternation During Turtle Swimming Crossed Commissural Pathways in the Spinal Hindlimb Enlargement Are Not Necessary , 2000 .

[67]  P. Stein,et al.  Scratch-swim hybrids in the spinal turtle: blending of rostral scratch and forward swim. , 2000, Journal of neurophysiology.

[68]  K. Pearson Common principles of motor control in vertebrates and invertebrates. , 1993, Annual review of neuroscience.

[69]  C. Mccrohan,et al.  Motor programme selection and the control of feeding in the snail , 1992 .

[70]  E. Marder,et al.  1 – Modulatory control of multiple task processing in the stomatogastric nervous system , 1992 .

[71]  R. Harris-Warrick In: Dynamic Biological Networks: The Stomatogastric Nervous System , 1992 .

[72]  Stephen R Soffe,et al.  Neurobiology of Motor Programme Selection , 1992 .

[73]  E. Marder,et al.  Neurons that form multiple pattern generators: identification and multiple activity patterns of gastric/pyloric neurons in the crab stomatogastric system. , 1991, Journal of neurophysiology.

[74]  H. Jahnsen Preparations of vertebrate central nervous system in vitro , 1990 .

[75]  C. Pratt,et al.  Ia inhibitory interneurons and Renshaw cells as contributors to the spinal mechanisms of fictive locomotion. , 1987, Journal of neurophysiology.

[76]  W. J. Heitler,et al.  Motor programme switching in the crayfish swimmeret system. , 1985, The Journal of experimental biology.

[77]  Ari Berkowitz,et al.  Annals of the New York Academy of Sciences Multifunctional and Specialized Spinal Interneurons for Turtle Limb Movements , 2022 .