The direction change concept for reticulospinal control of goldfish escape

This is an analysis of whether biomechanical or kinematic variables are controlled by descending reticulospinal commands to the spinal cord during escape responses (C-starts) in the goldfish. We studied how the animal contracted its trunk musculature to orient an escape trajectory. We used trunk EMG recordings as a measure of the reticulospinal output to the musculature and we simultaneously gathered high-speed cinematic records of the resulting movements. We found that the escape trajectory is controlled by (1) the relative size of the agonist versus the antagonist muscle contractions on two sides of the body and (2) the timing between these contractions. We found no separate signal for forward propulsion (or force) apart from the initial stage 1 bending of the body. Rather, the neural specification of force is embedded in the commands to bend the body. Thus, our findings demonstrate the importance of the angular kinematic components, or direction changes, caused by the descending reticulospinal command. This new direction change concept is important for two reasons. First, it unifies the diversity of C-start movement patterns into a single and rather simple quantitative model. Second, the model is analogous to the systematic EMG and kinematic changes observed by others to underlie single joint movements of limbs in other vertebrates such as primates. As in these cases, the fish capitalizes on the mechanical properties of the muscle by setting the extent and timing of agonist and antagonist contractions. This, plus the fact that sensory feedback is likely to be minimal, may enable the animal to reduce the number of computational steps in its motor commands used to produce the escape response. Because horizontal body movements in fish are a fundamental vertebrate movement pattern produced by a highly conserved brainstem movement system, our findings may have general implications for understanding the neural basis of rapid movements of diverse body parts.

[1]  Robert C. Eaton,et al.  The motor output of the Mauthner cell, a reticulospinal command neuron , 1990, Brain Research.

[2]  S. A. Wallace,et al.  An impulse-timing theory for reciprocal control of muscular activity in rapid, discrete movements. , 1981, Journal of motor behavior.

[3]  I. Golani A mobility gradient in the organization of vertebrate movement: The perception of movement through symbolic language , 1992, Behavioral and Brain Sciences.

[4]  J Nissanov,et al.  Role of the Mauthner cell in sensorimotor integration by the brain stem escape network. , 1991, Brain, behavior and evolution.

[5]  J. Fetcho,et al.  Spinal network of the Mauthner cell. , 1991, Brain, behavior and evolution.

[6]  P. Gruss Murine development control genes , 1989 .

[7]  P. Thompson Electromyography for Experimentalists , 1987 .

[8]  E. Evarts Pyramidal tract activity associated with a conditioned hand movement in the monkey. , 1966, Journal of neurophysiology.

[9]  D. Weihs,et al.  Optimal avoidance and evasion tactics in predator-prey interactions , 1984 .

[10]  G. Loeb,et al.  Electromyography for Experimentalists , 1986 .

[11]  R. C. Eaton,et al.  How stimulus direction determines the trajectory of the Mauthner-initiated escape response in a teleost fish. , 1991, The Journal of experimental biology.

[12]  J. Fetcho Spinal Network of the Mauthner Cell (Part 1 of 2) , 1991 .

[13]  R. Krumlauf,et al.  Segmental expression of Hox-2 homoeobox-containing genes in the developing mouse hindbrain , 1989, Nature.

[14]  D E Sherwood,et al.  Rapid movements with reversals in direction. I. The control of movement time. , 1988, Experimental brain research.

[15]  P. Gruss,et al.  Murine developmental control genes. , 1990, Science.

[16]  S. Rossignol,et al.  LOCOMOTION IN LAMPREY AND TROUT: THE RELATIVE TIMING OF ACTIVATION AND MOVEMENT , 1989 .

[17]  A. Bekoff Neuroethological approaches to the study of motor development in chicks: achievements and challenges. , 1992, Journal of neurobiology.

[18]  S. A. Wallace,et al.  EMG area scaling and velocity modulations in a spatiotemporally constrained movement. , 1991, Journal of electromyography and kinesiology : official journal of the International Society of Electrophysiological Kinesiology.

[19]  E. Bizzi,et al.  Geometrical and mechanical issues in movement planning and control , 1989 .

[20]  R. C. Eaton,et al.  Role of the Teleost Escape Response during Development , 1986 .

[21]  L C Rome,et al.  Myofilament overlap in swimming carp. II. Sarcomere length changes during swimming. , 1991, The American journal of physiology.

[22]  Barry W Peterson,et al.  2 – The Reticulospinal System and Its Role in the Control of Movement , 1984 .

[23]  Richard B. Stein,et al.  What muscle variable(s) does the nervous system control in limb movements? , 1982, Behavioral and Brain Sciences.

[24]  Henri Korn,et al.  Role of medullary networks and postsynaptic membrane properties in regulating Mauthner cell responsiveness to sensory excitation. , 1991, Brain, behavior and evolution.

[25]  R. C. Eaton,et al.  Segmental arrangement of reticulospinal neurons in the goldfish hindbrain , 1993, The Journal of comparative neurology.

[26]  D E Sherwood,et al.  Rapid movements with reversals in direction. II. Control of movement amplitude and inertial load. , 1988, Experimental brain research.

[27]  Robert W. Blake,et al.  Fast-Start Performance of Rainbow Trout Salmo Gairdneri and Northern Pike Esox Lucius , 1990 .

[28]  Robert C. Eaton,et al.  Reticulospinal Control of Rapid Escape Turning Maneuvers in Fishes , 1989 .

[29]  S. Zottoli,et al.  Correlation of the startle reflex and Mauthner cell auditory responses in unrestrained goldfish. , 1977, The Journal of experimental biology.

[30]  E. Bizzi,et al.  Processes controlling arm movements in monkeys. , 1978, Science.

[31]  A. G. Feldman Once More on the Equilibrium-Point Hypothesis (λ Model) for Motor Control , 1986 .

[32]  M. J. Noruésis,et al.  SPSS-X advanced statistics guide , 1985 .

[33]  J Nissanov,et al.  Flexible body dynamics of the goldfish C-start: implications for reticulospinal command mechanisms , 1988, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[34]  Paul W. Webb,et al.  Fast-start Performance and Body Form in Seven Species of Teleost Fish , 1978 .

[35]  R. Keynes,et al.  Segmental patterns of neuronal development in the chick hindbrain , 1989, Nature.

[36]  P. Wainwright Prey Processing in Haemulid Fishes: Patterns of Variation in Pharyngeal Jaw Muscle Activity , 1989 .

[37]  A. McClellan Command Systems for Initiating Locomotion in Fish and Amphibians: Parallels to Initiation Systems in Mammals , 1986 .

[38]  E. Fetz Movement control: Are movement parameters recognizably coded in the activity of single neurons? , 1992 .

[39]  G. Gottlieb,et al.  Strategies for the control of voluntary movements with one mechanical degree of freedom , 1989, Behavioral and Brain Sciences.

[40]  R. C. Eaton Eshkol-Wachman movement notation and the evolution of locomotor patterns in vertebrates , 1992, Behavioral and Brain Sciences.

[41]  P. Webb,et al.  Strike tactics of Esox. , 1980, Canadian journal of zoology.