Locomotor Modulation of Disynaptic EPSPs From the Mesencephalic Locomotor Region in Cat Motoneurons

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Locomotor Modulation of Disynaptic EPSPs From the Mesencephalic Locomotor Region in Cat Motoneurons

A. M. Degtyarenko, E. S. Simon, and R. E. Burke

Laboratory of Neural Control, National Institute of Neurological Disorders and Stroke, National Institutes of Health, Bethesda, Maryland 20892-4455

Degtyarenko, A. M., E. S. Simon, and R. E. Burke. Locomotor modulation of disynaptic EPSPs from the mesencephalic locomotorregion in cat motoneurons. J. Neurophysiol. 80: 3284-3296, 1998.When low-frequency tetanization of the mesencephalic locomotorregion (MLR) produce fictive locomotion in unanesthetized, decerebratecats, each MLR stimulus produces a distinctive cord dorsum potential(CDP) and oligosynaptic excitatory postsynaptic potentials (EPSPs)in many lumbosacral motoneurons. The average segmental latencyfrom the initial CDP wave [mean delay from stimulus: 4.3 ± 0.9(SD) ms] to the onset of detectable MLR EPSPs was 1.6 ± 0.4 ms,suggesting a disynaptic segmental connection. In gastrocnemius/soleus,flexor hallucis longus, flexor digitorum longus, tibialis anterior,and posterior biceps-semitendinosus motoneurons (35/38 cells),MLR EPSPs either appeared or were enhanced during the phase offictive stepping in which the target motoneurons were depolarizedand the motor pool was active (the ON phase), with parallel changesbetween EPSP amplitudes and membrane depolarization. In contrast,MLR stimulation produced small (1/10) or no EPSPs in extensordigitorum longus (EDL) motoneurons, with no ON phase enhancement(4/10) or oligosynaptic inhibitory postsynaptic potentials duringthe ON phase (5/10). Eight of 10 flexor digitorum longus (FDL)cells exhibited membrane depolarization in the early flexion phaseof fictive stepping, and five of these showed parallel enhancementof disynaptic MLR EPSPs during early flexion. Three cases werestudied when the FDL motor pool exhibited exclusively extensorphase firing. In these cases, the disynaptic MLR EPSPs were enhancedonly during the extensor phase, accompanied by membrane depolarizations.We conclude that the last-order interneurons that produce disynapticMLR EPSPs may well participate in producing the depolarizing locomotordrive potentials (LDPs) found in hindlimb motoneurons during fictivelocomotion. However, the absence of linkage between MLR EPSP enhancementand LDP depolarizations in EDL motoneurons suggests that othertypes of excitatory interneurons also must be involved at leastin some motor pools. We compared these patterns with the modulationof disynaptic EPSPs produced in FDL cells by stimulation of themedial longitudinal fasciculus (MLF). In all seven FDL motoneuronstested, disynaptic MLF EPSPs appeared only during the extensionphase, regardless of when the FDL motoneurons were active. Thefact that the modulation patterns of MLR and MLF disynaptic EPSPsis different in FDL motoneurons indicates that the two pathwaysdo not converge on common last-order interneurons to that motorpool.

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