Abstract
The motor cortex represents muscle and joint control and projects to spinal cord interneurons and–in many primates, including humans–motoneurons, via the corticospinal tract (CST). To examine these spinal CST anatomical mechanisms, we determined if motor cortex sites controlling individual forelimb joints project differentially to distinct cervical spinal cord territories, defined regionally and by the locations of putative last-order interneurons that were transneuronally labeled by intramuscular injection of pseudorabies virus. Motor cortex joint-specific sites were identified using intracortical-microstimulation. CST segmental termination fields from joint-specific sites, determined using anterograde tracers, comprised a high density core of terminations that was consistent between animals and a surrounding lower density projection that was more variable. Core terminations from shoulder, elbow, and wrist control sites overlapped in the medial dorsal horn and intermediate zone at C5/C6 but were separated at C7/C8. Shoulder sites preferentially terminated dorsally, in the dorsal horn; wrist/digit sites, more ventrally in the intermediate zone; and elbow sites, medially in the dorsal horn and intermediate zone. Pseudorabies virus injected in shoulder, elbow, or wrist muscles labeled overlapping populations of predominantly muscle-specific putative premotor interneurons, at a survival time for disynaptic transfer from muscle. At C5/C6, CST core projections from all joint zones were located medial to regions of densely labeled last-order interneurons, irrespective of injected muscle. At C7/C8 wrist CST core projections overlapped the densest interneuron territory, which was located in the lateral intermediate zone. In contrast, elbow CST core projections were located medial to the densest interneuron territories, and shoulder CST core projections were located dorsally and only partially overlapped the densest interneuron territory. Our findings show a surprising fractionation of CST terminations in the caudal cervical enlargement that may be organized to engage different spinal premotor circuits for distal and proximal joint control.
Highlights
The corticospinal tract (CST) provides a direct path for the motor cortex to spinal motor circuits
We used intracortical microstimulation (ICMS) to map the representations of contralateral forelimb joints in order to target anterograde axon tracer injections for mapping the CST spinal terminations of identified joint-specific zones
We compared the distributions of the joint-specific CST terminations with the locations of proprioceptive afferents using Cholera toxin b subunit (CTb) and putative last-order interneurons, using retrograde transneuronal labeling of pseudorabies virus (PRV) in adult mice at a survival time that ensured transport across only one spinal cord synapse
Summary
The corticospinal tract (CST) provides a direct path for the motor cortex to spinal motor circuits. We learned of the predominance of the motor cortex muscle and joint representation; the familiar homunculus in humans [1]. This has been reinforced using intracortical microstimulation (ICMS) for fine-grained mapping of the motor cortex in animals [2]. Possible functions of corticomotoneuronal cells [6,7] in individuated muscle control can be inferred by their direct connections. While we have an understanding of the diverse physiological actions of the CST on spinal interneuronal systems [8,9,10], and a growing inventory of CST-to-interneuron projections [11], we have little insight into the possible functional organization of these connections
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