Dataset Information

Corticospinal sprouting differs according to spinal injury location and cortical origin in macaque monkeys.

ABSTRACT: The primate corticospinal tract (CST), the major descending pathway mediating voluntary hand movements, comprises nine or more functional subdivisions. The role of subcomponents other than that from primary motor cortex, however, is not well understood. We have previously shown that following a cervical dorsal rhizotomy (Darian-Smith et al., 2013), CST projections originating from primary somatosensory (S1) and motor (M1) cortex responded quite differently to injury. Terminal projections from the S1 (areas 3b/1/2) shrank to <60% of the contralateral side, while M1 CST projections remained robust or expanded (>110%). Here, we asked what happens when a central lesion is added to the equation, to better simulate clinical injury. Monkeys (n = 6) received either a unilateral (1) dorsal root lesion (DRL), (2) or a combined DRL/dorsal column lesion (DRL/DCL), or (3) a DRL/DCL where the DCL was made 4 months following the initial DRL. Electrophysiological recordings were made in S1 4 months postlesion in the first two groups, and 6 weeks after the DCL in the third lesion group, to identify the reorganized region of D1-D3 (thumb, index finger, and middle finger) representation. Anterograde tracers were then injected bilaterally to assess spinal terminal labeling. Remarkably, in all DRL/DCL animals, terminal projections from the S1 and M1 extended bilaterally and caudally well beyond terminal territories in normal animals or following a DRL. These data were highly significant. Extensive sprouting from the S1 CST has not been reported previously, and these data raise important questions about S1 CST involvement in recovery following spinal injury.

SUBMITTER: Darian-Smith C

PROVIDER: S-EPMC4160766 | biostudies-literature | 2014 Sep

REPOSITORIES: biostudies-literature

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Corticospinal sprouting differs according to spinal injury location and cortical origin in macaque monkeys.

Darian-Smith Corinna C Lilak Alayna A Garner Joseph J Irvine Karen-Amanda KA

The Journal of neuroscience : the official journal of the Society for Neuroscience 20140901 37

The primate corticospinal tract (CST), the major descending pathway mediating voluntary hand movements, comprises nine or more functional subdivisions. The role of subcomponents other than that from primary motor cortex, however, is not well understood. We have previously shown that following a cervical dorsal rhizotomy (Darian-Smith et al., 2013), CST projections originating from primary somatosensory (S1) and motor (M1) cortex responded quite differently to injury. Terminal projections from th ...[more]

PMID: 25209269

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Project description:Depending on the severity of a CNS injury, in humans as well as in experimental animal models certain degrees of functional recovery are observed. Rodent studies have provided much evidence for underlying anatomical changes involving neurite outgrowth of both spared and axotomized fiber tracts, also referred to as sprouting. Following a thoracic spinal cord injury (SCI) in adult rats, axotomized fibers of the hindlimb corticospinal tract (CST) were found to sprout into the cervical spinal cord at different rostrocaudal levels. Anterograde tracings showed that these new collaterals of motor cortical hindlimb fibers project into the intermediate laminae of the cervical grey matter, particularly pronounced at the level of cervical segment three (C3). The molecular cues which induce the growth and guide these sprouts of hindlimb CST fibers are unknown. We hypothesize that sectreted factors and guidance and adhesion molecules are specifically expressed in the intermediate laminae of the cervical spinal cord to direct and target the ingrowth of the sprouting hindlimb CST fibers. To test our hypothesis the transcription profile of the target region of sprouts was investigated with RNA sequencing of total RNA extracted from the intermediate laminae (IV-VII) of the spinal gray matter at cervical level C3. Four major comparisons were performed, which were then again compared to each other. The first comparison was between samples of animals with an SCI sacrificed at four different time points after injury (1, 3, 6, 12 weeks after injury). The second and third comparison was between samples of rats with a SCI compared to their sham controls sacrificed at the same time point after surgery (1 week or 12 weeks respectively). The fourth comparison was between samples from animals of the two control groups, rats with a sham surgery which were either sacrificed at one or at twelve weeks after injury. We found that most changes in gene expression ocurred at one week after SCI and least changes occured at twelve weeks after SCI, suggesting that the largest effects on a global level of gene expression occur during early time points after injury. Interestingly, also we also found changes in gene expression when comparing the samples from the two control groups, which suggests that sham surgery consisting of a laminectomy is sufficient to induce transcriptional changes in the spinal cord. This is the first study to provide insight into transcriptional changes in the target region of sprouts investigating the role of the cervical spinal cord (target region) for sprouting of hindlimb CST fibers.

Dataset Information

Corticospinal sprouting differs according to spinal injury location and cortical origin in macaque monkeys.

Publications

Corticospinal sprouting differs according to spinal injury location and cortical origin in macaque monkeys.

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