Gene/Protein
Disease
Symptom
Drug
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Pivot Concepts:
Gene/Protein
Disease
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Target Concepts:
Gene/Protein
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Query: UMLS:C0026838 (
spasticity
)
6,471
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Spinal cord injury leads to severe problems involving impaired motor, sensory, and autonomic functions. After spinal injury there is an initial phase of hyporeflexia followed by hyperreflexia, often referred to as
spasticity
. Previous studies have suggested a relationship between the reappearance of endogenous plateau potentials in motor neurons and the development of
spasticity
after spinalization. To unravel the molecular mechanisms underlying the increased excitability of motor neurons and the return of plateau potentials below a spinal cord injury we investigated changes in gene expression in this cell population. We adopted a rat tail-
spasticity
model with a caudal spinal transection that causes a progressive development of
spasticity
from its onset after 2 to 3 wk until 2 mo postinjury. Gene expression changes of fluorescently identified tail motor neurons were studied 21 and 60 days postinjury. The motor neurons undergo substantial transcriptional regulation in response to injury. The patterns of differential expression show similarities at both time points, although there are 20% more differentially expressed genes 60 days compared with 21 days postinjury. The study identifies targets of regulation relating to both ion channels and receptors implicated in the endogenous expression of plateaux. The regulation of excitatory and inhibitory signal transduction indicates a shift in the balance toward increased excitability, where the glutamatergic N-methyl-d-aspartate receptor complex together with cholinergic system is up-regulated and the gamma-aminobutyric acid type A receptor system is down-regulated. The genes of the pore-forming proteins Cav1.3 and
Nav1.6
were not up-regulated, whereas genes of proteins such as nonpore-forming subunits and intracellular pathways known to modulate receptor and channel trafficking, kinetics, and conductivity showed marked regulation. On the basis of the identified changes in global gene expression in motor neurons, the present investigation opens up for new potential targets for treatment of motor dysfunction following spinal cord injury.
...
PMID:Global gene expression analysis of rodent motor neurons following spinal cord injury associates molecular mechanisms with development of postinjury spasticity. 1993 61
Upregulation of the persistent sodium current (I(NaP)) in motoneurons contributes to the development of
spasticity
after spinal cord injury (SCI). We investigated the mechanisms that regulate I(NaP) and observed elevated expression of voltage-gated sodium (Nav) 1.6 channels in spinal lumbar motoneurons of adult rats with SCI. Furthermore, immunoblots revealed a proteolysis of Nav channels, and biochemical assays identified calpain as the main proteolytic factor. Calpain-dependent cleavage of Nav channels after neonatal SCI was associated with an upregulation of I(NaP) in motoneurons. Similarly, the calpain-dependent cleavage of
Nav1.6
channels expressed in human embryonic kidney (HEK) 293 cells caused the upregulation of I(NaP). The pharmacological inhibition of calpain activity by MDL28170 reduced the cleavage of Nav channels, I(NaP) in motoneurons and
spasticity
in rats with SCI. Similarly, the blockade of I(NaP) by riluzole alleviated
spasticity
. This study demonstrates that Nav channel expression in lumbar motoneurons is altered after SCI, and it shows a tight relationship between the calpain-dependent proteolysis of
Nav1.6
channels, the upregulation of I(NaP) and
spasticity
.
...
PMID:Cleavage of Na(+) channels by calpain increases persistent Na(+) current and promotes spasticity after spinal cord injury. 2697 9
