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Query: EC:3.4.24.11 (
CD10
)
9,792
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Prominent among the several endogenous inhibitors known to limit recovery and plasticity after CNS injury are Nogo (neurite outgrowth inhibitor) and MAG (myelin associated glycoprotein). The effects of these inhibitors on axonal regeneration can be reduced by administration of specific antagonists, some of which are commercially available for experimental investigation. There are three aspects of therapeutic manipulations: targeting the inhibitory proteins, antagonizing the known receptor, and inhibiting the intracellular signal transduction of these inhibitory molecules. Infusion of an antibody against Nogo improves behavioral deficits and enhances corticospinal tract regeneration in animals after stroke and spinal cord injury (SCI). Similarly, peripheral injection of a mouse monoclonal antibody directed against MAG results in dramatic preferential motor reinnervation in mice after transection of the femoral nerve, indicating that interference with the repellant function of MAG facilitates reinnervation of correct pathways by motor neurons. Further, antagonism of the
Nogo receptor
by the peptide
NEP
1-40 (Nogo extracellular peptide residues 1-40) can promote axonal regeneration in rats after SCI. Blockade of signal transduction also can be effective. The p75 neurotrophin receptor probably represents the signaling part of the receptor complex for neurite growth inhibitors. There is evidence in vitro that the inhibitory actions of MAG and myelin are blocked if neurons are primed with a variety of neurotrophins. Thus, there are several therapeutic approaches to overcome the actions of endogenous neurite growth inhibitors so as to promote CNS regeneration.
...
PMID:Targeting neurite growth inhibitors to induce CNS regeneration. 1585 81
This study was undertaken as part of the NIH "Facilities of Research-Spinal Cord Injury" project to support independent replication of published studies. Here, we repeated a study reporting that treatment with the
NgR
antagonist peptide NEP1-40 results in enhanced growth of corticospinal and serotonergic axons and enhanced locomotor recovery after thoracic spinal cord injury. Mice received dorsal hemisection injuries at T8 and then received either NEP1-40, Vehicle, or a Control Peptide beginning 4-5 h (early treatment) or 7 days (delayed treatment) post-injury. CST axons were traced by injecting BDA into the sensorimotor cortex. Serotonergic axons were assessed by immunocytochemistry. Hindlimb motor function was assessed using the BBB and BMS scales, kinematic and footprint analyses, and a grid climbing task. There were no significant differences between groups in the density of CST axon arbors in the gray matter rostral to the injury or in the density of serotonergic axons caudal to the injury. Tract tracing revealed that a small number of CST axons extended past the lesion in the ventral column in some mice in all treatment groups. The proportion of mice with such axons was higher in the NEP1-40 groups that received early treatment. In one experiment, mice treated with either NEP1-40 or a Control Peptide (reverse sequence) had higher BBB and BMS scores than Vehicle-treated controls at the early post-injury testing intervals, but scores converged at later intervals. There were no statistically significant differences between groups on other functional outcome measures. In a second experiment comparing
NEP
-treated and Vehicle controls, there were no statistically significant differences on any of the functional outcome measures. Together, our results suggest that treatment with NEP1-40 created a situation that was slightly more conducive to axon regeneration or sprouting. Enhanced functional recovery was not seen consistently with the different functional assessments, however.
...
PMID:A re-assessment of the effects of a Nogo-66 receptor antagonist on regenerative growth of axons and locomotor recovery after spinal cord injury in mice. 1823 96
Neuronal regeneration and axonal regrowth mechanisms in the injured mammalian central nervous system are largely unknown. As part of a major pathway for inhibiting axonal regeneration, activated neuronal glycosylphosphatidylinositol-anchored
Nogo receptor
(
NgR
) interacts with LINGO-1 and p75NTR to form a complex at the cell surface. However, it was found in our previous report that upregulation of
NgR
stimulated by injury plays a key role in neuronal regeneration in the neonatal cortex freeze-lesion model, but its downstream signalling remains elusive. In the present study, the novel regulatory role of
NgR
in a serine-threonine kinase WNK1 was identified.
NgR
's transcriptional regulation of WNK1 was identified by RT-qPCR and semiquantitative western blot after the overexpression or knockdown of
NgR
, and the regulation is specific to WNK1, which is not the same for its family members, WNK2, WNK3 and WNK4. Furthermore,
NgR
inhibition by
NEP
fails to affect WNK1, which indicates that WNK1 functions outside of the Nogo-A/
NgR
pathway. By performing a proliferation, migration and axonal extension assay, we also identified that overexpressed
NgR
critically regulated these processes and impairment by overexpressing
NgR
was rescued with coexpression of WNK1, indicating the partial role of WNK1 in
NgR
-mediated morphological regulation. Our study identifies a separation of functions for the
NgR
-regulated WNK1 in mediating proliferation, migration and axonal extension in PC12 cells as well as a specific regulatory role between
NgR
and WNK1 that is important for recovery from central nervous system injury.
...
PMID:The Nogo receptor inhibits proliferation, migration and axonal extension by transcriptionally regulating WNK1 in PC12 cells. 2848 65
Diffuse traumatic brain injury (TBI) initiates secondary pathology, including inflammation and reduced myelination. Considering these injury-related pathologies, the many states of activated microglia as demonstrated by differing morphologies would form, migrate, and function in and through fields of growth-inhibitory myelin byproduct, specifically Nogo. Here we evaluate the relationship between inflammation and reduced myelin antigenicity in the wake of diffuse TBI and present the hypothesis that the
Nogo-66 receptor
antagonist peptide
NEP
(1-40) would reverse the injury-induced shift in distribution of microglia morphologies by limiting myelin-based inhibition. Adult male rats were subjected to midline fluid percussion sham or brain injury. At 2h, 6h, 1d, 2d, 7d, and 21d post-injury, immunohistochemical staining was analyzed in sensory cortex (S1BF) for myelin antigens (myelin basic protein; MBP and CNPase), microglia morphology (ionized calcium-binding adapter protein; Iba1),
Nogo receptor
and Nogo. Pronounced reduction in myelin antigenicity was evident transiently at 1d post-injury, as evidenced by decreased MBP and CNPase staining, as well as loss of white matter organization, compared to sham and later injury time points. Concomitant with reduced myelin antigenicity, injury shifted microglia morphology from the predominantly ramified morphology observed in sham-injured cortex to hyper-ramified, activated, fully activated, or rod. Changes in microglial morphology were evident as early as 2h post-injury, and remained at least until day 21. Additional cohorts of uninjured and brain-injured animals received vehicle or drug (
NEP
(1-40), i.p., 15min and 19h post-injury) and brains were collected at 2h, 6h, 1d, 2d, or 7d post-injury.
NEP
(1-40) administration further shifted distributions of microglia away from an injury-induced activated morphology toward greater proportions of rod and macrophage-like morphologies compared to vehicle-treated. By 7d post-injury, no differences in the distributions of microglia were noted between vehicle and
NEP
(1-40). This study begins to link secondary pathologies of white matter damage and inflammation after diffuse TBI. In the injured brain, secondary pathologies co-occur and likely interact, with consequences for neuronal circuit disruption leading to neurological symptoms.
...
PMID:Nogo presence is inversely associated with shifts in cortical microglial morphology following experimental diffuse brain injury. 2873 37
