Literature DB >> 21829212

Selective CDK inhibitor limits neuroinflammation and progressive neurodegeneration after brain trauma.

Shruti V Kabadi1, Bogdan A Stoica, Kimberly R Byrnes, Marie Hanscom, David J Loane, Alan I Faden.   

Abstract

Traumatic brain injury (TBI) induces secondary injury mechanisms, including cell-cycle activation (CCA), which lead to neuronal cell death, microglial activation, and neurologic dysfunction. Here, we show progressive neurodegeneration associated with microglial activation after TBI induced by controlled cortical impact (CCI), and also show that delayed treatment with the selective cyclin-dependent kinase inhibitor roscovitine attenuates posttraumatic neurodegeneration and neuroinflammation. CCI resulted in increased cyclin A and D1 expressions and fodrin cleavage in the injured cortex at 6 hours after injury and significant neurodegeneration by 24 hours after injury. Progressive neuronal loss occurred in the injured hippocampus through 21 days after injury and correlated with a decline in cognitive function. Microglial activation associated with a reactive microglial phenotype peaked at 7 days after injury with sustained increases at 21 days. Central administration of roscovitine at 3 hours after CCI reduced subsequent cyclin A and D1 expressions and fodrin cleavage, improved functional recovery, decreased lesion volume, and attenuated hippocampal and cortical neuronal cell loss and cortical microglial activation. Furthermore, delayed systemic administration of roscovitine improved motor recovery and attenuated microglial activation after CCI. These findings suggest that CCA contributes to progressive neurodegeneration and related neurologic dysfunction after TBI, likely in part related to its induction of microglial activation.

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Year:  2011        PMID: 21829212      PMCID: PMC3323296          DOI: 10.1038/jcbfm.2011.117

Source DB:  PubMed          Journal:  J Cereb Blood Flow Metab        ISSN: 0271-678X            Impact factor:   6.200


  44 in total

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2.  Spatial and temporal characteristics of neurodegeneration after controlled cortical impact in mice: more than a focal brain injury.

Authors:  Edward D Hall; Patrick G Sullivan; Tonya R Gibson; Krissi M Pavel; Brian M Thompson; Stephen W Scheff
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Review 3.  The role of the hippocampus in solving the Morris water maze.

Authors:  A D Redish; D S Touretzky
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4.  Role of the cell cycle in the pathobiology of central nervous system trauma.

Authors:  Ibolja Cernak; Bogdan Stoica; Kimberly R Byrnes; Simone Di Giovanni; Alan I Faden
Journal:  Cell Cycle       Date:  2005-09-15       Impact factor: 4.534

5.  Metabolism and pharmacokinetics of the cyclin-dependent kinase inhibitor R-roscovitine in the mouse.

Authors:  Bernard P Nutley; Florence I Raynaud; Stuart C Wilson; Peter M Fischer; Angela Hayes; Phyllis M Goddard; Steven J McClue; Michael Jarman; David P Lane; Paul Workman
Journal:  Mol Cancer Ther       Date:  2005-01       Impact factor: 6.261

6.  Cell cycle inhibition provides neuroprotection and reduces glial proliferation and scar formation after traumatic brain injury.

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Journal:  Proc Natl Acad Sci U S A       Date:  2005-05-27       Impact factor: 11.205

7.  Roscovitine targets, protein kinases and pyridoxal kinase.

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Review 8.  Animal models of head trauma.

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9.  Sustained sensory/motor and cognitive deficits with neuronal apoptosis following controlled cortical impact brain injury in the mouse.

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  51 in total

1.  CR8, a selective and potent CDK inhibitor, provides neuroprotection in experimental traumatic brain injury.

Authors:  Shruti V Kabadi; Bogdan A Stoica; Marie Hanscom; David J Loane; Giorgi Kharebava; Michael G Murray Ii; Rainier M Cabatbat; Alan I Faden
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2.  Mild traumatic brain injury-induced hippocampal gene expressions: The identification of target cellular processes for drug development.

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Journal:  J Neurosci Methods       Date:  2016-02-08       Impact factor: 2.390

3.  CR8, a novel inhibitor of CDK, limits microglial activation, astrocytosis, neuronal loss, and neurologic dysfunction after experimental traumatic brain injury.

Authors:  Shruti V Kabadi; Bogdan A Stoica; David J Loane; Tao Luo; Alan I Faden
Journal:  J Cereb Blood Flow Metab       Date:  2014-01-08       Impact factor: 6.200

4.  Combined inhibition of cell death induced by apoptosis inducing factor and caspases provides additive neuroprotection in experimental traumatic brain injury.

Authors:  Chun-Shu Piao; David J Loane; Bogdan A Stoica; Shihong Li; Marie Hanscom; Rainier Cabatbat; Klas Blomgren; Alan I Faden
Journal:  Neurobiol Dis       Date:  2012-03-09       Impact factor: 5.996

Review 5.  Genetic manipulation of cell death and neuroplasticity pathways in traumatic brain injury.

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6.  Microglial/Macrophage Polarization Dynamics following Traumatic Brain Injury.

Authors:  Alok Kumar; Dulce-Mariely Alvarez-Croda; Bogdan A Stoica; Alan I Faden; David J Loane
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7.  Spinal cord injury causes brain inflammation associated with cognitive and affective changes: role of cell cycle pathways.

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Journal:  J Neurosci       Date:  2014-08-13       Impact factor: 6.167

Review 8.  Hyperphosphorylated tau is implicated in acquired epilepsy and neuropsychiatric comorbidities.

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Journal:  Mol Neurobiol       Date:  2013-12-10       Impact factor: 5.590

9.  Tumor necrosis factor in traumatic brain injury: effects of genetic deletion of p55 or p75 receptor.

Authors:  Luca Longhi; Carlo Perego; Fabrizio Ortolano; Silvia Aresi; Stefano Fumagalli; Elisa R Zanier; Nino Stocchetti; Maria-Grazia De Simoni
Journal:  J Cereb Blood Flow Metab       Date:  2013-04-24       Impact factor: 6.200

10.  Treatment with an activator of hypoxia-inducible factor 1, DMOG provides neuroprotection after traumatic brain injury.

Authors:  Tanusree Sen; Nilkantha Sen
Journal:  Neuropharmacology       Date:  2016-03-09       Impact factor: 5.250
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