Abstract

Following spinal cord injury (SCI), adult mammalian axons initiate a regenerative effort that fails at the site of tissue damage. The local environment at the lesion site is altered as complex cellular responses to injury lead to remodeling of the extracellular matrix (ECM). While there is a general consensus that the environment surrounding the site of injury is inhibitory to axonal growth, the roles of the cellular and ECM components in this process are poorly understood. To begin to address this problem, we have developed a spinal cord contusion injury model in the mouse, and we have compared ECM and axon profile distribution in selected inbred strains of mice that differ in the cellular response to an identical injury paradigm. Our preliminary data indicate that the cellular and ECM composition at the lesion dictate the distribution and extent of axonal growth after a contusive SCI. For example, we observed increased axonal growth in strains with a reduced expression of chondroitin sulfate proteoglycan sidechains, or CSPG-GAGs, in the glial borders of the lesion and increased laminin within the lesion site. To extend and test this central hypothesis, we will complete the following four specific aims:
In Specific Aim 1, we will determine the distribution and trajectory of identified axons approaching the site of contusion injury in chosen inbred mouse strains. Using the phenotypic variation in cellular response to injury as a tool, we will define the distribution of axons in and around the lesion site with immunohistochemical and anterograde tract tracing methods. These experiments will serve to identify the strains and regions that are associated with growing axons. Then, we will study those regions further in Specific Aim 2 to define the relationship between axon profiles, supporting cells, and ECM components at the lesion site. These experiments will center on co-localizing axons with cellular and ECM components, including CSPGs and laminins, using light, confocal, and electron microscopy.
In Specific Aim 3, we will directly test the role of CSPG-GAGs on axonal growth in and around the site of a contusion injury, using chondroitinase ABC to cleave the GAG sidechains from the core proteins. Finally, in Specific Aim 4, we will extend the study of axon/ECM interactions to determine the role of the local ECM on the integration and growth of embryonic neurons after transplantation into the site of a contusion lesion. Together, these four aims will establish a firm basis for understanding the relationship between cellular and ECM remodeling and axonal growth after SCI, and will help to direct future strategies to enhance axonal growth after injury.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS043246-02
Application #
6855687
Study Section
Special Emphasis Panel (ZRG1-CNNT (01))
Program Officer
Kleitman, Naomi
Project Start
2004-03-01
Project End
2009-02-28
Budget Start
2005-03-01
Budget End
2006-02-28
Support Year
2
Fiscal Year
2005
Total Cost
$276,575
Indirect Cost

  Institution

Name
Ohio State University
Department
Physiology
Type
Schools of Medicine
DUNS #
832127323
City
Columbus
State
OH
Country
United States
Zip Code
43210

  Publications

Hesp, Zoe C; Yoseph, Rim Y; Suzuki, Ryusuke et al. (2018) Proliferating NG2-Cell-Dependent Angiogenesis and Scar Formation Alter Axon Growth and Functional Recovery After Spinal Cord Injury in Mice. J Neurosci 38:1366-1382
Church, Jamie S; Milich, Lindsay M; Lerch, Jessica K et al. (2017) E6020, a synthetic TLR4 agonist, accelerates myelin debris clearance, Schwann cell infiltration, and remyelination in the rat spinal cord. Glia 65:883-899
Goldstein, Evan Z; Church, Jamie S; Pukos, Nicole et al. (2017) Intraspinal TLR4 activation promotes iron storage but does not protect neurons or oligodendrocytes from progressive iron-mediated damage. Exp Neurol 298:42-56
Ma, Baofeng; Buckalew, Richard; Du, Yixing et al. (2016) Gap junction coupling confers isopotentiality on astrocyte syncytium. Glia 64:214-26
Kigerl, Kristina A; de Rivero Vaccari, Juan Pablo; Dietrich, W Dalton et al. (2014) Pattern recognition receptors and central nervous system repair. Exp Neurol 258:5-16
Jakeman, Lyn B; Williams, Kent E; Brautigam, Bryan (2014) In the presence of danger: The extracellular matrix defensive response to central nervous system injury. Neural Regen Res 9:377-384
Andrews, Ellen M; Richards, Rebekah J; Yin, Feng Q et al. (2012) Alterations in chondroitin sulfate proteoglycan expression occur both at and far from the site of spinal contusion injury. Exp Neurol 235:174-87
Jakeman, Lyn B; Hoschouer, Emily L; Basso, D Michele (2011) Injured mice at the gym: review, results and considerations for combining chondroitinase and locomotor exercise to enhance recovery after spinal cord injury. Brain Res Bull 84:317-26
White, Robin E; Rao, Meghan; Gensel, John C et al. (2011) Transforming growth factor ýý transforms astrocytes to a growth-supportive phenotype after spinal cord injury. J Neurosci 31:15173-87
Naphade, Swati B; Kigerl, Kristina A; Jakeman, Lyn B et al. (2010) Progranulin expression is upregulated after spinal contusion in mice. Acta Neuropathol 119:123-33

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