Matrix metalloproteinase production in regenerating axolotl spinal cord

Chernoff, Ellen A.G.; O'Hara, Christina M.; Bauerle, D; Bowling, Michael

doi:10.1046/j.1524-475x.2000.00282.x

Cited by 42 publications

(41 citation statements)

References 39 publications

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“…The MRL/MpJ mouse has a heightened and prolonged local expression of MMPs, including both MMP-2 and MMP-9, following ear punch or after injury to the cortex or retina in the CNS (Gourevitch et al, 2003; Hampton et al, 2004; Tucker et al, 2008). MMPs are important mediators of tissue regeneration in urodeles (Chernoff et al, 2000; Monaghan et al, 2007), yet their functions after injury in the mammalian CNS are complex. MMP-9 is upregulated at 1–2 days after SCI, during the period of neutrophil recruitment and tissue degradation (Noble et al, 2002; Goussev et al, 2003; Fleming et al, 2006).…”

Section: Discussionmentioning

confidence: 99%

Robust axonal growth and a blunted macrophage response are associated with impaired functional recovery after spinal cord injury in the MRL/MpJ mouse

et al. 2008

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Spinal cord injury (SCI) in mammals leads to a robust inflammatory response followed by the formation of a glial and connective tissue scar that comprises a barrier to axonal regeneration. The inbred MRL/MpJ mouse strain exhibits reduced inflammation after peripheral injury and shows true regeneration without tissue scar formation following an ear punch wound. We hypothesized that following SCI, the unique genetic wound healing traits of this strain would result in reduced glial and connective tissue scar formation, increased axonal growth, and improved functional recovery. Adult MRL/MpJ and C57BL/6J mice were subjected to a mid-thoracic spinal contusion and the distribution of axon profiles and selected cellular and extracellular matrix components was compared at 1, 2, 4 and 6 weeks post-injury. Recovery of hind-limb locomotor function was assessed over the same time period. The MRL/MpJ mice exhibited robust axon growth within the lesion, beginning at 4 weeks post-injury. This growth was accompanied by reduced macrophage staining at 1, 2, 4 and 6 weeks post-injury, decreased chondroitin sulfate proteoglycan staining at 1-2 weeks and increased laminin staining throughout the lesion at 2-6 weeks post-injury. Paradoxically, the extent of locomotor recovery was impaired in the MRL/MpJ mice. Close examination of the chronic lesion site revealed evidence of ongoing degeneration both within and surrounding the lesion site. Thus, the regenerative genetic wound healing traits of the MRL/MpJ mice contribute to the evolution of a lesion environment that supports enhanced axon growth after SCI. However, this response occurs at the expense of meaningful functional recovery. NIH Public Access Author ManuscriptNeuroscience. Author manuscript; available in PMC 2009 October 15. Published in final edited form as:Neuroscience. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptTissue regenerative capacity varies across phylogeny, with complete epimorphic regeneration in planarians (Reddien and Sanchez Alvarado, 2004) and axolotls (Chernoff et al., 2003), and the loss of this capacity during metamorphosis in the tadpole (Beattie et al., 1990). Most adult mammals show no true regenerative ability, with the exception of the pinna of the rabbit ear and the wings of bats (Church and Warren, 1968;Goss and Grimes, 1975). In other tissues, injury initiates a cellular response including activation and recruitment of circulating inflammatory cells. These interact with resident cells to enhance connective tissue deposition, scar tissue formation and wound contraction to restore tissue and vascular integrity at the injury site (Werner et al., 2007).Injury to the mammalian CNS is characterized by similar events, leading to glial activation and connective tissue scar formation at the site of injury allowing little or no axonal regeneration. Within hours to days after trauma, activated neutrophils, macrophages, mesenchymal cells and leukocytes are recruited to the site of injury (Zhang et al., 1996;Popovich et al...

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Section: Discussionmentioning

confidence: 99%

Robust axonal growth and a blunted macrophage response are associated with impaired functional recovery after spinal cord injury in the MRL/MpJ mouse

et al. 2008

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“…Many studies have demonstrated that MMPs facilitate axonal regeneration in the mammalian PNS (Heine et al, 2004; Kobayashi et al, 2008; Shubayev and Myers, 2004; Zuo et al, 1998), and the CNS of lower vertebrates (Chernoff et al, 2000). Researchers also found that increased MMP expression after mammalian CNS injury is correlated with areas of increased axonal outgrowth and the subsequent enhancement of functional recovery (Ahmed et al, 2005; Duchossoy et al, 2001; Hsu et al, 2006).…”

Section: Harnessing Proteases To Promote Neural Regenerationmentioning

confidence: 99%

Protease Regulation: The Yin and Yang of Neural Development and Disease

Bai

Pfaff

2011

Neuron

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Summary The formation, maintenance and plasticity of neural circuits rely upon a complex interplay between progressive and regressive events. Increasingly, new functions are being identified for axon guidance molecules in the dynamic processes that occur within the embryonic and adult nervous system. The magnitude, duration, and spatial activity of axon guidance molecule signaling are precisely regulated by a variety of molecular mechanisms. Here we focus on recent progress in understanding the role of protease-mediated cleavage of guidance factors required for directional axon growth, with a particular emphasis on the role of metalloprotease and γ-secretase. Since axon guidance molecules have also been linked to neural degeneration and regeneration in adults, studies of guidance receptor proteolysis are beginning to define new relationships between neurodevelopment and neurodegeneration. These findings raise the possibility that the signaling checkpoints controlled by proteases could be useful targets to enhance regeneration.

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“…After initial stage of trauma, when cell death, axon damage and demyelination are taking place, the glial scar starts developing [5,75]. Following, the production of ECM molecules increases at the damage [76,77]. Then activation and migration to the damage site of microglia occur, where they serve microphage function, particularly by removing disturbed myelin [78].…”

Section: а Bmentioning

confidence: 99%

The Role of the Brain Extracellular Matrix in Synaptic Plasticity After Brain Injuries (Review)

Dembitskaya¹,

Tyurikova²,

Semyanov³

2016

Sovrem Tehnol Med

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The brain extracellular matrix is secreted by neurons and glial cells and represents a molecular net comprised of polysaccharides and proteins, fulfilling the space between cells in the tissue. A complex structure and ubiquitous localization of extracellular matrix underlie its involvement in numerous important brain functions, such as diffusion regulation, molecular cell-to-cell interactions, synaptic plasticity and learning. Additionally, the brain extracellular matrix participates in regeneration of neuronal connections after brain and spinal cord injuries. The ability to regenerate connections attenuates by the fast proliferation of the brain extracellular matrix, when its degradation leads to regeneration improvement. Therefore, the brain extracellular matrix represents an important direction of clinical research and possible target for therapeutic interventions. Here we not only describe the structure of the brain extracellular matrix and its sites of localization in the brain, but also make an overview of the influence of the brain extracellular matrix in synaptic plasticity, learning and memory. This review describes the role of the brain extracellular matrix for connection recovery after brain and spinal cord injuries. Here, we highlight the positive ability of enzymatic removal of extracellular matrix component -chondroitin sulphate proteoglycans by chondroitinase ABC to promote restoration of neuronal connections. In conclusion, we discuss possible side effects of treatments requiring the enzymatic removal of chondroitin sulphate proteoglycans on synaptic plasticity and speculate about future development of the field of the brain extracellular matrix research.

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Matrix metalloproteinase production in regenerating axolotl spinal cord

Cited by 42 publications

References 39 publications

Robust axonal growth and a blunted macrophage response are associated with impaired functional recovery after spinal cord injury in the MRL/MpJ mouse

Robust axonal growth and a blunted macrophage response are associated with impaired functional recovery after spinal cord injury in the MRL/MpJ mouse

Protease Regulation: The Yin and Yang of Neural Development and Disease

The Role of the Brain Extracellular Matrix in Synaptic Plasticity After Brain Injuries (Review)

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