Morven C. Shearer scite author profile

Chondroitin sulfate proteoglycan (CS-PG) expression is increased in response to CNS injury and limits the capacity for axonal regeneration. Previously we have shown that neurocan is one of the CS-PGs that is upregulated (Asher et al., 2000). Here we show that another member of the aggrecan family, versican, is also upregulated in response to CNS injury. Labeling of frozen sections 7 d after a unilateral knife lesion to the cerebral cortex revealed a clear increase in versican immunoreactivity around the lesion. Western blot analysis of extracts prepared from injured and uninjured tissue also revealed considerably more versican in the injured tissue extract. In vitro studies revealed versican to be a product of oligodendrocyte lineage cells (OLCs). Labeling was seen between the late A2B5-positive stage and the O1-positive pre-oligodendrocyte stage. Neither immature, bipolar A2B5-positive cells, nor differentiated, myelin-forming oligodendrocytes were labeled. The amount of versican in conditioned medium increased as these cells differentiated. Versican and tenascin-R colocalized in OLCs, and coimmunoprecipitation indicated that the two exist as a complex in oligodendrocyte-conditioned medium. Treatment of pre-oligodendrocytes with hyaluronidase led to the release of versican, indicating that its retention at the cell surface is dependent on hyaluronate (HA). In rat brain, approximately half of the versican is bound to hyaluronate. We also provide evidence of a role for CS-PGs in the axon growth-inhibitory properties of oligodendrocytes. Because large numbers of OLCs are recruited to CNS lesions, these results suggest that OLC-derived versican contributes to the inhospitable environment of the injured CNS.

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The astrocyte/meningeal cell interface – a barrier to successful nerve regeneration?

Shearer

2001

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Following injuries to the adult mammalian CNS meningeal cells migrate into the lesion cavity, forming a fibrotic scar and accessory glia limitans. This infiltration re-establishes the meningeal layer that normally surrounds the CNS, and so reforms the barrier between the CNS and external environment, thus protecting the damaged region from events outside it. However, the newly formed meningeal layer and glia limitans may impede subsequent nerve regeneration through the injured region. This structure can be modelled in vitro using an astrocyte/meningeal co-culture system. We have examined patterns of neurite outgrowth on such cultures, and we find that axons cross readily from meningeal cells to astrocytes, but are unwilling to cross in the other direction. The distribution of cell surface and matrix molecules on these cultures is described, and the effect of various pharmacological interventions which can affect axon growth between the two cell types is summarised in this review.

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The astrocyte/meningeal cell interface is a barrier to neurite outgrowth which can be overcome by manipulation of inhibitory molecules or axonal signalling pathways

Shearer

Niclou

Brown

et al. 2003

Molecular and Cellular Neuroscience

101

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Axon behaviour at Schwann cell – astrocyte boundaries: manipulation of axon signalling pathways and the neural adhesion molecule L1 can enable axons to cross

Adcock

Brown

Shearer

et al. 2004

Eur J of Neuroscience

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Axon regeneration in vivo is blocked at boundaries between Schwann cells and astrocytes, such as occur at the dorsal root entry zone and around peripheral nerve or Schwann cell grafts. We have created a tissue culture model of these boundaries in Schwann cell - astrocyte monolayer co-cultures. Axon behaviour resembles that in vivo, with axons showing a strong preference for Schwann cells over astrocytes. At boundaries between the two cell types, axons growing on astrocytes cross readily onto Schwann cells, but only 15% of axons growing on Schwann cells are able to cross onto astrocytes. Treatment with chondroitinase or chlorate to reduce inhibition by proteoglycans did not change this behaviour. The neural adhesion molecule L1 is present on Schwann cells and not astrocytes, and manipulation of L1 by application of an antibody, L1-Fc in solution, or adenoviral transduction of L1 into astrocytes increased the proportion of axons able to cross onto astrocytes to 40-50%. Elevating cAMP levels increased crossing from Schwann cells onto astrocytes in live and fixed cultures, and had a co-operative effect with NT-3 but not with NGF. Inactivation of Rho with a cell-permeant form of C3 exoenzyme also increased crossing from Schwann cells to astrocytes. Our experiments indicate that the preference of axons for Schwann cells is largely mediated by the presence of L1 on Schwann cells but not astrocytes, and that manipulation of growth cone signalling pathways can allow axons to disregard boundaries between the two cell types.

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Transition from paediatric to adult health services in Scotland for young people with cerebral palsy

Wright

Robb

Shearer

2015

J Child Health Care

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Morven C. Shearer

Versican Is Upregulated in CNS Injury and Is a Product of Oligodendrocyte Lineage Cells

The astrocyte/meningeal cell interface – a barrier to successful nerve regeneration?

The astrocyte/meningeal cell interface is a barrier to neurite outgrowth which can be overcome by manipulation of inhibitory molecules or axonal signalling pathways

Axon behaviour at Schwann cell – astrocyte boundaries: manipulation of axon signalling pathways and the neural adhesion molecule L1 can enable axons to cross

Transition from paediatric to adult health services in Scotland for young people with cerebral palsy

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