Gail M. Kelly

Sensory Deprivation Alters Aggrecan and Perineuronal Net Expression in the Mouse Barrel Cortex

An important role for the neural extracellular matrix in modulating cortical activity-dependent synaptic plasticity has been established by a number of recent studies. However, identification of the critical molecular components of the neural matrix that mediate these processes is far from complete. Of particular interest is the perineuronal net (PN), an extracellular matrix component found surrounding the cell body and proximal neurites of a subset of neurons. Because of the apposition of the PN to synapses and expression of this structure coincident with the close of the critical period, it has been hypothesized that nets could play uniquely important roles in synapse stabilization and maturation. Interestingly, previous work has also shown that expression of PNs is dependent on appropriate sensory stimulation in the visual system. Here, we investigated whether PNs in the mouse barrel cortex are expressed in an activity-dependent manner by manipulating sensory input through whisker trimming. Importantly, this manipulation did not lead to a global loss of PNs but instead led to a specific decrease in PNs, detected with the antibody Cat-315, in layer IV of the barrel cortex. In addition, we identified a key activity-regulated component of PNs is the proteoglycan aggrecan. We also demonstrate that these Cat-315-positive neurons virtually all also express parvalbumin. Together, these data are in support of an important role for aggrecan in the activity-dependent formation of PNs on parvalbumin-expressing cells and suggest a role for expression of these nets in regulating the close of the critical period.

Intracranial injury acutely induces the expression of the secreted isoform of the CNS-specific hyaluronan-binding protein BEHAB/brevican.

Hyaluronan (HA) plays an important role in tissue reorganization in response to injury. The mechanisms by which HA participates in these processes are likely to include HA-binding proteins. Previously, we reported the cloning and initial characterization of a central nervous system (CNS)-specific HA-binding protein, BEHAB (brain enriched hyaluronan binding), which was independently cloned in another laboratory and named brevican. BEHAB/brevican mRNA is expressed in the ventricular zone coincident with the initial proliferation and migration of glial cells and in surgical samples of human glioma, where glial-derived cells proliferate and migrate. To determine whether BEHAB/brevican is also expressed during the cellular proliferation and migration associated with CNS injury, we have examined BEHAB/brevican expression during reactive gliosis. BEHAB/brevican occurs as secreted and cell-surface, glycosylphosphatidylinositol (GPI)-anchored, isoforms. The secreted, but not the GPI-anchored, isoform is up-regulated in response to a stab wound to the adult rat brain. The temporal regulation and spatial distribution of BEHAB/brevican expression parallel the gliotic response and the expression of the intermediate filament protein nestin. The up-regulation of BEHAB/brevican in response to CNS injury suggests a role for this extracellular matrix molecule in reactive gliosis. Glial process extension, a central element in the glial response to injury, may require the reexpression of both cytoskeletal and matrix elements that are normally expressed during the glial motility seen in the immature brain.

BEHAB/brevican: a brain-specific lectican implicated in gliomas and glial cell motility

Several recent findings have advanced our understanding of the composition and function of the brain extracellular matrix (ECM). BEHAB/brevican, a recently identified CNS-specific proteoglycan, is a component of the brain ECM and is upregulated during glial cell motility. It is expressed at high levels during development, in response to injury, and in primary brain tumors. Cleavage of the BEHAB/brevican protein may increase invasion of tumor cells.

Identification and characterization of novel developmentally regulated proteins in rat spinal cord.

We previously used 2-dimensional (2-D) gel electrophoresis to identify novel proteins that may be involved in the genesis of the mammalian nervous system [1]. Several novel proteins that were up- or down-regulated coincident with neurogenesis and neuronal migration in rat neocortex were identified. To further investigate the expression of some of these developmentally regulated proteins during a comparable period in spinal cord development, 2-D electrophoresis is used to study their regulation in the crude membrane and soluble fractions of spinal cord at embryonic day 12 (E12) and embryonic day 21 (E21). This analysis indicates that 7 of the proteins that exhibited large changes in their synthesis in cerebral cortex between embryonic day 14 (E14) and embryonic day 21 (E21) demonstrate similar up- or down-regulation during spinal cord neurogenesis. However, two proteins are restricted in their expression or developmental regulation. One of these, 667-800, appears cortex-specific, while the up-regulation of protein SC.1 appears to be spinal cord specific. Several of these proteins also appear to be enriched in both the cortex and spinal cord relative to non-neural tissues (117, 162, 182, 310 [TOAD-64], 667-800) and may be neural specific. To further characterize its expression, one of these neural-specific, up-regulated proteins, TOAD-64 (protein 310) [2-4], is studied throughout embryonic and postnatal spinal cord development using peptide-specific polyclonal antibodies. As suggested by the 2-D gel analysis and the previously reported expression pattern in cerebral cortex [3], TOAD-64 is transiently expressed in postmitotic spinal cord neurons early in their development and sharply down-regulated after the second postnatal week. In the adult spinal cord, TOAD-64 expression is remarkably restricted to a subset of primary afferents to the spinal cord. This expression pattern, coupled with its recently discovered homology to two proteins implicated in axon pathfinding in the chick and nematode [5,3], suggests that TOAD-64 may have a fundamental role in axon pathfinding.