Guus Wolswijk scite author profile

In the past decade, considerable progress has been made in the understanding of the biology of rodent oligodendrocyte precursor cells and their role in the generation of oligodendrocytes in the developing and adult rodent CNS. Much less is known about human oligodendrocyte lineage cells and about the reasons for the failure of the regeneration of the oligodendrocyte population during chronic stages of multiple sclerosis (MS). In particular, the fate of the oligodendrocyte precursor population in MS has remained elusive. The present study examined the possibility that oligodendrocyte regeneration ultimately fails because of the local destruction of both oligodendrocytes and their precursor cells. Analysis of chronic stage MS tissue suggested that this is not the case, because all chronic MS lesions studied contained significant numbers of oligodendrocyte precursor cells, identified as process-bearing cells that bound the O4 antibody but not antibodies to GalC and GFAP. The oligodendrocyte precursor cells appeared, however, to be relatively quiescent, because none expressed the nuclear proliferation antigen recognized by the Ki-67 antibody, and because most lesions lacked myelinating oligodendrocytes in their centers. Thus, it appears that the regeneration of the oligodendrocyte population fails during chronic stages of MS because of the inability of oligodendrocyte precursor cells to proliferate and differentiate rather than because of the local destruction of all oligodendrocyte lineage cells. The identification of ways of stimulating the endogenous oligodendrocyte precursor population to expand and generate remyelinating cells may represent an alternative to transplantation of oligodendrocyte lineage cells to promote myelin repair in MS.

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Oligodendrocyte precursor cells in the demyelinated multiple sclerosis spinal cord

Wolswijk¹

2002

249

168

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Lesions appearing in the CNS of patients in the chronic phase of the inflammatory, demyelinating disease multiple sclerosis often fail to repair, resulting in neurological dysfunction. This failure of remyelination appears, in many cases, to be due not to the destruction of the local oligodendrocyte precursor population, a source for new myelin-forming cells, but to the failure of the precursor cells to proliferate and differentiate, at least in brain lesions. The spinal cord is also a prominent site for lesions in multiple sclerosis, but nothing is known about the fate of the oligodendrocyte precursor population in this area. The present study has therefore analysed spinal cord samples with demyelination from 16 subjects with longstanding multiple sclerosis for the presence of oligodendrocyte precursor cells. Immunolabellings of 10 microm thick sections with the O4/anti-galactocerebroside (GalC) antibody combination, to visualize O4-positive, GalC-negative oligodendrocyte precursor cells, revealed that such cells were prevalent in many spinal cord lesions, with densities of up to 35 cells/mm(2). Six of the spinal cord lesions contained < or =3 O4-positive, GalC-negative cells/mm(2), but such cells were widespread in brain lesions from these multiple sclerosis cases that were available for study (8-26 cells/mm(2)). The density of the O4-positive, GalC-negative oligodendrocyte precursor cells in all spinal cord and brain lesions studied thus far (n = 41) decreased significantly with declining numbers of debris-laden macrophages. In addition, lesions lacking macrophages tended to be derived from the older patients and there was a negative correlation between the density of the oligodendrocyte precursor cells and clinical age of the multiple sclerosis subject at death, and disease duration. The analysis further revealed that lesions from subjects with primary progressive and secondary progressive multiple sclerosis contained, on average, similar numbers of oligodendrocyte precursor cells/mm(2) and that immature oligodendrocytes were only present in significant numbers in lesions with high precursor densities. Taken together, the present data suggest that there is a gradual reduction in the size of the O4-positive, GalC- negative oligodendrocyte precursor population with increasing age of the lesion, that the generation of new oligodendrocytes becomes increasingly more impaired and that lesions are not repopulated to a significant extent by migratory oligodendrocyte precursor cells present in the adjacent unaffected tissue. Hence, strategies intended to promote endogenous remyelination in multiple sclerosis patients should focus on both enhancing the long-term survival of oligodendrocyte precursor cells and on stimulating these cells to proliferate and differentiate into remyelinating oligodendrocytes.

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Cooperation between PDGF and FGF converts slowly dividing O-2Aadult progenitor cells to rapidly dividing cells with characteristics of O-2Aperinatal progenitor cells.

1992

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Abstract. We have shown previously that oligodendrocyte-type-2 astrocyte (O-2A) progenitor cells isolated from adult rat optic nerves can be distinguished in vitro from their pcrinatal counterparts on the basis of their much slower rates of division, differentiation, and migration when grown in the presence of cortical astrocytes or PDGF. This behavior is consistent with in vivo observations that there is only a modest production of oligodendrocytes in the adult CNS. As such a behavior is inconsistent with the likely need for a rapid generation of oligodcndrocytes following demyelinating damage to the mature CNS, we have been concerned with identifying in vitro conditions that allow O-2A ~l* progenitor cells to generate rapidly large numbers of progeny cells. We now provide evidence that many slowly dividing O-2A ~d' progenitor cells can be converted to rapidly dividing cells by exposing adult optic nerve cultures to both PDGF and bFGF. In addition, these O-2A ~d~t progenitor cells appear to acquire other properties of O-2A~oZ progenitor cells, such as bipolar morphology and high rate of migration. Although many O-2A ~ progenitor cells in cultures exposed to bFGF alone also divide rapidly, these cells are multipolar and migrate little in vitro.

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Guus Wolswijk

Identification of an adult-specific glial progenitor cell

Chronic Stage Multiple Sclerosis Lesions Contain a Relatively Quiescent Population of Oligodendrocyte Precursor Cells

Oligodendrocyte precursor cells in the demyelinated multiple sclerosis spinal cord

Cooperation between PDGF and FGF converts slowly dividing O-2Aadult progenitor cells to rapidly dividing cells with characteristics of O-2Aperinatal progenitor cells.

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