Abstract
Cultures of newborn rat spinal cord contain multiple types of astrocytes. By using a combination of cultures enriched for glial precursors and clonal analysis, we have identified a particular astrocyte precursor that gives rise to morphologically distinct classes of astrocytes. This astrocyte precursor labels with the monoclonal antibody A2B5, is highly migratory, proliferates in response to serum and platelet-derived growth factor, and differentiates into process-bearing astrocytes, many of which subsequently assume a "pancake"-shaped morphology. A2B5+ astrocyte precursors share antigenic and migratory characteristics with previously described O2A progenitor cells but differ in their response to regulatory factors, including serum and coculture with type 1 astrocytes. More importantly, these astrocyte precursors do not give rise to oligodendrocytes. In their proliferative response to serum and their capacity to differentiate into astrocytes, these glial precursors resemble type 1 astrocyte precursors from optic nerve. However, unlike type 1 astrocyte precursors, these cells are A2B5+, highly migratory, and do not give rise to fibroblast-like astrocytes. Neonatal rat spinal cord cultures contain approximately twice the number of the A2B5+ astrocyte precursors than O2A progenitor cells. By contrast, the majority of A2B5+ cells in postnatal day 7 optic nerve cultures are O2A progenitors. The presence of large numbers of A2B5+ astrocyte precursors in rat spinal cord cultures may reflect the more complex cytoarchitecture of the spinal cord compared to the optic nerve.