Cell purification provides a powerful ABT-199 method that enables the study of the intrinsic properties of a cell type and its interactions with other cell types. Despite their abundance in the CNS, study of astrocytes has been hindered by
the lack of a method for their prospective purification. The McCarthy and de Vellis (1980) method has been an invaluable method for isolation of neonatal astrocyte-like cells, but it has been unclear if these cells are good models of astrocytes in vivo as their isolation was not prospective and involved passage in serum-containing medium. As these MD-astrocytes can only be obtained from neonatal brain, it has been speculated that these cells may be more akin to radial glia, astrocyte progenitor cells or reactive astrocytes. Indeed, our recent gene profiling studies demonstrated that MD-astrocytes highly express hundreds of MDV3100 solubility dmso genes that are not normally expressed in vivo (Cahoy et al., 2008). and in more recent work we have found that their profiles indicate that they may be a combination of reactive and developing astrocytes (J. Zamanian, L.C.F., and B.A.B., unpublished
data). Prospective purification is important as it ensures that the selected astrocytes are representative of the whole population, avoiding the selection of a minor subset. In the MD-astrocyte preparation procedure, only a small percentage of astrocyte-like
cells in the starting neonatal suspension survive in culture (our unpublished observations). Prospective purification also avoids prolonged culture of the cells in serum, which can irreversibly alter the properties of the cells. By combining a series of depletion panning steps to remove unwanted cell types such as microglia followed by a selection step using a monoclonal antibody to integrin beta 5, we have been able to prospectively isolate differentiated astrocytes from P1 to P18 rat brain tissue at a purity of 99% and a yield of 50% of all tuclazepam astrocytes at P7. Although we have focused on the isolation of rat astrocytes in this work, we have developed a similar panning method to purify astrocytes to greater than 95% purity from postnatal mouse brain (Experimental Procedures). This will enable astrocyte isolation from mutant or diseased mice, further facilitating the understanding of the functional role of astrocytes. Theoretically, this method can be extended to the purification of human astrocytes by using an appropriate ITGB5 antibody. It has long been thought that astrocytes, unlike other brain cell types, may not need trophic signals to survive. Astrocytic cell death was reported in the postnatal rat cerebellum (Soriano et al.