Weaver mouse cerebellar granule neurons fail to migrate on wild-type astroglial processes in vitro.

To study the regulation of glial-guided neuronal migration, we have analyzed the behavior of cerebellar granule neurons purified from the homozygous weaver (wv/wv) B6CBA-w mouse, an autosomal recessive genetic mutation that suffers a failure of granule cell migration along Bergmann glial processes (Rakic and Sidman, 1973a, b; Rezai and Yoon, 1972), on the processes of astroglia purified from homozygous normal B6CBA-Aw-J-wv (+/+) mouse cerebella. When co-cultured with normal astroglia, weaver granule neurons failed to form neuron-glia contacts characteristic of migrating neurons and impaired normal astroglial morphological differentiation. Normal astroglial cells co-cultured with weaver granule cells had enlarged cell somata with stunted processes and enlarged endfeet compared to normal astroglia co-cultured with normal granule cells. In contrast, normal neurons associated with weaver astroglia, forming tight appositions seen for migrating neurons in vivo, and enhanced weaver astroglial morphological differentiation. Weaver astroglia co-cultured with normal granule cells contained a more normal complement of glial filaments and had a smaller perikaryon with longer, more tapered processes than their counterparts co-cultured with weaver neurons. These results suggest, in agreement with the study of Goldowitz and Mullen (1982) on heterozygous mutant chimeras, that the granule neuron is a primary site of action of the weaver gene, and further support our previous findings that neuron-glia interactions regulate astroglial morphological differentiation (Hatten, 1985).