Abstract. S100/~ produced in Escherichia coli from a synthetic gene (Van Eldik, L. J., J. L. Staecker, and E Winningham-Major. 1988. J. Biol. Chem. 263:7830-7837) stimulates neurite outgrowth and enhances cell maintenance in cultures of embryonic chick cerebral cortex neurons. In control experiments, the neurite extension activity is reduced by preincubation with antibodies made against bovine brain S100/L When either of the two cysteines in S100/3 are altered by site-directed mutagenesis, the resultant proteins maintain the overall biochemical properties of S100/~, but lose both the neurite extension and neuronal survival activities. However, another S100/3 mutant, in which the relative position of one of the two cysteines was changed, had neurotrophic activity similar to that of the unmodified protein. These and other results indicate that (a) specific neurite extension activity and neuronal survival activity are two related activities inherent to the S100/3 molecule; (b) a disulfide-linked form of S100/~ is required for full biological activity, and (c) the relative position of the cysteines can be modified. These data suggest potential in vivo roles for S100/~ in the development and maintenance of neuronal function in the central nervous system, and demonstrate the feasibility of the longer term development of selective pharmacological agents based on the S100/~ structure.T HE early development of the vertebrate nervous system involves a complex set of events, including neuronal and glial cell proliferation, migration and differentiation; neurite outgrowth and guidance; and establishment of appropriate synapses. This program of development is further complicated by interactions among different components of the nervous system. For example, specific extracellulax signals function as neurotrophic factors by stimulating neurite outgrowth and/or enhancing neuronal survival. Identification and characterization of factors that have neurotrophic activity are important steps in understanding the moleculax mechanisms by which neuronal development and axonal growth are controlled. Many types of neurotrophic factors have been described, including ions, hormones, extracellulax matrix proteins, cell-cell adhesion proteins, growth factors, and oncogenes (for reviews, see Greene, 1982;Berg, 1984; Thoenen et ai., 1987;Walicke, 1989). One of the best characterized neurotrophic factors is nerve growth factor
