Suppressor analysis of fimbrin (Sac6p) overexpression in yeast.

Yeast fimbrin (Sac6p) is an actin filament-bundling protein that is lethal when overexpressed. To identify the basis for this lethality, we sought mutations that can suppress it. A total of 1326 suppressor mutations were isolated and analyzed. As the vast majority of mutations were expected to simply decrease the expression of Sac6p to tolerable levels, a rapid screen was devised to eliminate these mutations. A total of 1324 mutations were found to suppress by reducing levels of Sac6p in the cell. The remaining 2 mutations were both found to be in the actin gene and to make the novel changes G48V (act1-20) and K50E (act1-21). These mutations suppress the defect in cytoskeletal organization and cell morphology seen in ACT1 cells that overexpress SAC6. These findings indicate that the lethal phenotype caused by Sac6p overexpression is mediated through interaction with actin. Moreover, the altered residues lie in the region of actin previously implicated in the binding of Sac6p, and they result in a reduced affinity of actin for Sac6p. These results indicate that the two mutations most likely suppress by reducing the affinity of actin for Sac6p in vivo. This study suggests it should be possible to use this type of suppressor analysis to identify other pairs of physically interacting proteins and suggests that it may be possible to identify sites where such proteins interact with each other.

Molecular evolution of integrins: genes encoding integrin beta subunits from a coral and a sponge.

The integrin family of cell surface receptors is strongly conserved in higher animals, but the evolutionary history of integrins is obscure. We have identified and sequenced cDNAs encoding integrin beta subunits from a coral (phylum Cnidaria) and a sponge (Porifera), indicating that these proteins existed in the earliest stages of metazoan evolution. The coral betaCn1 and, especially, the sponge betaPo1 sequences are the most divergent of the "beta1-class" integrins and share a number of features not found in any other vertebrate or invertebrate integrins. Perhaps the greatest difference from other beta subunits is found in the third and fourth repeats of the cysteine-rich stalk, where the generally conserved spacings between cysteines are highly variable, but not similar, in betaCn1 and betaPo1. Alternatively spliced cDNAs, containing a stop codon about midway through the full-length translated sequence, were isolated from the sponge library. These cDNAs appear to define a boundary between functional domains, as they would encode a protein that includes the globular ligand-binding head but would be missing the stalk, transmembrane, and cytoplasmic domains. These and other sequence comparisons with vertebrate integrins are discussed with respect to models of integrin structure and function.

Genetic analysis of the fimbrin-actin binding interaction in Saccharomyces cerevisiae.

Yeast fimbrin is encoded by the SAC6 gene, mutations of which suppress temperature-sensitive mutations in the actin gene (ACT1). To examine the mechanism of suppression, we have sequenced 17 sac6 suppressor alleles, and found that they change nine different residues, all of which cluster in three regions of one of the two actin-binding domains of Sac6p. Two of these clusters occur in highly conserved regions (ABS1 and ABS3) that have been strongly implicated in the binding of related proteins to actin. The third cluster changes residues not previously implicated in the interaction with actin. As changes in any of nine different residues can suppress several different act1 alleles, it is likely that the suppressors restore the overall affinity, rather than specific lost interactions, between Sac6p and actin. Using mutagenesis, we have identified two mutations of the second actin-binding domain that can also suppress the act1 mutations of interest. This result suggests the two actin-binding domains of Sac6p interact with the same region of the actin molecule. However, differences in strength of suppression of temperature-sensitivity and sporulation indicate that the two actin-binding domains are distinct, and explain why second-domain mutations were not identified previously.

Actin mutations that show suppression with fimbrin mutations identify a likely fimbrin-binding site on actin.

Actin interacts with a large number of different proteins that modulate its assembly and mediate its functions. One such protein is the yeast actin-binding protein Sac6p, which is homologous to vertebrate fimbrin (Adams, A. E. M., D. Botstein, and D. G. Drubin. 1991. Nature (Lond.). 354:404-408.). Sac6p was originally identified both genetically (Adams, A. E. M., and D. Botstein. 1989. Genetics. 121:675-683.) by dominant, reciprocal suppression of a temperature-sensitive yeast actin mutation (act1-1), as well as biochemically (Drubin, D. G., K. G. Miller, and D. Botstein. 1988. J. Cell Biol. 107: 2551-2561.). To identify the region on actin that interacts with Sac6p, we have analyzed eight different act1 mutations that show suppression with sac6 mutant alleles, and have asked whether (a) these mutations occur in a small defined region on the crystal structure of actin; and (b) the mutant actins are defective in their interaction with Sac6p in vitro. Sequence analysis indicates that all of these mutations change residues that cluster in the small domain of the actin crystal structure, suggesting that this region is an important part of the Sac6p-binding domain. Biochemical analysis reveals defects in the ability of several of the mutant actins to bind Sac6p, and a reduction in Sac6p-induced cross-linking of mutant actin filaments. Together, these observations identify a likely site of interaction of fimbrin on actin.