A computationally directed screen identifying interacting coiled coils from Saccharomyces cerevisiae

Computational methods can frequently identify protein-interaction motifs in otherwise uncharacterized open reading frames. However, the identification of candidate ligands for these motifs (e.g., so that partnering can be determined experimentally in a directed manner) is often beyond the scope of current computational capabilities. One exception is provided by the coiled-coil interaction motif, which consists of two or more α helices that wrap around each other: the ligands for coiled-coil sequences are generally other coiled-coil sequences, thereby greatly simplifying the motif/ligand recognition problem. Here, we describe a two-step approach to identifying protein–protein interactions mediated by two-stranded coiled coils that occur in Saccharomyces cerevisiae. Coiled coils from the yeast genome are first predicted computationally, by using the multicoil program, and associations between coiled coils are then determined experimentally by using the yeast two-hybrid assay. We report 213 unique interactions between 162 putative coiled-coil sequences. We evaluate the resulting interactions, focusing on associations identified between components of the spindle pole body (the yeast centrosome).

A genetic screen identifies cellular factors involved in retroviral -1 frameshifting.

To identify cellular factors that function in -1 ribosomal frameshifting, we have developed assays in the yeast Saccharomyces cerevisiae to screen for host mutants in which frameshifting is specifically affected. Expression vectors have been constructed in which the mouse mammary tumor virus gag-pro frameshift region is placed upstream of the lacZ gene or the CUP1 gene so that the reporters are in the -1 frame relative to the initiation codon. These vectors have been used to demonstrate that -1 frameshifting is recapitulated in yeast in response to retroviral mRNA signals. Using these reporters, we have isolated spontaneous host mutants in two complementation groups, ifs1 and ifs2, in which frameshifting is increased 2-fold. These mutants are also hypersensitive to antibiotics that target the 40S ribosomal subunit. We have cloned the IFS1 gene and shown that it encodes a previously undescribed protein of 1091 aa with clusters of acidic residues in the carboxyl-terminal region. Haploid cells lacking 82% of the IFS1 open reading frame are viable and phenotypically identical to ifs1-1 mutants. This approach could help identify potential targets for antiretroviral agents.