The Cyc8 (Ssn6)-Tup1 corepressor complex is composed of one Cyc8 and four Tup1 subunits.

The Cyc8 (Ssn6)-Tup1 corepressor complex is required for repression in several important regulatory systems in yeast cells, including glucose repression and mating type. Cyc8-Tup1 is recruited to target genes by interaction with diverse repressor proteins that bind directly to DNA. Since the complex has a large apparent molecular mass of 1,200 kDa on nondenaturing gels (F. E. Williams, U. Varanasi, and R. J. Trumbly, Mol. Cell. Biol. 11:3307-3316, 1991), we used a variety of approaches to determine its actual subunit composition. Immunoprecipitation of epitope-tagged complex and reconstitution of the complex from in vitro-translated proteins demonstrated that only the Cyc8 and Tup1 proteins were present in the complex. Hydrodynamic properties showed that these proteins have unusually large Stokes radii, low sedimentation coefficients, and high frictional ratios, all characteristic of asymmetry which partly accounts for the apparent high molecular weight. Calculation of native molecular weights from these properties indicated that the Cyc8-Tup1 complex is composed of one Cyc8 subunit and four Tup1 subunits. This composition was confirmed by reconstitution of the complex from Cyc8 and Tup1 expressed in vitro and analysis by one- and two-dimensional gel electrophoresis.     

The yeast UME6 gene product is required for transcriptional repression mediated by the CAR1 URS1 repressor binding site.

URS1 is known to be a repressor binding site in Saccharomyces cerevisiae that negatively regulates expression of many genes including CAR1 (arginase), several required for sporulation, mating type switching, inositol metabolism, and oxidative carbon metabolism. In addition to the proteins previously shown to directly bind to the URS1 site, we show here that the UME6 gene product is required for URS1 to mediate repression of gene expression in the absence of inducer. We also show that mutations in the CAR80 (CARGRI) gene are allelic to those in UME6.     

Structure of the N-terminal domain of PEX1 AAA-ATPase. Characterization of a putative adaptor-binding domain

Peroxisomes are responsible for several pathways in primary metabolism, including beta-oxidation and lipid biosynthesis. PEX1 and PEX6 are hexameric AAA-type ATPases, both of which are indispensable in targeting over 50 peroxisomal resident proteins from the cytosol to the peroxisomes. Although the tandem AAA-ATPase domains in the central region of PEX1 and PEX6 are highly similar, the N-terminal sequences are unique. To better understand the distinct molecular function of these two proteins, we analyzed the unique N-terminal domain (NTD) of PEX1. Extensive computational analysis revealed weak similarity (<10% identity) of PEX1 NTD to the N-terminal domains of other membrane-related type II AAA-ATPases, such as VCP (p97) and NSF. We have determined the crystal structure of mouse PEX1 NTD at 2.05-A resolution, which clearly demonstrated that the domain belongs to the double-psi-barrel fold family found in the other AAA-ATPases. The N-domains of both VCP and NSF are structural neighbors of PEX1 NTD with a 2.7- and 2.1-A root mean square deviation of backbone atoms, respectively. Our findings suggest that the supradomain architecture, which is composed of a single N-terminal domain followed by tandem AAA domains, is a common feature of organellar membrane-associating AAA-ATPases. We propose that PEX1 functions as a protein unfoldase in peroxisomal biogenesis, using its N-terminal putative adaptor-binding domain.