Satoshi Harashima

The PHO84 gene specifies Pi-transport in Saccharomyces cerevisiae. A DNA fragment bearing the PHO84 gene was cloned by its ability to complement constitutive synthesis of repressible acid phosphatase of pho84 mutant cells. Its nucleotide sequence predicted a protein of 596 amino acids with a sequence homologous to that of a superfamily of sugar transporters. Hydropathy analysis suggested that the secondary structure of the PHO84 protein consists of two blocks of six transmembrane domains separated by 74 amino acid residues. The cloned PH084 DNA restored the Pi transport activity of pho84 mutant cells. The PHO84 transcription was regulated by Pi like those of the PHO5, PHO8, and PHO81 genes. A PHO84-lacZ fusion gene produced beta-galactosidase activity under the regulation of Pi, and the activity was suggested to be bound to a membrane fraction. Gene disruption of PHO84 was not lethal. By comparison of nucleotide sequences and by tetrad analysis with GAL80 as a standard, the PHO84 locus was mapped at a site beside the TUB3 locus on the left arm of chromosome XIII.

The PHO84 gene specifies Pi-transport in Saccharomyces cerevisiae. A DNA fragment bearing the PHO84 gene was cloned by its ability to complement constitutive synthesis of repressible acid phosphatase of pho84 mutant cells. Its nucleotide sequence predicted a protein of 596 amino acids with a sequence homologous to that of a superfamily of sugar transporters. Hydropathy analysis suggested that the secondary structure of the PHO84 protein consists of two blocks of six transmembrane domains separated by 74 amino acid residues. The cloned PH084 DNA restored the Pi transport activity of pho84 mutant cells. The PHO84 transcription was regulated by Pi like those of the PHO5, PHO8, and PHO81 genes. A PHO84-lacZ fusion gene produced beta-galactosidase activity under the regulation of Pi, and the activity was suggested to be bound to a membrane fraction. Gene disruption of PHO84 was not lethal. By comparison of nucleotide sequences and by tetrad analysis with GAL80 as a standard, the PHO84 locus was mapped at a site beside the TUB3 locus on the left arm of chromosome XIII.

A higher plant homologue to the high-affinity phosphate transporter gene of yeast (Saccharomyces cerevisiae) PHO84 was isolated from Arabidopsis thaliana. Expression of the Arabidopsis gene PHT1 at high levels in tobacco-cultured cells increased the rate of phosphate uptake. The uptake activity attributable to the transgene was inhibited by protonophores, suggesting an H+ cotransport mechanism of phosphate uptake, and had a Km of 3.1 microM which is within limits characteristic of high-affinity transport mechanisms. These results indicate that PHT1 encodes a high-affinity phosphate transporter. The transgenic cells exhibited increased biomass production when the supply of phosphate was limited, establishing gene engineering of phosphate transport as one approach toward enhancing plant cell growth.

The GCD2 protein is a translational repressor of GCN4, the transcriptional activator of multiple amino acid biosynthetic genes in Saccharomyces cerevisiae. We present evidence that GCD2 has a general function in the initiation of protein synthesis in addition to its gene-specific role in translational control of GCN4 expression. Two temperature-sensitive lethal gcd2 mutations result in sensitivity to inhibitors of protein synthesis at the permissive temperature, and the gcd2-503 mutation leads to reduced incorporation of labeled leucine into total protein following a shift to the restrictive temperature of 36 degrees C. The gcd2-503 mutation also results in polysome runoff, accumulation of inactive 80S ribosomal couples, and accumulation of at least one of the subunits of the general translation initiation factor 2 (eIF-2 alpha) in 43S-48S particles following a shift to the restrictive temperature. The gcd2-502 mutation causes accumulation of 40S subunits in polysomes, known as halfmers, that are indicative of reduced 40S-60S subunit joining at the initiation codon. These phenotypes suggest that GCD2 functions in the translation initiation pathway at a step following the binding of eIF-2.GTP.Met-tRNA(iMet) to 40S ribosomal subunits. consistent with this hypothesis, we found that inhibiting 40S-60S subunit joining by deleting one copy (RPL16B) of the duplicated gene encoding the 60S ribosomal protein L16 qualitatively mimics the phenotype of gcd2 mutations in causing derepression of GCN4 expression under nonstarvation conditions. However, deletion of RPL16B also prevents efficient derepression of GCN4 under starvation conditions, indicating that lowering the concentration of 60S subunits and reducing GCD2 function affect translation initiation at GCN4 in different ways. This distinction is in accord with a recently proposed model for GCN4 translational control in which ribosomal reinitiation at short upstream open reading frames in the leader of GCN4 mRNA is suppressed under amino acid starvation conditions to allow for increased reinitiation at the GCN4 start codon.