Yuji Akiyoshi scite author profile

Yuji Akiyoshi

3Publications

104Citation Statements Received

45Citation Statements Given

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Affiliations

Tokyo University of Science, The University of Tokyo, Ube (Japan)

Publications

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Fission Yeast Homolog of Murine Int-6 Protein, Encoded by Mouse Mammary Tumor Virus Integration Site, Is Associated with the Conserved Core Subunits of Eukaryotic Translation Initiation Factor 3

Akiyoshi

Clayton

Phan

et al. 2001

Journal of Biological Chemistry

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The murine int-6 locus, identified as a frequent integration site of mouse mammary tumor viruses, encodes the 48-kDa eIF3e subunit of translation initiation factor eIF3. Previous studies indicated that the catalytically active core of budding yeast eIF3 consists of five subunits, all conserved in eukaryotes, but does not contain a protein closely related to eIF3e/Int-6. Whereas the budding yeast genome does not encode a protein closely related to murine Int-6, fission yeast does encode an Int-6 ortholog, designated here Int6. We found that fission yeast Int6/eIF3e is a cytoplasmic protein associated with 40 S ribosomes. FLAG epitope-tagged Tif35, a putative core eIF3g subunit, copurified with Int6 and all five orthologs of core eIF3 subunits. An int6 deletion (int6⌬) mutant was viable but grew slowly in minimal medium. This slow growth phenotype was accompanied by a reduction in the amount of polyribosomes engaged in translation and was complemented by expression of human Int-6 protein. These findings support the idea that human and Schizosaccharomyces pombe Int-6 homologs are involved in translation. Interestingly, haploid int6⌬ cells showed unequal nuclear partitioning, possibly because of a defect in tubulin function, and diploid int6⌬ cells formed abnormal spores. We propose that Int6 is not an essential subunit of eIF3 but might be involved in regulating the activity of eIF3 for translation of specific mRNAs in S. pombe.

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14-3-3 Protein Interferes with the Binding of RNA to the Phosphorylated Form of Fission Yeast Meiotic Regulator Mei2p

et al. 2002

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The switch from mitosis to meiosis is controlled by the Pat1(Ran1) kinase-Mei2p system in Schizosaccharomyces pombe. Mei2p promotes both premeiotic DNA synthesis and meiosis I, and its RNA binding ability is essential for these two processes. Mei2p forms a dot structure in the nucleus prior to meiosis I, aided by a specific RNA species named "meiRNA". Pat1 kinase phosphorylates Mei2p on two positions and downregulates its activity. Pat1 kinase undergoes inactivation under meiotic conditions, as a result of the production of a tethering pseudosubstrate Mei3p, and accumulation of the unphosphorylated form of Mei2p commits cells to meiosis. However, the mechanism of how phosphorylation of Mei2p suppresses its activity to induce meiosis remains largely unknown. Here we show that S. pombe Rad24p, a 14-3-3 protein, functions as a negative factor for meiosis by antagonizing the function of meiRNA to promote the formation of a nuclear Mei2p dot. Rad24p binds preferentially to Mei2p phosphorylated by Pat1 kinase. It inhibits association of meiRNA to the phosphorylated form of Mei2p but not to the unphosphorylated form in vitro. We speculate that Rad24p, bound tightly to the residues phosphorylated by Pat1 kinase, may mask the RNA recognition motifs on Mei2p. This model will explain, at least partly, why phosphorylation by Pat1 kinase inhibits the meiosis-inducing activity of Mei2p.

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Computer-Aided Reaction Design. Development of a New Facile Procedure to Synthesize 2-Mercapto-3-alkoxycarboxylate on the Basis of ab Initio Molecular Orbital Calculations

1999

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This paper describes a new facial procedure to substitute a tosyloxy group in 2-(tosyloxy)alkanoate with SH(-) to yield 2-mercaptoalkanoate on the basis of ab initio MO calculations. Combination of substrate and solvent effects can control both reactivity and selectivity of reaction for 2-(tosyloxy)-3-alkoxycarboxylic acid which gave 2-mercapto-3-alkoxycarboxylic acid in good yield while its ethyl ester gave alpha,beta-unsaturated carboxylate ester as a main product. The difference of carboxylate moiety in the substrate causes remarkable change in reactivity and selectivity. To clarify origin of the difference, ab initio MO calculations in the gas phase and in DMF have been carried out. The solvent effect was considered at RHF/6-31+G with the IPCM-SCRF model. It was confirmed that the substrate with an ester fragment prefers the E1cB to the S(N)2 mechanism. In the transition state of the S(N)2 mechanism with a carboxylate ion fragment, the nucleophile SH(-) locates far from the reaction center due to the electrostatic repulsion between the COO(-) fragment and SH(-). This repulsion causes high activation barrier in the gas phase while polar solvent can reduce the barrier height. Therefore, reaction conditions can control reactivity of carboxylic acid. On the basis of analysis of the MO calculations, subsequent experiments were designed for a new dianion system to synthesize 2-pyrimidinylthio carboxylic acid from 2-tosyloxy carboxylate. We succeeded in developing a new facile method that the two reactions for thioether carried out in a one-pot procedure in excellent yield.

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Yuji Akiyoshi

Fission Yeast Homolog of Murine Int-6 Protein, Encoded by Mouse Mammary Tumor Virus Integration Site, Is Associated with the Conserved Core Subunits of Eukaryotic Translation Initiation Factor 3

14-3-3 Protein Interferes with the Binding of RNA to the Phosphorylated Form of Fission Yeast Meiotic Regulator Mei2p

Computer-Aided Reaction Design. Development of a New Facile Procedure to Synthesize 2-Mercapto-3-alkoxycarboxylate on the Basis of ab Initio Molecular Orbital Calculations

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