Atsuko Shirai

Mutagenicity of pyrrolizidine alkaloids in the Salmonella/mammalian-microsome test.

The mutagenicities of 7 pyrrolizidine alkaloids to Salmonella typhimurium TA100 were demonstrated by a modified Amess method. The pyrrolizidine alkaloids found to be mutagenic were clivorine, fukinotoxin, heliotrine, lasiocarpine, ligularidine, LX201 and senkirkine. Pre-incubation of these alkaloids with S9 mix and bacteria in a liquid medium was essential for demonstration of their mutagenicities.

pDUAL, a multipurpose, multicopy vector capable of chromosomal integration in fission yeast

A novel series of plasmid vectors named pDUAL have been developed. These vectors enable one to introduce not only multicopies of genes with episomal maintenance but also a single copy with chromosomal integration into the fission yeast, Schizosaccharomyces pombe. The multicopy plasmids can be easily converted to fragments for chromosomal integration by digestion of the plasmids with a certain restriction endonuclease before transformation of the yeast cells. The resultant fragments, lacking the autonomously replicating sequence, are designed for targeting into the chromosomal leu1 locus by homologous recombination. Whether the transformants are the results of episomal maintenance of the plasmid or homologous gene targeting can be readily checked by their requirement for uracil or leucine, or by the PCR diagnostic analysis. Furthermore, we propose the use of pDUAL derivatives for PCR‐based chromosomal tagging of a gene to introduce several tags into 5′‐terminus of a gene, employing a set of primers. Using these all‐in‐one vectors, a suitable mode of expression of a cloned gene can be selected for individual analysis without any complicated subcloning processes. Copyright

Global analysis of gel mobility of proteins and its use in target identification

SDS-PAGE is a basic method that has long been used for separation of proteins according to their molecular sizes. Despite its simplicity, it provides information on characteristics of proteins beyond their molecular masses because gel mobility of proteins often reflects their physicochemical properties and post-translational modifications. Here we report on a global analysis of gel mobility of the proteome, which we term the “mobilitome,” covering 93.4% of the fission yeast proteome. To our surprise, more than 40% of proteins did not migrate to their calculated positions. Statistical analyses revealed that the discrepancy was largely dependent on the hydrophobicity of proteins. This experimental data set, with a high coverage rate of real mobility, made it feasible to identify proteins detected on the gel without using any specialized techniques. This approach enabled us to detect previously unknown post-translational modifications of a protein; for example, we revealed that eIF5A is novel substrate of a Sir2-related deacetylase Hst2. Furthermore, we concomitantly identified twelve acetylated and eight methylated proteins using specific anti-acetylated and anti-methylated lysine antibodies, most of which had not been known to be subject to the modifications. Thus, we propose the general usefulness of the mobilitome and electrophoresis-based methodology for the identification and characterization of proteins detected on the gel.

Marine antifungal theonellamides target 3β-hydroxysterol to activate Rho1 signaling

Linking bioactive compounds to their cellular targets is a central challenge in chemical biology. Here we report the mode of action of theonellamides, bicyclic peptides derived from marine sponges. We generated a chemical-genomic profile of theonellamide F using a collection of fission yeast strains in which each open reading frame (ORF) is expressed under the control of an inducible promoter. Clustering analysis of the Gene Ontology (GO) terms associated with the genes that alter drug sensitivity suggested a mechanistic link between theonellamide and 1,3-beta-D-glucan synthesis. Indeed, theonellamide F induced overproduction of 1,3-beta-D-glucan in a Rho1-dependent manner. Subcellular localization and in vitro binding assays using a fluorescent theonellamide derivative revealed that theonellamides specifically bind to 3beta-hydroxysterols, including ergosterol, and cause membrane damage. The biological activity of theonellamides was alleviated in mutants defective in ergosterol biosynthesis. Theonellamides thus represent a new class of sterol-binding molecules that induce membrane damage and activate Rho1-mediated 1,3-beta-D-glucan synthesis.

Factors Modulating Mutagenicity in Microbial Tests

The preincubation of test compound, bacterial tester strain, and S-9 mix or buffer before pouring a minimal-glucose agar plate enhanced the sensitivity of mutation test and increased the spectrum of mutagens detected. Addition of NADH and ATP in S-9 mix enhanced the mutagenicity of some compounds. Addition of norharman in the preincubation mixture made it possible to detect a marginal or weak mutagenicity of certain types of mutagens. Addition of riboflavin revealed the mutagenicity of azo compounds. Glycosidase was required to detect the mutagenicity of glycosides or natural products.

Methylation of Ribosomal Protein L42 Regulates Ribosomal Function and Stress-adapted Cell Growth *□

Lysine methylation is one of the most common protein modifications. Although lysine methylation of histones has been extensively studied and linked to gene regulation, that of non-histone proteins remains incompletely understood. Here, we show a novel regulatory role of ribosomal protein methylation. Using an in vitro methyltransferase assay, we found that Schizosaccharomyces pombe Set13, a SET domain protein encoded by SPAC688.14, specifically methylates lysine 55 of ribosomal protein L42 (Rpl42). Mass spectrometric analysis revealed that endogenous Rpl42 is monomethylated at lysine 55 in wild-type S. pombe cells and that the methylation is lost in Δset13 mutant cells. Δset13 and Rpl42 methylation-deficient mutant S. pombe cells showed higher cycloheximide sensitivity and defects in stress-responsive growth control compared with wild type. Genetic analyses suggested that the abnormal growth phenotype was distinct from the conserved stress-responsive pathway that modulates translation initiation. Furthermore, the Rpl42 methylation-deficient mutant cells showed a reduced ability to survive after entering stationary phase. These results suggest that Rpl42 methylation plays direct roles in ribosomal function and cell proliferation control independently of the general stress-response pathway.

A series of promoters for constitutive expression of heterologous genes in fission yeast

Inducible/repressible promoters are useful for the maintenance of toxic genes or timely expression. For ectopic expression of cloned genes in the fission yeast Schizosaccharomyces pombe, the thiamine‐regulatable nmt1 promoter has been widely used, since the transcriptional activity of this promoter can be controlled by thiamine. However, this property sometimes limits a certain type of research, since the expression inevitably requires cells to be cultivated under the conditions that induce promoter activation. To allow constitutive expression of heterologous genes, we cloned three promoters of cam1+, tif51+ and ef1a‐c+. Construction of a series of vectors comprising these promoters and their introduction into the fission yeast cells demonstrated that the activity was different among these promoters but was not affected by cultured media commonly used in fission yeast. Therefore, a promoter with appropriate strength would be selectable from these promoters, depending on the genes to be expressed. Copyright

Impact of nucleic acid and methylated H3K9 binding activities of Suv39h1 on its heterochromatin assembly

SUV39H is the major histone H3 lysine 9 (H3K9)-specific methyltransferase that targets pericentric regions and is crucial for assembling silent heterochromatin. SUV39H recognizes trimethylated H3K9 (H3K9me3) via its chromodomain (CD), and enriched H3K9me3 allows SUV39H to target specific chromosomal regions. However, the detailed targeting mechanisms, especially for naïve chromatin without preexisting H3K9me3, are poorly understood. Here we show that Suv39h1’s CD (Suv39h1-CD) binds nucleic acids, and this binding is important for its function in heterochromatin assembly. Suv39h1-CD had higher binding affinity for RNA than DNA, and its ability to bind nucleic acids was independent of its H3K9me3 recognition. Suv39h1 bound major satellite RNAs in vivo, and knockdown of major satellite RNAs lowered Suv39h1 retention on pericentromere. Suv39h1 mutational studies indicated that both the nucleic acid–binding and H3K9me–binding activities of Suv39h1-CD were crucial for its pericentric heterochromatin assembly. These results suggest that chromatin-bound RNAs contribute to creating SUV39H’s target specificity. DOI: http://dx.doi.org/10.7554/eLife.25317.001

A novel series of vectors for chromosomal integration in fission yeast

A series of fission yeast targeting vectors that can be used for wild-type strains having no selectable markers have been designed. The functions of one of three marker genes, lys1(+), arg1(+), and his3(+), involved in amino acid synthesis, are impaired by integration of the fragments generated by restriction enzyme digestion of the plasmids. Successful integration of the fragments into the targeted loci can be readily verified by their requirement for amino acids, or by the PCR diagnostic analysis. Since these selection markers are not used commonly in fission yeast, these plasmids are likely to facilitate studies that require the co-expression of genes such as co-localization and co-immunoprecipitation experiments, by employing them in combination with most of the previously reported markers.

Mitochondrial localization of fission yeast manganese superoxide dismutase is required for its lysine acetylation and for cellular stress resistance and respiratory growth

Manganese-dependent superoxide dismutase (MnSOD) is localized in the mitochondria and is important for oxidative stress resistance. Although transcriptional regulation of MnSOD has been relatively well studied, much less is known about the proteins posttranslational regulation. In budding yeast, MnSOD is activated after mitochondrial import by manganese ion incorporation. Here we characterize posttranslational modification of MnSOD in the fission yeast Schizosaccharomyces pombe. Fission yeast MnSOD is acetylated at the 25th lysine residue. This acetylation was diminished by deletion of N-terminal mitochondrial targeting sequence, suggesting that MnSOD is acetylated after import into mitochondria. Mitochondrial localization of MnSOD is not essential for the enzyme activity, but is crucial for oxidative stress resistance and growth under respiratory conditions of fission yeast. These results suggest that, unlike the situation in budding yeast, S. pombe MnSOD is already active even before mitochondrial localization; nonetheless, mitochondrial localization is critical to allow the cell to cope with reactive oxygen species generated inside or outside of mitochondria.