Cellular responses to compound stress induced by atmospheric-pressure plasma in fission yeast.

The stress response is one of the most fundamental cellular processes. Although the molecular mechanisms underlying responses to a single stressor have been extensively studied, cellular responses to multiple stresses remain largely unknown. Here, we characterized fission yeast cellular responses to a novel stress inducer, non-thermal atmospheric-pressure plasma. Plasma irradiation generates ultraviolet radiation, electromagnetic fields and a variety of chemically reactive species simultaneously, and thus can impose multiple stresses on cells. We applied direct plasma irradiation to fission yeast and showed that strong plasma irradiation inhibited fission yeast growth. We demonstrated that mutants lacking sep1 and ace2, both of which encode transcription factors required for proper cell separation, were resistant to plasma irradiation. Sep1-target transcripts were downregulated by mild plasma irradiation. We also demonstrated that plasma irradiation inhibited the target of rapamycin kinase complex 1 (TORC1). These observations indicate that two pathways, namely the Sep1-Ace2 cell separation pathway and TORC1 pathway, operate when fission yeast cope with multiple stresses induced by plasma irradiation.

Influence of mutation in the regulatory domain of α-isopropylmalate synthase from Saccharomyces cerevisiae on its activity and feedback inhibition.

Isoamyl alcohol (i-AmOH) is produced from α-ketoisocaproate in the l-leucine biosynthetic pathway in yeast and controlled by the negative feedback regulation of α-isopropylmalate synthase (IPMS), which senses the accumulation of l-leucine. It is known that i-AmOH production increases when mutations in the regulatory domain reduce the susceptibility to feedback inhibition. However, the impact of mutations in this domain on the IPMS activity has not been examined. In this study, we obtained 5 IPMS mutants, encoding the LEU4 gene, N515D/S520P/S542F/A551D/A551V, that are tolerant to 5,5,5-trifluoro-dl-leucine. All mutant proteins were purified and examined for both IPMS activity and negative feedback activity by in vitro experiments. The results showed that not only the negative-feedback regulation by l-leucine was almost lost in all mutants, but also the IPMS activity was greatly decreased and the difference in IPMS activity among Leu4 mutants in the presence of l-leucine was significantly correlated with i-AmOH production.

The cis element and factors required for condensin recruitment to chromosomes.

Condensins are required for segregation of rDNA repeats in concert with Fob1, a replication fork block protein binding at the replication fork barrier (RFB) site within rDNA in yeast. Here, we found that the RFB site functions as a cis element for Fob1-dependent condensin recruitment onto chromosomes. Replication fork blockage itself is not necessary for condensin recruitment. Instead, by genetic screening, we identified three genes, TOF2, CSM1, and LRS4, required both for condensin recruitment to the RFB site and for assuring the segregation of rDNA repeats. Hierarchical binding of Fob1, these three proteins and condensin, and interactions between Csm1/Lrs4 and multiple subunits of condensin were observed. These results suggest that three proteins control protein interactions linking between Fob1 and condensin, and contribute to ensuring the faithful segregation of rDNA repeats. Our study also suggests that recruitment of condensin onto chromosomes requires cis elements and recruiters that physically interact with condensin.

RNA polymerase I transcription obstructs condensin association with 35S rRNA coding regions and can cause contraction of long repeat in Saccharomyces cerevisiae.

In many eukaryotic cells, the ribosomal RNA gene (rDNA) is composed of a highly repetitive structure. Previously, we reported the isolation of condensin mutants of Saccharomyces cerevisiae that were defective in carrying long rDNA repeat due to the loss of the replication fork barrier (RFB) protein Fob1p; thus the repeat in the mutants were dramatically contracted. The reintroduction of the FOB1 gene suppressed the contraction of the repeat. It was found that condensin mainly localized at the RFB site in a FOB1-dependent fashion. Here, we show that RNA polymerase I transcription interferes with condensin association with 35S rRNA coding regions in fob1 cells and causes dramatic contraction of rDNA repeat in the fob1 condensin double mutant. Inactivation of RNA polymerase I suppresses the dramatic contraction of the rDNA repeat in the fob1 condensin double mutant. These results suggest that association of condensin with the RFB site outside the active transcription region avoids the dramatic contraction of the rDNA repeat. We also found that the stimulation of RNA polymerase II transcription within the rDNA repeat decreased condensin association with actively transcribed regions. Thus, a characteristic of condensin is that its association with the chromatin is interfered by transcription.

Expression of rRNA genes and nucleolus formation at ectopic chromosomal sites in the yeast Saccharomyces cerevisiae.

We constructed yeast strains in which rRNA gene repeats are integrated at ectopic sites in the presence or absence of the native nucleolus. At all three ectopic sites analyzed, near centromere CEN5, near the telomere of chromosome VI-R, and in middle of chromosome V-R (mid-V-R), a functional nucleolus was formed, and no difference in the expression of rRNA genes was observed. When two ribosomal DNA (rDNA) arrays are present, one native and the other ectopic, there is codominance in polymerase I (Pol I) transcription. We also examined the expression of a single rDNA repeat integrated into ectopic loci in strains with or without the native RDN1 locus. In a strain with reduced rRNA gene copies at RDN1 (approximately 40 copies), the expression of a single rRNA gene copy near the telomere was significantly reduced relative to the other ectopic sites, suggesting a less-efficient recruitment of the Pol I machinery from the RDN1 locus. In addition, we found a single rRNA gene at mid-V-R was as active as that within the 40-copy RDN1. Combined with the results of activity analysis of a single versus two tandem copies at CEN5, we conclude that tandem repetition is not required for efficient rRNA gene transcription.

Condensin loaded onto the replication fork barrier site in the rRNA gene repeats during S phase in a FOB1-dependent fashion to prevent contraction of a long repetitive array in Saccharomyces cerevisiae.

An average of 200 copies of the rRNA gene (rDNA) is clustered in a long tandem array in Saccharomyces cerevisiae. FOB1 is known to be required for expansion/contraction of the repeats by stimulating recombination, thereby contributing to the maintenance of the average copy number. In Deltafob1 cells, the repeats are still maintained without any fluctuation in the copy number, suggesting that another, unknown system acts to prevent repeat contraction. Here, we show that condensin acts together with FOB1 in a functionally complemented fashion to maintain the long tandem repeats. Six condensin mutants possessing severely contracted rDNA repeats were isolated in Deltafob1 cells but not in FOB1+ cells. We also found that the condensin complex associated with the nontranscribed spacer region of rDNA with a major peak coincided with the replication fork barrier (RFB) site in a FOB1-dependent fashion. Surprisingly, condensin association with the RFB site was established during S phase and was maintained until anaphase. These results indicate that FOB1 plays a novel role in preventing repeat contraction by regulating condensin association and suggest a link between replication termination and chromosome condensation and segregation.

Tor pathway regulates Rrn3p-dependent recruitment of yeast RNA polymerase I to the promoter but does not participate in alteration of the number of active genes.

Yeast cells entering into stationary phase decrease rRNA synthesis rate by decreasing both the number of active genes and the transcription rate of individual active genes. Using chromatin immunoprecipitation assays, we found that the association of RNA polymerase I with the promoter and the coding region of rDNA is decreased in stationary phase, but association of transcription factor UAF with the promoter is unchanged. Similar changes were also observed when growing cells were treated with rapamycin, which is known to inhibit the Tor signaling system. Rapamycin treatment also caused a decrease in the amount of Rrn3p-polymerase I complex, similar to stationary phase. Because recruitment of Pol I to the rDNA promoter is Rrn3p-dependent as shown in this work, these data suggest that the decrease in the transcription rate of individual active genes in stationary phase is achieved by the Tor signaling system acting at the Rrn3p-dependent polymerase recruitment step. Miller chromatin spreads of cells treated with rapamycin and cells in post-log phase confirm this conclusion and demonstrate that the Tor system does not participate in alteration of the number of active genes observed for cells entering into stationary phase.

Replication fork block protein, Fob1, acts as an rDNA region specific recombinator in S. cerevisiae.

BACKGROUND: The analysis of homologous recombination in the tandemly repeating rDNA array of Saccharomyces cerevisiae should provide useful information about the stability of not only the rDNA repeat but also the abundant repeated sequences on higher eukaryotic genomes. However, the data obtained so far are not yet conclusive, due to the absence of a reliable assay for detecting products of recombination in the rDNA array. RESULTS: We developed an assay method to detect the products of unequal sister-chromatid recombination (marker-duplication products) in yeast rDNA. This assay, together with the circular rDNA detection assay, was used for the analysis. Marker-duplication occurred throughout the rDNA cluster, preferentially between nearby repeat units. The FOB1 and RAD52 genes were required for both types of recombinant formation. FOB1 showed a gene dosage effect on not only the amounts of both recombinants, but also on the copy number of the repeat. However, unlike the RAD52 gene, the FOB1 gene was not involved in homologous recombination in a non-rDNA locus. In addition, the marker-duplication products were drastically decreased in the mre11 mutant. CONCLUSION: Our data demonstrate that FOB1- and RAD52-dependent homologous recombination cause the gain and loss of a few copies of the rDNA unit, and this must be a basic mechanism responsible for amplification and reduction of the rDNA copy number. In addition, FOB1 may also play a role in the copy number regulation of rDNA tandem repeats.