Taku Chibazakura

NblR Is a Novel One-Component Response Regulator in the Cyanobacterium Synechococcus elongatus PCC 7942

A response regulator, NblR, of the cyanobacterium Synechococcus elongatus PCC 7942 is known to induce expression of the nblA gene, a key factor in phycobilisome degradation (bleaching) under nutrient-deprivation conditions. In this study, we observed phosphorylation-independent regulation of NblR activity. We constructed a mutant strain expressing NblR (D57A), in which a putative phospho-accepting Asp-57 was replaced with Ala residue. Under nitrogen deprivation, this strain exhibited the typical bleaching phenotype observed in wild-type cells. Moreover, in the mutant, the nblA transcript accumulated at a level similar to that of the wild type. Our results indicate that activation of NblR is independent of phosphorylation, if any, by a cognate histidine kinase. Screening of proteins interacting with NblR by yeast two-hybrid analysis revealed two candidates, MreC and NarB, suggesting a novel mechanism that activates NblR, or other functions of the response regulator.

Cyclin A promotes S-phase entry via interaction with the replication licensing factor Mcm7.

ABSTRACT Cyclin A is known to promote S-phase entry in mammals, but its critical targets in this process have not been defined. We derived a novel human cyclin A mutant (CycA-C1), which can activate cyclin-dependent kinase but cannot promote S-phase entry, and isolated replication licensing factor Mcm7 as a factor that interacts with the wild-type cyclin A but not with the mutant. We demonstrated that human cyclin A and Mcm7 interact in the chromatin fraction. To address the physiological significance of the cyclin A-Mcm7 interaction, we isolated an Mcm7 mutant (Mcm7-3) that is capable of association with CycA-C1 and found that it can also suppress the deficiency of CycA-C1 in promoting S-phase entry. Finally, RNA interference experiments showed that the CycA-C1 mutant is defective for the endogenous cyclin A function in S-phase entry and that this defect can be suppressed by the Mcm7-3 mutant. Our findings demonstrate that interaction with Mcm7 is essential for the function of cyclin A in promoting S-phase entry.

Expression Analysis of Multiple dnaK Genes in the Cyanobacterium Synechococcus elongatus PCC 7942

We analyzed the stress responses of three dnaK homologues (dnaK1, dnaK2, and dnaK3) in the cyanobacterium Synechococcus elongatus PCC 7942. A reporter assay showed that under stress conditions the expression of only the dnaK2 gene was induced, suggesting a functional assignment of these homologues. RNA blot hybridization indicated a typical stress response of dnaK2 to heat and high-light stress. Primer extension mapping showed that dnaK2 was transcribed from similar sites under various stress conditions. Although no known sequence motif was detected in the upstream region, a 20-bp sequence element was highly conserved in dnaK2; it was essential not only for the stress induction but also for the basal expression of dnaK2. The ubiquitous upstream localization of this element in each heat shock gene suggests its important role in the cyanobacterial stress response.

An essential enzyme for phospholipid synthesis associates with the Bacillus subtilis divisome

The mechanism by which the membrane synthetic machinery might be co‐organized with the cell‐division architecture during the bacterial cell cycle remains to be investigated. We characterized a key enzyme of phospholipid and fatty acid synthesis in Bacillus subtilis, the acyl–acyl carrier protein phosphate acyltransferase (PlsX), and identified it as a component of the cell‐division machinery. Comprehensive interaction analysis revealed that PlsX interacts with FtsA, the FtsZ‐anchoring protein. PlsX mainly localized at the potential division site independent of FtsA and FtsZ and then colocalized with FtsA. By multidirectional approaches, we revealed that the Z‐ring stabilizes the association of PlsX at the septum and pole. The localization of PlsX is also affected by the progression of DNA replication. PlsX is needed for cell division and its inactivation leads to aberrant Z‐ring formation. We propose that PlsX localization is prior to Z‐ring formation in the hierarchy of septum formation events and that PlsX is important for co‐ordinating membrane synthesis with cell division in order to properly complete septum formation.

Intensive DNA Replication and Metabolism during the Lag Phase in Cyanobacteria

Unlike bacteria such as Escherichia coli and Bacillus subtilis, several species of freshwater cyanobacteria are known to contain multiple chromosomal copies per cell, at all stages of their cell cycle. We have characterized the replication of multi-copy chromosomes in the cyanobacterium Synechococcus elongatus PCC 7942 (hereafter Synechococcus 7942). In Synechococcus 7942, the replication of multi-copy chromosome is asynchronous, not only among cells but also among multi-copy chromosomes. This suggests that DNA replication is not tightly coupled to cell division in Synechococcus 7942. To address this hypothesis, we analysed the relationship between DNA replication and cell doubling at various growth phases of Synechococcus 7942 cell culture. Three distinct growth phases were characterised in Synechococcus 7942 batch culture: lag phase, exponential phase, and arithmetic (linear) phase. The chromosomal copy number was significantly higher during the lag phase than during the exponential and linear phases. Likewise, DNA replication activity was higher in the lag phase cells than in the exponential and linear phase cells, and the lag phase cells were more sensitive to nalidixic acid, a DNA gyrase inhibitor, than cells in other growth phases. To elucidate physiological differences in Synechococcus 7942 during the lag phase, we analysed the metabolome at each growth phase. In addition, we assessed the accumulation of central carbon metabolites, amino acids, and DNA precursors at each phase. The results of these analyses suggest that Synechococcus 7942 cells prepare for cell division during the lag phase by initiating intensive chromosomal DNA replication and accumulating metabolites necessary for the subsequent cell division and elongation steps that occur during the exponential growth and linear phases.

Interactions Between Histidine Kinase NblS and the Response Regulators RpaB and SrrA are Involved in the Bleaching Process of the Cyanobacterium Synechococcus elongatus PCC 7942

Cyanobacteria have developed a light-harvesting antenna complex known as the phycobilisome. When cells are starved for nutrients or exposed to high light, the phycobilisome is rapidly degraded (bleaching). It has been suggested that in the cyanobacterium Synechococcus elongatus PCC 7942, the bleaching process is regulated by a two-component histidine kinase, NblS. To clarify the signaling pathway involving NblS, we identified the NblS-interacting response regulators RpaB and SrrA. In vitro assays using recombinant proteins showed that both RpaB and SrrA can receive phosphoryl groups from autophosphorylated NblS; the NblS-interacting protein SipA clearly enhances the phosphotransfer activity from NblS to RpaB and SrrA. In addition, NblS prefers SrrA over RpaB as the phosphotransfer target with or without SipA. Gel mobility shift assay revealed that both RpaB and SrrA can bind to the upstream region of nblA, a major regulatory factor in the bleaching process. nblA transcript accumulates in nblS or rpaB mutants even under normal growth conditions, while in the srrA disruptant the nblA transcripts are slightly up-regulated under stress conditions. These observations suggest that the bleaching signal transduction pathway via NblS is regulated by RpaB and that SrrA is partially involved.

Protection of psbAII Transcript from Ribonuclease Degradation in Vitro by DnaK2 and DnaJ2 Chaperones of the Cyanobacterium Synechococcus elongatus PCC 7942

Three dnaK and four dnaJ genes have been identified in the genome of cyanobacterium Synechococcus elongatus PCC 7942. Our comprehensive analysis of yeast two-hybrid screening revealed a specific interaction among DnaK2, DnaJ2, and RNase E, an essential endoribonuclease. We examined the effects of DnaK2 and DnaJ2 on RNase E activity by monitoring the digestion of psbAII transcript in vitro. The addition of DnaK2 and DnaJ2 obviously inhibited RNase E activity in an ATP-dependent manner. These results suggest that DnaK2 and DnaJ2 are involved in RNA degradation through interaction with RNase E.

Cyclin A overexpression induces chromosomal double-strand breaks in mammalian cells.

Cyclin A is a major regulator in vertebrate cell cycle, associated with cyclin-dependent kinase (Cdk), and involved in S-phase progression and entry into mitosis. It has been known that cyclin A overexpression not only causes premature S-phase entry but also induces prolongation of S phase. Here we show that ectopic expression of cyclin A leads to extensive γ−H2AX focus formation, which is indicative of DNA double-strand breaks. Likewise, cyclin E, but not cyclin B1 and cyclin D1, also induced the γ−H2AX focus formation, suggesting that these DNA lesions may be induced via aberrant DNA replication process. Moreover, the γ−H2AX focus formation was suppressed by co-expressing p21Cip1/Waf1 or dominant-negative Cdk2 mutant, suggesting that aberrant cyclin A-Cdk2 activation induces the chromosomal double-strand breaks.

Regulation of the Response Regulator Gene degU through the Binding of SinR/SlrR and Exclusion of SinR/SlrR by DegU in Bacillus subtilis

Bacillus subtilis DegU is a response regulator of the DegS-DegU two-component regulatory system. Phosphorylated DegU (DegU-P) controls many genes and biological processes, such as exoprotease and γ-polyglutamic acid production, in addition to the degU gene, by binding to target gene promoters. Nonphosphorylated DegU and low levels of DegU-P are required for swarming motility and genetic competence. The DNA-binding repressors SinR and SlrR are part of a double-negative feedback loop and comprise the epigenetic switch governing biofilm formation. In this study, we found that SinR repressed degU. Furthermore, SlrR, which interacts with SinR through protein-protein interaction, seems to have an active role in degU expression in in vivo lacZ analysis. An in vitro transcription assay supported this observation. An electrophoretic mobility shift assay (EMSA) showed that SinR bound to the degU promoter and that SlrR formed a complex with SinR on the degU promoter. In EMSA, DegU-P excluded the SinR/SlrR complex but not SinR from the degU promoter in the presence of RNA polymerase. These findings suggest that DegU-P interacts with SlrR. In support of this hypothesis, disruption of the slrR gene resulted in decreased degU expression. This newly identified regulatory mechanism for degU is considered to be sequential transcription factor replacement.

Complete Genome Sequence of Enterococcus mundtii QU 25, an Efficient l-(+)-Lactic Acid-Producing Bacterium

Enterococcus mundtii QU 25, a non-dairy bacterial strain of ovine faecal origin, can ferment both cellobiose and xylose to produce l-lactic acid. The use of this strain is highly desirable for economical l-lactate production from renewable biomass substrates. Genome sequence determination is necessary for the genetic improvement of this strain. We report the complete genome sequence of strain QU 25, primarily determined using Pacific Biosciences sequencing technology. The E. mundtii QU 25 genome comprises a 3 022 186-bp single circular chromosome (GC content, 38.6%) and five circular plasmids: pQY182, pQY082, pQY039, pQY024, and pQY003. In all, 2900 protein-coding sequences, 63 tRNA genes, and 6 rRNA operons were predicted in the QU 25 chromosome. Plasmid pQY024 harbours genes for mundticin production. We found that strain QU 25 produces a bacteriocin, suggesting that mundticin-encoded genes on plasmid pQY024 were functional. For lactic acid fermentation, two gene clusters were identified—one involved in the initial metabolism of xylose and uptake of pentose and the second containing genes for the pentose phosphate pathway and uptake of related sugars. This is the first complete genome sequence of an E. mundtii strain. The data provide insights into lactate production in this bacterium and its evolution among enterococci.