Genome-wide survey of mRNA half-lives in Bacillus subtilis identifies extremely stable mRNAs.

We have used DNA microarrays to survey rates of mRNA decay on a genomic scale in early stationary-phase cultures of Bacillus subtilis. The decay rates for mRNAs corresponding to about 1500 genes could be estimated. About 80% of these mRNAs had a half-life of less than 7 min. More than 30 mRNAs, including both mono- and polycistronic transcripts, were found to be extremely stable, i.e. to have a half-life of > or =15 min. Only two such transcripts were known previously in B. subtilis. The results provide the first overview of mRNA decay rates in a gram-positive bacterium and help to identify polycistronic operons. We could find no obvious correlation between the stability of an mRNA and the function of the encoded protein. We have also not found any general features in the 5' regions of mRNAs that distinguish stable from unstable transcripts. The identified set of extremely stable mRNAs may be useful in the construction of stable recombinant genes for the overproduction of biomolecules in Bacillus species.

Preparation and crystallization of a Bacillus subtilis arsenate reductase.

Arsenate reductase (AR) in B. subtilis is encoded by the chromosomal arsC gene. Together with arsB and arsR, arsC participates in detoxification processes for the arsenate and arsenite ions. Full-length arsenate reductase without any modification has been expressed in Escherichia coli and purified in a soluble form. The recombinant protein has been crystallized at 277 K using polyethyleneglycol (PEG) or poly(ethyleneglycol) methyl ether (PME) as the main precipitant. At least two forms of crystals large enough for data collection have been obtained from wild-type protein under different conditions. An orthorhombic crystal diffracted to beyond 2.2 A with space group P2(1)2(1)2(1) and unit-cell parameters a = 51.22, b = 91.62, c = 101.93 A. A near-complete data set has been collected to 2.5 A. The application of the flash-annealing technique was crucial for high resolution during the data collection. The SeMet-substituted AR has also been produced and crystallized under very similar conditions as the wild type, but the unit-cell parameters are very different. The crystals of the SeMet protein diffracted to higher resolution than those of the wild type.

The carboxin-binding site on Paracoccus denitrificans succinate:quinone reductase identified by mutations.

Succinate:quinone reductase catalyzes electron transfer from succinate to quinone in aerobic respiration. Carboxin is a specific inhibitor of this enzyme from several different organisms. We have isolated mutant strains of the bacterium Paracoccus denitrificans that are resistant to carboxin due to mutations in the succinate:quinone reductase. The mutations identify two amino acid residues, His228 in SdhB and Asp89 in SdhD, that most likely constitute part of a carboxin-binding site. This site is in the same region of the enzyme as the proposed active site for ubiquinone reduction. From the combined mutant data and structural information derived from Escherichia coli and Wolinella succinogenes quinol:fumarate reductase, we suggest that carboxin acts by blocking binding of ubiquinone to the active site. The block would be either by direct exclusion of ubiquinone from the active site or by occlusion of a pore that leads to the active site.

The distal heme center in Bacillus subtilis succinate:quinone reductase is crucial for electron transfer to menaquinone.

Succinate:quinone reductases are membrane-bound enzymes that catalyze electron transfer from succinate to quinone. Some enzymes in vivo reduce ubiquinone (exergonic reaction) whereas others reduce menaquinone (endergonic reaction). The succinate:menaquinone reductases all contain two heme groups in the membrane anchor of the enzyme: a proximal heme (heme b(P)) located close to the negative side of the membrane and a distal heme (heme b(D)) located close to the positive side of the membrane. Heme b(D) is a distinctive feature of the succinate:menaquinone reductases, but the role of this heme in electron transfer to quinone has not previously been analyzed. His28 and His113 are the axial ligands to heme b(D) in Bacillus subtilis succinate:menaquinone reductase. We have individually replaced these His residues with Leu and Met, respectively, resulting in assembled membrane-bound enzymes. The H28L mutant enzyme lacks succinate:quinone reductase activity probably due to a defective quinone binding site. The H113M mutant enzyme contains heme b(D) with raised midpoint potential and is impaired in electron transfer to menaquinone. Our combined experimental data show that the heme b(D) center, into which we include a quinone binding site, is crucial for succinate:menaquinone reductase activity. The results support a model in which menaquinone is reduced on the positive side of the membrane and the transmembrane electrochemical potential provides driving force for electron transfer from succinate via heme b(P) and heme b(D) to menaquinone.

Genes required for cytochrome c synthesis in Bacillus subtilis.

Cytochromes of c-type contain covalently bound haem and in bacteria are located on the periplasmic side of the cytoplasmic membrane. More than eight different gene products have been identified as being specifically required for the synthesis of cytochromes c in Gram-negative bacteria. Corresponding genes are not found in the genome sequences of Gram-positive bacteria. Using two random mutagenesis approaches, we have searched for cytochrome c biogenesis genes in the Gram-positive bacterium Bacillus subtilis. Three genes, resB, resC and ccdA, were identified. CcdA has been found previously and is required for a late step in cytochrome c synthesis and also plays a role in spore synthesis. No function has previously been assigned for ResB and ResC but these predicted membrane proteins show sequence similarity to proteins required for cytochrome c synthesis in chloroplasts. Attempts to inactivate resB and resC in B. subtilis have indicated that these genes are essential for growth. We demonstrate that various nonsense mutations in resB or resC can block synthesis of cytochromes c with no effect on other types of cytochromes and little effect on sporulation and growth. The results strongly support the recent proposal that Gram-positive bacteria, cyanobacteria, epsilon-proteobacteria, and chloroplasts have a similar type of machinery for cytochrome c synthesis (System II), which is very different from those of most Gram-negative bacteria (System I) and mitochondria (System III).

Enterococcus faecalis V583 contains a cytochrome bd-type respiratory oxidase.

We have cloned an Enterococcus faecalis gene cluster, cydABCD, which when expressed in Bacillus subtilis results in a functional cytochrome bd terminal oxidase. Our results indicate that E. faecalis V583 cells have the capacity of aerobic respiration when grown in the presence of heme.

Efficient spore synthesis in Bacillus subtilis depends on the CcdA protein.

CcdA is known to be required for the synthesis of c-type cytochromes in Bacillus subtilis, but the exact function of this membrane protein is not known. We show that CcdA also plays a role in spore synthesis. The expression of ccdA and the two downstream genes yneI and yneJ was analyzed. There is a promoter for each gene, but there is only one transcription terminator, located after the yneJ gene. The promoter for ccdA was found to be weak and was active mainly during the transition from exponential growth to stationary phase. The promoters for yneI and yneJ were both active in the exponential growth phase. The levels of the CcdA and YneJ proteins in the membrane were consistent with the observed promoter activities. The ccdA promoter activity was independent of whether the ccdA-yneI-yneJ gene products were absent or overproduced in the cell. It is shown that the four known cytochromes c in B. subtilis and the YneI and YneJ proteins are not required for sporulation. The combined data from analysis of sporulation-specific sigma factor activity, resistance properties of spores, and spore morphology indicate that CcdA deficiency affects stage V in sporulation. We conclude that CcdA, YneI, and YneJ are functionally unrelated proteins and that the role of CcdA in cytochrome c and spore synthesis probably relates to sulfhydryl redox chemistry on the outer surface of the cytoplasmic membrane.

The Bacillus subtilis ctaB paralogue, yjdK, can complement the heme A synthesis deficiency of a CtaB-deficient mutant.

Heme A is a prosthetic group in many respiratory oxidases. It is synthesised from heme B (protoheme IX) with heme O as an intermediate. In Bacillus subtilis two genes required for heme A synthesis, ctaA and ctaB, have been identified. CtaB is the heme O synthase and CtaA is involved in the conversion of heme O to heme A. A ctaB paralogue, yjdK, has been identified through the B. subtilis genome sequencing project. In this study we show that when carried on a low copy number plasmid, the yjdK gene can complement a ctaB deletion mutant with respect to heme A synthesis. Our results indicate that YjdK has heme O synthase activity. We therefore suggest that yjdK be renamed as ctaO.

A cytochrome bb'-type quinol oxidase in Bacillus subtilis strain 168.

The aerobic respiratory system of Bacillus subtilis 168 is known to contain three terminal oxidases: cytochrome caa(3), which is a cytochrome c oxidase, and cytochrome aa(3) and bd, which are quinol oxidases. The presence of a possible fourth oxidase in the bacterium was investigated using a constructed mutant, LUH27, that lacks the aa(3) and caa(3) terminal oxidases and is also deficient in succinate:menaquinone oxidoreductase. The cytochrome bd content of LUH27 can be varied by using different growth conditions. LUH27 membranes virtually devoid of cytochrome bd respired with NADH or exogenous quinol as actively as preparations containing 0.4 nmol of cytochrome bd/mg of protein but were more sensitive to cyanide and aurachin D. The reduced minus oxidized difference spectra of the bd-deficient membranes as well as absorption changes induced by CO and cyanide indicated the presence of a "cytochrome o"-like component; however, the membranes did not contain heme O. The results provide strong evidence for the presence of a terminal oxidase of the bb' type in B. subtilis. The enzyme does not pump protons and combines with CO much faster than typical heme-copper oxidases; in these respects, it resembles a cytochrome bd rather than members of the heme-copper oxidase superfamily. The genome sequence of B. subtilis 168 contains gene clusters for four respiratory oxidases. Two of these clusters, cta and qox, are deleted in LUH27. The remaining two, cydAB and ythAB, encode the identified cytochrome bd and a putative second cytochrome bd, respectively. Deletion of ythAB in strain LUH27 or the presence of the yth genes on plasmid did not affect the expression of the bb' oxidase. It is concluded that the novel bb'-type oxidase probably is cytochrome bd encoded by the cyd locus but with heme D being substituted by high spin heme B at the oxygen reactive site, i.e. cytochrome b(558)b(595)b'.

Bacillus subtilis contains two small c-type cytochromes with homologous heme domains but different types of membrane anchors.

We demonstrate that the cccB gene, identified in the Bacillus subtilis genome sequence project, is the structural gene for a 10-kDa membrane-bound cytochrome c(551) lipoprotein described for the first time in B. subtilis. Apparently, CccB corresponds to cytochrome c(551) of the thermophilic bacterium Bacillus PS3. The heme domain of B. subtilis cytochrome c(551) is very similar to that of cytochrome c(550), a protein encoded by the cccA gene and anchored to the membrane by a single transmembrane polypeptide segment. Thus, B. subtilis contains two small, very similar, c-type cytochromes with different types of membrane anchors. The cccB gene is cotranscribed with the yvjA gene, and transcription is repressed by glucose. Mutants deleted for cccB or yvjA-cccB show no apparent growth, sporulation, or germination defect. YvjA is not required for the synthesis of cytochrome c(551), and its function remains unknown.

Subunit II of Bacillus subtilis cytochrome c oxidase is a lipoprotein.

The sequence of the N-terminal end of the deduced ctaC gene product of Bacillus species has the features of a bacterial lipoprotein. CtaC is the subunit II of cytochrome caa3, which is a cytochrome c oxidase. Using Bacillus subtilis mutants blocked in lipoprotein synthesis, we show that CtaC is a lipoprotein and that synthesis of the membrane-bound protein and covalent binding of heme to the cytochrome c domain is not dependent on processing at the N-terminal part of the protein. Mutants blocked in prolipoprotein diacylglyceryl transferase (Lgt) or signal peptidase type II (Lsp) are, however, deficient in cytochrome caa3 enzyme activity. Removal of the signal peptide from the CtaC polypeptide, but not lipid modification, is seemingly required for formation of functional enzyme.

Carboxin resistance in Paracoccus denitrificans conferred by a mutation in the membrane-anchor domain of succinate:quinone reductase.

Succinate:quinone reductase is a membrane-bound enzyme of the citric acid cycle and the respiratory chain. Carboxin is a potent inhibitor of the enzyme of certain organisms. The bacterium Paracoccus denitrificans was found to be sensitive to carboxin in vivo, and mutants that grow in the presence of 3'-methyl carboxin were isolated. Membranes of the mutants showed resistant succinate:quinone reductase activity. The mutation conferring carboxin resistance was identified in four mutants. They contained the same missense mutation in the sdhD gene, which encodes one of two membrane-intrinsic polypeptides of the succinate:quinone reductase complex. The mutation causes an Asp to Gly replacement at position 89 in the SdhD polypeptide. P. denitrificans strains that overproduced wild-type or mutant enzymes were constructed. Enzymic properties of the purified enzymes were analyzed. The apparent Km for quinone (DPB) and the sensitivity to thenoyltrifluoroacetone was normal for the carboxin-resistant enzyme, but the succinate:quinone reductase activity was lower than for the wild-type enzyme. Mutations conferring carboxin resistance indicate the region on the enzyme where the inhibitor binds. A previously reported His to Leu replacement close to the [3Fe-4S] cluster in the iron-sulfur protein of Ustilago maydis succinate:quinone reductase confers resistance to carboxin and thenoyltrifluoroacetone. The Asp to Gly replacement in the P. denitrificans SdhD polypeptide, identified in this study to confer resistance to carboxin but not to thenoyltrifluoroacetone, is in a predicted cytoplasmic loop connecting two transmembrane segments. It is likely that this loop is located in the neighborhood of the [3Fe-4S] cluster.

The ms2io6A37 modification of tRNA in Salmonella typhimurium regulates growth on citric acid cycle intermediates.

The modified nucleoside 2-methylthio-N-6-isopentenyl adenosine (ms2i6A) is present in position 37 (adjacent to and 3' of the anticodon) of tRNAs that read codons beginning with U except tRNA(i.v. Ser) in Escherichia coli. In Salmonella typhimurium, 2-methylthio-N-6-(cis-hydroxy)isopentenyl adenosine (ms2io6A; also referred to as 2-methylthio cis-ribozeatin) is found in tRNA, most likely in the species that have ms2i6A in E. coli. Mutants (miaE) of S. typhimurium in which ms2i6A hydroxylation is blocked are unable to grow aerobically on the dicarboxylic acids of the citric acid cycle. Such mutants have normal uptake of dicarboxylic acids and functional enzymes of the citric acid cycle and the aerobic respiratory chain. The ability of S. typhimurium to grow on succinate, fumarate, and malate is dependent on the state of modification in position 37 of those tRNAs normally having ms2io6A37 and is not due to a second cellular function of tRNA (ms2io6A37)hydroxylase, the miaE gene product. We suggest that S. typhimurium senses the hydroxylation status of the isopentenyl group of the tRNA and will grow on succinate, fumarate, or malate only if the isopentenyl group is hydroxylated.

Electron paramagnetic resonance studies of succinate:ubiquinone oxidoreductase from Paracoccus denitrificans. Evidence for a magnetic interaction between the 3Fe-4S cluster and cytochrome b.

Electron paramagnetic resonance (EPR) studies of succinate:ubiquinone oxidoreductase (SQR) from Paracoccus denitrificans have been undertaken in the purified and membrane-bound states. Spectroscopic "signatures" accounting for the three iron-sulfur clusters (2Fe-2S, 3Fe-4S, and 4Fe-4S), cytochrome b, flavin, and protein-bound ubisemiquinone radicals have been obtained in air-oxidized, succinate-reduced, and dithionite-reduced preparations at 4-10 K. Spectra obtained at 170 K in the presence of excess succinate showed a signal typical of that of a flavin radical, but superimposed with another signal. The superimposed signal originated from two bound ubisemiquinones, as shown by spectral simulations. Power saturation measurements performed on the air-oxidized enzyme provided evidence for a weak magnetic dipolar interaction operating between the oxidized 3Fe-4S cluster and the oxidized cytochrome b. Power saturation experiments performed on the succinate- and dithionite-reduced forms of the enzyme demonstrated that the 4Fe-4S cluster is coupled weakly to both the 2Fe-2S and the 3Fe-4S clusters. Quantitative interpretation of these power saturation experiments has been achieved through redox calculations. They revealed that a spin-spin interaction between the reduced 3Fe-4S cluster and the cytochrome b (oxidized) may also exist. These findings form the first direct EPR evidence for a close proximity (

Bacillus subtilis CcdA-defective mutants are blocked in a late step of cytochrome c biogenesis.

Cytochromes of the c type contain covalently bound heme. In bacteria, they are located on the outside of the cytoplasmic membrane. Cytochrome c synthesis involves export of heme and apocytochrome across the cytoplasmic membrane followed by ligation of heme to the polypeptide. Using radioactive protoheme IX produced in Escherichia coli, we show that Bacillus subtilis can use heme from the growth medium for cytochrome c synthesis. The B. subtilis ccdA gene encodes a 26-kDa integral membrane protein which is required for cytochrome c synthesis (T. Schiött et al., J. Bacteriol. 179:1962-1973, 1997). In this work, we analyzed the stage at which cytochrome c synthesis is blocked in a ccdA deletion mutant. The following steps were found to be normal in the mutant: (i) transcription and translation of cytochrome c structural genes, (ii) translocation of apocytochrome across the cytoplasmic membrane, and (iii) heme transport from the cytoplasm to cytochrome polypeptide on the outer side of the cytoplasmic membrane. It is concluded that CcdA is required for a late step in the cytochrome c synthesis pathway.

Escherichia coli ccm in-frame deletion mutants can produce periplasmic cytochrome b but not cytochrome c.

Escherichia coli CcmA, CcmB and CcmC polypeptides are required for cytochrome c synthesis and are thought to constitute the subunits of an ABC-type transporter as judged from sequence data. Using a periplasmic reporter system based on Bacillus subtilis cytochrome c-550 and E. coli cytochrome b-562 we show that the synthesis of the b-type cytochrome in the periplasm is normal in E. coli ccmA and ccmC in-frame deletion mutants. Mutants deleted for ccmF or ccmG encoding a component of a putative cytochrome c-heme lyase and a membrane bound thioredoxin-like protein, respectively, have the same phenotype. The ccm mutants produce cytochrome c-550 polypeptide, but not holocytochrome c. Taken together the results demonstrate that heme can be transported to the periplasm by a ccm-independent mechanism.

Isolated Bacillus subtilis HemY has coproporphyrinogen III to coproporphyrin III oxidase activity.

Oxidation of coproporphyrinogen III to coproporphyrin III is found in extracts of Escherichia coli cells containing the Bacillus subtilis HemY protein (M. Hansson and L. Hederstedt, J. Bacteriol. 176, 5962-5970). We have analysed whether this activity is due to the heterologous expression system, since it in vivo would lead to disruption of the heme biosynthetic pathway. B. subtilis hemY was fused in its 3'-end to a polynucleotide encoding six histidine residues and expressed from plasmids in both E. coli and B. subtilis. The His6-tagged HemY protein extracted from membranes using non-ionic detergent was purified by Ni2+ affinity chromatography. Isolated HemY fusion protein synthesised in E. coli and B. subtilis oxidised coproporphyrinogen III to coproporphyrin III. No direct formation of protoporphyrin IX from coproporphyrinogen III could be detected. Our results suggest that the coproporphyrinogen III to coproporphyrin III activity of HemY is either avoided in B. subtilis in vivo or that coproporphyrin III is a heme biosynthetic intermediate in this bacterium.

Identification and characterization of the ccdA gene, required for cytochrome c synthesis in Bacillus subtilis.

The gram-positive, endospore-forming bacterium Bacillus subtilis contains several membrane-bound c-type cytochromes. We have isolated a mutant pleiotropically deficient in cytochromes c. The responsible mutation resides in a gene which we have named ccdA (cytochrome c defective). This gene is located at 173 degrees on the B. subtilis chromosome. The ccdA gene was found to be specifically required for synthesis of cytochromes of the c type. CcdA is a predicted 26-kDa integral membrane protein with no clear similarity to any known cytochrome c biogenesis protein but seems to be related to a part of Escherichia coli DipZ/DsbD. The ccdA gene is cotranscribed with two other genes. These genes encode a putative 13.5-kDa single-domain response regulator, similar to B. subtilis CheY and Spo0F, and a predicted 18-kDa hydrophobic protein with no similarity to any protein in databases, respectively. Inactivation of the three genes showed that only ccdA is required for cytochrome c synthesis. The results also demonstrated that cytochromes of the c type are not needed for growth of B. subtilis.