Genetic analysis of a Rhodobacter capsulatus gene region involved in utilization of taurine as a sulfur source.

Rhodobacter capsulatus was shown to grow efficiently with taurine as sole source of sulfur. We identified a gene region exhibiting similarity to the Escherichia coli tauABC genes coding for a taurine-specific ABC transporter. The R. capsulatus tauABC genes were flanked by two putative operons (orf459-484-590 and cysE-srpI-nifS2) both reading in opposite direction relative to tauABC. Orf459 shows strong similarity to taurine:pyruvate aminotransferase (Tpa) from Bilophila wadsworthia catalyzing the initial transamination during anaerobic taurine degradation, and Orf590 exhibits clear similarity to sulfoacetaldehyde sulfo-lyase from Desulfonispora thiosulfatigenes probably catalyzing the step following the taurine:pyruvate aminotransferase (Tpa) reaction, whereas nifS2 might code for a putative cysteine desulfurase. Expression of R. capsulatus tauABC and nifS2 was inhibited by sulfate, suggesting that tauABC and nifS2 might belong to the same regulon. In contrast, transcription of orf459 was not inhibited by sulfate but was induced by taurine. A tauAB deletion mutant showed significantly reduced growth compared to the wild-type with taurine as sole sulfur source in the presence of serine as a nitrogen source, whereas normal growth was observed in the presence of taurine and ammonium. Deletion of orf459-484-590 completely abolished growth with taurine/serine. Single mutations in any of the three genes resulted in the same phenotype, indicating that all three genes of this putative operon are essential for taurine sulfur utilization in the presence of serine. A model for anaerobic taurine sulfur assimilation in R. capsulatus is discussed.

Rhodobacter capsulatus nifA mutants mediating nif gene expression in the presence of ammonium.

Expression of nitrogen fixation genes in Rhodobacter capsulatus is repressed by ammonium at different regulatory levels including an NtrC-independent mechanism controlling NifA activity. In contrast to R. capsulatus NifA, heterologous NifA proteins of Klebsiella pneumoniae and Rhizobium meliloti, respectively, were not subjected to this posttranslational ammonium control in R. capsulatus. The characterization of ammonium-tolerant R. capsulatus NifA1 mutants indicated that the N-terminal domain of NifA was involved in posttranslational regulation. Analysis of a double mutant carrying amino acid substitutions in both the N-terminal domain and the C-terminal DNA-binding domain gave rise to the hypothesis that an interaction between these two domains might be involved in ammonium regulation of NifA activity. Western analysis demonstrated that both constitutively expressed wild-type and ammonium-tolerant NifA1 proteins exhibited high stability and accumulated to comparable levels in cells grown in the presence of ammonium excluding the possibility that proteolytic degradation was responsible for ammonium-dependent inactivation of NifA.

Urea utilization in the phototrophic bacterium Rhodobacter capsulatus is regulated by the transcriptional activator NtrC.

The phototrophic nonsulfur purple bacterium Rhodobacter capsulatus can use urea as a sole source of nitrogen. Three transposon Tn5-induced mutations (Xan-9, Xan-10, and Xan-19), which led to a Ure(-) phenotype, were mapped to the ureF and ureC genes, whereas two other Tn5 insertions (Xan-20 and Xan-22) were located within the ntrC and ntrB genes, respectively. As in Klebsiella aerogenes and other bacteria, the genes encoding urease (ureABC) and the genes required for assembly of the nickel metallocenter (ureD and ureEFG) are clustered in R. capsulatus (ureDABC-orf136-ureEFG). No homologues of Orf136 were found in the databases, and mutational analysis demonstrated that orf136 is not essential for urease activity or growth on urea. Analysis of a ureDA-lacZ fusion showed that maximum expression of the ure genes occurred under nitrogen-limiting conditions (e.g., serine or urea as the sole nitrogen source), but ure gene expression was not substrate (urea) inducible. Expression of the ure genes was strictly dependent on NtrC, whereas sigma(54) was not essential for urease activity. Expression of the ure genes was lower (by a factor of 3.5) in the presence of ammonium than under nitrogen-limiting conditions, but significant transcription was also observed in the presence of ammonium, approximately 10-fold higher than in an ntrC mutant background. Thus, ure gene expression in the presence of ammonium also requires NtrC. Footprint analyses demonstrated binding of NtrC to tandem binding sites upstream of the ureD promoter. Phosphorylation of NtrC increased DNA binding by at least eightfold. Although urea is effectively used as a nitrogen source in an NtrC-dependent manner, nitrogenase activity was not repressed by urea.

Evidence for a regulatory link of nitrogen fixation and photosynthesis in Rhodobacter capsulatus via HvrA.

A Rhodobacter capsulatus reporter strain, carrying a constitutively expressed nifA gene and a nifH-lacZ gene fusion, was used for random transposon Tn5 mutagenesis to search for genes required for the NtrC-independent ammonium repression of NifA activity. A mutation in hvrA, which is known to be involved in low-light activation of the photosynthetic apparatus, released both ammonium and oxygen control of nifH expression in this reporter strain, demonstrating a regulatory link of nitrogen fixation and photosynthesis via HvrA. In addition, a significant increase in bacteriochlorophyll alpha (BChl alpha) content was found in cells under nitrogen-fixing conditions. HvrA was not involved in this up-regulation of BChl alpha. Instead, the presence of active nitrogenase seemed to be sufficient for this process, since no increase in BChl alpha content was observed in different nif mutants.

The isiB gene encoding flavodoxin is not essential for photoautotrophic iron limited growth of the cyanobacterium Synechocystis sp. strain PCC 6803.

When iron becomes limiting, Synechocystis 6803 induces the synthesis of flavodoxin. As a basis for genetic analysis, the flavodoxin-encoding isiB gene of Synechocystis 6803 was cloned and sequenced. The isiB gene was disrupted by insertion of an interposon within the isiB coding region resulting in two Synechocystis 6803 mutant strains, CKF-I and CKF-II. They were distinguished from each other by the orientation of the kanamycin resistance cassette. Photoautotrophic growth of the mutant strains under iron limiting conditions, which are sufficient for induction of flavodoxin in the wild-type cells, demonstrated that IsiB was not essential for Synechocystis 6803.

Identification and characterization of the nifV-nifZ-nifT gene region from the filamentous cyanobacterium Anabaena sp. strain PCC 7120.

The nifV and leuA genes, which encode homocitrate synthase and alpha-isopropylmalate synthase, respectively, were cloned from the filamentous cyanobacterium Anabaena sp. strain PCC 7120 by a PCR-based strategy. Since the N-terminal parts of NifV and LeuA from other bacteria are highly similar to each other, a single pair of PCR primers was used to amplify internal fragments of both Anabaena strain 7120 genes. Sequence analysis of cloned PCR products confirmed the presence of two different nifV-like DNA fragments, which were subsequently used as nifV- and leuA-specific probes, respectively, to clone XbaI fragments of 2.1 kbp (pOST4) and 2.6 kbp (pOST2). Plasmid pOST4 carried the Anabaena strain 7120 nifV-nifZ-nifT genes, whereas pOST2 contained the leuA and dapF genes. The nifVZT genes were not located in close proximity to the main nif gene cluster in Anabaena strain 7120, and therefore nifVZT forms a second nif gene cluster in this strain. Overlaps between the nifV and nifZ genes and between the nifZ and nifT genes and the presence of a 1.8-kb transcript indicated that nifVZT might form one transcriptional unit. Transcripts of nifV were induced not only in a nitrogen-depleted culture but also by iron depletion irrespective of the nitrogen status. The nifV gene in Anabaena strain 7120 was interrupted by an interposon insertion (mutant strain BMB105) and by a plasmid integration via a single crossover with a nifV internal fragment as a site for recombination (mutant strain BMB106). Both mutant strains were capable of diazotrophic growth, and their growth rates were only slightly impaired compared to that of the wild type. Heterologous complementation of the Rhodobacter capsulatus nifV mutant R229I by the Anabaena strain 7120 nifV gene corroborated the assumption that Anabaena strain 7120 nifV also encodes a homocitrate synthase. In contrast, the Anabaena strain 7120 leuA gene did not complement the nifV mutation of R229I efficiently.

The heterocyst-specific fdxH gene product of the cyanobacterium Anabaena sp. PCC 7120 is important but not essential for nitrogen fixation.

To clarify the role of the heterocyst-specific [2Fe-2S] ferredoxin in cyanobacterial nitrogen fixation, mutational analysis of the Anabaena 7120 fdxH gene region was carried out. First, the DNA sequence of the wild-type 3509-bp EcoRI fragment downstream of the fdxH gene was determined. Genes homologous to ORF3 from the fdxH gene regions of A. variabilis and Plectonema boryanum, the mop genes of Clostridium pasteurianum encoding molybdo-pterin binding proteins, and ORF3 from the A. variabilis hydrogenase gene cluster were identified within the sequenced region. For mutational analysis the Anabaena 7120 mutant strains LAK4, BMB92, and KSH10 were constructed. In LAK4 the fdxH coding region is disrupted by an interposon, whereas BMB92 is deleted for a 2799-bp NheI fragment encompassing fdxH, ORF3, mop, ORF4, and ORF5. Mutant strain KSH10 is a derivative of BMB92, complemented for fdxH but not for the other genes located further downstream. Analysis of the Nif phenotype of these mutant strains showed that FdxH is necessary for maximum nitrogenase activity and optimal growth under nitrogen-fixing conditions, but not absolutely essential for diazotrophic growth. The role of alternative electron donors for nitrogenase, which might substitute for FdxH, is discussed. Iron concentrations (1 microM Fe) sufficient to induce synthesis of the vegetative cell flavodoxin did not stimulate diazotrophic growth of the fdxH mutant strains, suggesting that FdxH was not replaced by a NifJ-flavodoxin system. Comparison of LAK4 and BMB92 indicated that one of the genes located downstream of fdxH might also play a (minor) role in nitrogen fixation.

Long tandemly repeated repetitive (LTRR) sequences in the filamentous cyanobacterium Anabaena sp. PCC 7120.

Nucleotide sequence analysis of the DNA region carrying transposon Tn5-1087b from the Anabaena 7120 nitrogen fixation-deficient mutant YC16 revealed the presence of a novel repeated DNA element in cyanobacteria designated long tandemly repeated repetitive (LTRR) sequence. The LTRR element is 37 bp long and contains an inverted repeat sequence. 17 copies of the LTRR element, 13 of which were completely identical, were identified within a 1.3 kb DNA fragment, which was flanked by two divergently transcribed genes homologous to bacteriophage T4 'gene 15' and Rhizobium meliloti exoD, respectively. LTRR-like sequences occur in several DNA regions in Anabaena 7120 and in other cyanobacteria. Furthermore, the presence of an LTRR-like DNA region in mitochondrial plasmids of Vicia faba indicates strong conservation of such structures during evolution.

The cyanobacterium Synechococcus sp. strain PCC 7942 contains a second alkaline phosphatase encoded by phoV.

A gene (phoV) encoding an alkaline phosphatase from Synechococcus sp. strain PCC 7942 was isolated by screening a plasmid gene bank for expression of alkaline phosphatase activity in Escherichia coli JM103. Two independent clones carrying the same alkaline-phosphatase-encoding gene were isolated. One of these clones (pKW1) was further analysed and the nucleotide sequence of a contiguous 3234 bp DNA fragment was determined. Two complete open reading frames (ORF1 and phoV) and an incomplete ORF3 were identified reading in the same direction. The deduced phoV gene product showed 34% identity to the alkaline phosphatase PhoA from Zymomonas mobilis, and the N-terminal part of the putative ORF3 protein exhibited 57% identity to a protein of unknown function from Frankia sp. Insertional inactivation of the Synechococcus PCC 7942 phoV gene failed, indicating an essential role for either the phoV or the ORF3 gene product. PhoV consists of 550 amino acid residues, resulting in a molecular mass of 61.3 kDa. To overexpress the Synechococcus PCC 7942 phoV gene in E. coli, plasmid pKW1 was transformed into a phoA mutant of E. coli (CC118). In E. coli strain CC118(pKW1) PhoV was expressed constitutively with high rates of activity, and was shown to be membrane associated in the periplasmic space. After partial purification of the recombinant PhoV, it was shown that, like other alkaline phosphatases, the Synechococcus PhoV had a broad pH optimum in the alkaline region and a broad substrate specificity for phosphomonoesters, required Zn2+ for activity, and was inhibited by phosphate. In contrast to several other alkaline phosphatases, PhoV was inhibited by Mn2+. Due to the lack of a Synechococcus PCC 7942 phoV mutant strain, the function of PhoV remains uncertain. However, the present results show that Synechococcus PCC 7942 has a second, probably phosphate-irrepressible, alkaline phosphatase (PhoV, 61.3 kDa) in addition to the phosphate-repressible enzyme (PhoA, 145 kDa) already described.

Partial amino acid sequence of an L-amino acid oxidase from the cyanobacterium Synechococcus PCC6301, cloning and DNA sequence analysis of the aoxA gene.

A novel type of L-amino acid oxidase from Synechococcus PCC6301 was purified and subjected to amino acid sequence analysis. Since the N-terminus of the L-amino acid oxidase protein was not accessible for Edman degradation, the protein was partially hydrolysed and a contiguous sequence of 17 amino acid residues was obtained from an endogenous peptide fragment. Based on the partial peptide sequence two oligonucleotides were designed, which were used as probes in Southern hybridization experiments in order to identify the corresponding aoxA gene. The aoxA gene was isolated from a size-fractionated genomic library of Synechococcus PCC6301 and subsequently sequenced. From the nucleotide sequence (data base accession number Z48565) it can be deduced that the L-amino acid protein consists of 355 amino acid residues resulting in a molar mass of 39.2 kDa. The calculated isoelectric point of the protein is 9.81. The L-amino acid oxidase from Synechococcus PCC6301 shows low homologies to other flavin oxidases/dehydrogenases, especially amine oxidases, but no homologies to other so far sequenced L- or D-amino acid oxidases.

Expression of the putA gene encoding proline dehydrogenase from Rhodobacter capsulatus is independent of NtrC regulation but requires an Lrp-like activator protein.

Four Rhodobacter capsulatus mutants unable to grow with proline as the sole nitrogen source were isolated by random Tn5 mutagenesis. The Tn5 insertions were mapped within two adjacent chromosomal EcoRI fragments. DNA sequence analysis of this region revealed three open reading frames designated selD, putR, and putA. The putA gene codes for a protein of 1,127 amino acid residues which is homologous to PutA of Salmonella typhimurium and Escherichia coli. The central part of R. capsulatus PutA showed homology to proline dehydrogenase of Saccharomyces cerevisiae (Put1) and Drosophila melanogaster (SlgA). The C-terminal part of PutA exhibited homology to Put2 (pyrroline-5-carboxylate dehydrogenase) of S. cerevisiae and to aldehyde dehydrogenases from different organisms. Therefore, it seems likely that in R. capsulatus, as in enteric bacteria, both enzymatic steps for proline degradation are catalyzed by a single polypeptide (PutA). The deduced amino acid sequence of PutR (154 amino acid residues) showed homology to the small regulatory proteins Lrp, BkdR, and AsnC. The putR gene, which is divergently transcribed from putA, is essential for proline utilization and codes for an activator of putA expression. The expression of putA was induced by proline and was not affected by ammonia or other amino acids. In addition, putA expression was autoregulated by PutA itself. Mutations in glnB, nifR1 (ntrC), and NifR4 (ntrA encoding sigma 54) had no influence on put gene expression. The open reading frame located downstream of R. capsulatus putR exhibited strong homology to the E. coli selD gene, which is involved in selenium metabolism. R. capsulatus selD mutants exhibited a Put+ phenotype, demonstrating that selD is required neither for viability nor for proline utilization.

A Rhizobium meliloti ferredoxin (FdxN) purified from Escherichia coli donates electrons to Rhodobacter capsulatus nitrogenase.

The fdxN gene from Rhizobium meliloti encoding a bacterial-type ferredoxin (FdxN) was expressed in Escherichia coli under the control of the lac promoter. The fdxN gene product was purified under anaerobic conditions by ion-exchange chromatography and gel-filtration steps using an antiserum raised against an FdxN-LacZ fusion protein as a detection system. The purified ferredoxin was shown to be identical to the predicted R. meliloti FdxN protein in its amino acid composition and N-terminal amino acid sequence. Chemical determination of the iron content revealed 8.6 +/- 0.6 mol Fe/mol FdxN. The ultraviolet/visible absorption spectrum of the FdxN protein in the oxidized form exhibited maxima at 284 nm and 378 nm, with an A378/A284 ratio of 0.7. EPR spectroscopy revealed a rhombic signal when FdxN was partially reduced, and a broad signal indicative of spin-spin interaction when fully reduced, suggesting the presence of two Fe-S cluster/ferredoxin polypeptide. Our data suggest that FdxN contains two [4Fe-4S] clusters. Purified FdxN was able to mediate electron transport between illuminated chloroplasts and Rhodobacter capsulatus nitrogenase in vitro.

Identification of a new class of nitrogen fixation genes in Rhodobacter capsulatus: a putative membrane complex involved in electron transport to nitrogenase.

DNA sequence analysis of a 12236 bp fragment, which is located upstream of nifE in Rhodobacter capsulatus nif region A, revealed the presence of ten open reading frames. With the exception of fdxC and fdxN, which encode a plant-type and a bacterial-type ferredoxin, the deduced products of these coding regions exhibited no significant homology to known proteins. Analysis of defined insertion and deletion mutants demonstrated that six of these genes were required for nitrogen fixation. Therefore, we propose to call these genes rnfA, rnfB, rnfC, rnfD, rnfE and rnfF (for Rhodobacter nitrogen fixation). Secondary structure predictions suggested that the rnf genes encode four potential membrane proteins and two putative iron-sulphur proteins, which contain cysteine motifs (C-X2-C-X2-C-X3-C-P) typical for [4Fe--4S] proteins. Comparison of the in vivo and in vitro nitrogenase activities of fdxN and rnf mutants suggested that the products encoded by these genes are involved in electron transport to nitrogenase. In addition, these mutants were shown to contain significantly reduced amounts of nitrogenase. The hypothesis that this new class of nitrogen fixation genes encodes components of an electron transfer system to nitrogenase was corroborated by analysing the effect of metronidazole. Both the fdxN and rnf mutants had higher growth yields in the presence of metronidazole than the wild type, suggesting that these mutants contained lower amounts of reduced ferredoxins.

The draTG gene region of Rhodobacter capsulatus is required for post-translational regulation of both the molybdenum and the alternative nitrogenase.

Synthetic oligonucleotides, which were designed according to amino acid sequences conserved between Rhodospirillum rubrum and Azospirillum brasilense DraT and DraG, respectively, were used to identify the corresponding genes of Rhodobacter capsulatus. Sequence analysis of a 1904 bp DNA fragment proved the existence of R. capsulatus draT and draG. These two genes were separated by 11 bp only, suggesting that R. capsulatus draT and draG were part of one transcriptional unit. In contrast to R. rubrum, A. brasilense and Azospirillum lipoferum, the R. capsulatus draTG genes were not located upstream of the structural genes of nitrogenase nifHDK but close to the dctP gene at a distance of about 1000 kb from the nifHDK genes. Deletion mutations in the draTG gene region were constructed and introduced into R. capsulatus wild-type and a nifHDK deletion strain. The resulting mutant strains were examined for post-translational regulation of the molybdenum and the alternative nitrogenase in response to ammonia and darkness. Under 'switch-off' conditions the modified (ADP-ribosylated) and the non-modified forms of component II of both the molybdenum and the alternative nitrogenase were detected in a draTG wild-type background by immunoblot analysis, whereas only the non-modified forms were present in the draTG deletion strains. Nitrogenase activity in these strains was followed by the acetylene reduction assay. In contrast to the wild-type, draTG mutants were not affected in nitrogenase activity in response to ammonia or darkness. These results demonstrated that the draTG genes are required for post-translational regulation of both the molybdenum and the heterometal-free nitrogenase in R. capsulatus.

nif gene expression studies in Rhodobacter capsulatus: ntrC-independent repression by high ammonium concentrations.

The expression of nif genes in Rhodobacter capsulatus depends on the two regulatory genes, rpoN and nifA, encoding a nif-specific alternative sigma factor of RNA polymerase and a nif-specific transcriptional activator, respectively. The expression of the rpoN gene itself is also RPON/NIFA dependent. In order to better characterize the regulation of nif gene induction, chromosomal nifH-, rpoN-, nifA1- and nifA2- lacZ fusions were constructed and the expression of these different nif-lacZ fusions was determined under photoheterotrophic conditions at different starting ammonium concentrations. The two nifA genes were found to be induced first, followed by nifH and finally by rpoN upon weak, medium and strong nitrogen starvation, respectively. This induction profile and the correlation between the expression of the different nif genes suggested that nifA1 expression is the limiting factor for nif gene induction. This hypothesis was tested by construction of different nifA1 overexpressing mutants. Contrary to the current model of nif gene expression in R. capsulatus, which predicted constitutive nif gene expression in such mutants, a strong repression of nifH and rpoN was found at high ammonium concentration. The low nifH expression under these conditions is unaffected by nifA2 and is not increased in a ntrC mutant, ruling out any role of NTRC as a mediator of this repression. This finding implies an additional, so far unidentified, regulation by fixed nitrogen in R. capsulatus. Changing the expression level of rpoN indicated that low levels of RPON are already sufficient for full nifH induction. The nifA1 and rpoN expression mutants were also tested for diazotrophic growth. Similar generation times were determined for the mutants and for the wild type, but diazotrophic growth of the nifA1 over-expressing ntrC mutant RCM14 did not start until after a prolonged lag phase of two to three days.

Nucleotide sequence and genetic analysis of the Rhodobacter capsulatus ORF6-nifUI SVW gene region: possible role of NifW in homocitrate processing.

DNA sequence analysis of a 3494-bp HindIII-BclI fragment of the Rhodobacter capsulatus nif region A revealed genes that are homologous to ORF6, nifU, nifS, nifV and nifW from Azotobacter vinelandii and Klebsiella pneumoniae. R. capsulatus nifU, which is present in two copies, encodes a novel type of NifU protein. The deduced amino acid sequences of NifUI and NifUII share homology only with the C-terminal domain of NifU from A. vinelandii and K. pneumoniae. In contrast to nifA and nifB, which are almost perfectly duplicated, the predicted amino acid sequences of the two NifU proteins showed only 39% sequence identity. Expression of the ORF6-nifUISVW operon, which is preceded by a putative sigma 54-dependent promoter, required the function of NifA and the nif-specific rpoN gene product encoded by nifR4. Analysis of defined insertion and deletion mutants demonstrated that only nifS was absolutely essential for nitrogen fixation in R. capsulatus. Strains carrying mutations in nifV were capable of very slow diazotrophic growth, whereas ORF6, nifUI and nifW mutants as well as a nifUI/nifUII double mutant exhibited a Nif+ phenotype. Interestingly, R. capsulatus nifV mutants were able to reduce acetylene not only to ethylene but also to ethane under conditions preventing the expression of the alternative nitrogenase system. Homocitrate added to the growth medium repressed ethane formation and cured the NifV phenotype in R. capsulatus. Higher concentrations of homocitrate were necessary to complement the NifV phenotype of a polar nifV mutant (NifV-NifW-), indicating a possible role of NifW either in homocitrate transport or in the incorporation of this compound into the iron-molybdenum cofactor of nitrogenase.

Synthesis of the ferredoxin-like protein FdxN from Rhizobium meliloti bacteroids as a fusion protein in Escherichia coli.

To analyze the overexpression of the Rhizobium meliloti fdxN gene in Escherichia coli, different translational and transcriptional fusions were constructed. The translational signals of R. meliloti fdxN were recognized in E. coli as demonstrated by the use of in-frame lac fusions. Translational fusions consisting of the lacZ or the lpp gene fused in frame to the 3' end of the entire fdxN gene were expressed at high levels in E. coli. In contrast, the wild-type R. meliloti FdxN protein without a C-terminal fusion could only be detected using the very sensitive T7 promoter-polymerase system and not in immunoblots with antibodies against an FdxN-LacZ hybrid protein. Evidently, translational fusions to the 3' end of fdxN had a stabilizing effect on the expression of the fdxN gene. A constitutively expressed transcriptional fdxN fusion, which did not mediate detectable amounts of FdxN protein either in E. coli or in free-living R. meliloti cells, complemented the Fix- phenotype of an R. meliloti fdxN::[Tc] mutant strain to wild-type levels. Therefore, either low amounts of the wild-type FdxN protein are sufficient for symbiotic nitrogen fixation or there are stabilizing factors, which are present only in R. meliloti bacteroids but not in free-living R. meliloti cells. Fusion proteins consisting of FdxN and LacZ or a partial Lpp protein restored the Fix- phenotype of an R. meliloti fdxN mutant to 3 and 11%, respectively, indicating that a C-terminal fusion did not completely abolish the function of FdxN.

Functional analysis of the cysteine motifs in the ferredoxin-like protein FdxN of Rhizobium meliloti involved in symbiotic nitrogen fixation.

The Rhizobium meliloti fdxN gene, which is part of the nifA-nifB-fdxN operon, is absolutely required for symbiotic nitrogen fixation. The deduced sequence of the FdxN protein is characterized by two cysteine motifs typical of bacterial-type ferredoxins. The Fix-phenotype of an R. meliloti fdxN::[Tc] mutant could be rescued by the R. leguminosarum fdxN gene, whereas no complementation was observed with nif-associated genes encoding ferredoxins from Bradyrhizobium japonicum, Azotobacter vinelandii, A. chroococcum and Rhodobacter capsulatus. In addition to these heterologous genes, several R. meliloti fdxN mutant genes constructed by site-directed mutagenesis were analyzed. Not only a cysteine residue within the second cysteine motif (position 42), which is known to coordinate the Fe-S cluster in homologous proteins, but also a cysteine located down-stream of this motif (position 61), was found to be essential for the activity of the R. meliloti FdxN protein. Changing the amino acid residue proline in position 56 into methionine resulted in a FdxN mutant protein with decreased activity, whereas changes in positions 35 (Asp35Glu) and 45 (Gly45Glu) had no significant effect on the function of the FdxN mutant proteins. In contrast to bacterial-type ferredoxins, which contain two identical cysteine motifs of the form C-X2-C-X2-C-X3-C, nif-associated ferredoxins, including R. meliloti FdxN, are characterized by two different cysteine motifs. Six "additional" amino acids separate the second (Cys42) and the third cysteine (Cys51) in the C-terminal motif (C-X2-C-X8-C-X3-C).(ABSTRACT TRUNCATED AT 250 WORDS)

Insertional inactivation of the psbO gene encoding the manganese stabilizing protein of photosystem II in the cyanobacterium Synechococcus PCC7942. Effect on photosynthetic water oxidation and L-amino acid oxidase activity.

A Synechococcus PCC7942 mutant in which the psbO gene was inactivated by insertion of a chloramphenicol interposon and which did not contain any detectable manganese stabilizing protein in immunoblot experiments, was constructed. Such a Synechococcus mutant was able to grow under photoautotrophic conditions. Isolated thylakoid membranes from the mutant required addition of CaCl2 and MnCl2 for photosynthetic O2 evolution, and the detectable L-amino acid oxidase activity in the isolated thylakoid membranes from the mutant was approximately four times higher than in wild-type thylakoids. The results are discussed with respect to our model suggesting that the water-oxidizing enzyme may have evolved from a flavoprotein with L-amino acid dehydrogenase/oxidase activity.

DNA sequence and genetic analysis of the Rhodobacter capsulatus nifENX gene region: homology between NifX and NifB suggests involvement of NifX in processing of the iron-molybdenum cofactor.

Rhodobacter capsulatus genes homologous to Klebsiella pneumoniae nifE, nifN and nifX were identified by DNA sequence analysis of a 4282 bp fragment of nif region A. Four open reading frames coding for a 51,188 (NifE), a 49,459 (NifN), a 17,459 (NifX) and a 17,472 (ORF4) dalton protein were detected. A typical NifA activated consensus promoter and two imperfect putative NifA binding sites were located in the 377 bp sequence in front of the nifE coding region. Comparison of the deduced amino acid sequences of R. capsulatus NifE and NifN revealed homologies not only to analogous gene products of other organisms but also to the alpha and beta subunits of the nitrogenase iron-molybdenum protein. In addition, the R. capsulatus nifE and nifN proteins shared considerable homology with each other. The map position of nifX downstream of nifEN corresponded in R. capsulatus and K. pneumoniae and the deduced molecular weights of both proteins were nearly identical. Nevertheless, R. capsulatus NifX was more related to the C-terminal end of NifY from K. pneumoniae than to NifX. A small domain of approximately 33 amino acid residues showing the highest degree of homology between NifY and NifX was also present in all nifB proteins analyzed so far. This homology indicated an evolutionary relationship of nifX, nifY and nifB and also suggested that NifX and NifY might play a role in maturation and/or stability of the iron-molybdenum cofactor. The open reading frame (ORF4) downstream of nifX in R. capsulatus is also present in Azotobacter vinelandii but not in K. pneumoniae.(ABSTRACT TRUNCATED AT 250 WORDS)