Fluorinated Vitamin B12 Analogs Are Cofactors of Corrinoid-Dependent Enzymes: a 19F-Labeled Nuclear Magnetic Resonance Probe for Identifying Corrinoid-Protein Interactions

The homoacetogenic bacterium Sporomusa ovata synthesized the vitamin B₁₂ analog phenolyl cobamide or 4-fluorophenolyl cobamide when the methanol medium of growing cells was supplemented with 10 mM phenol or 5 mM 4-fluorophenol. Phenol and, presumably, 4-fluorophenol were specifically incorporated into these cobamides, since phenol was not metabolized significantly into amino acids or into acetic acid, the product of the catabolism. The phenol-containing cobamides contributed up to 90% of the protein-bound cobamides of the 1,300 to 1,900 nmol of corrinoid per g of dry cell material formed. Fluorine-19 nuclear magnetic resonance spectroscopy of 4-fluorophenolyl cobamide exhibited a resonance near 30 ppm. An additional signal emerged at 25 ppm when 4-fluorophenolyl cobamide was investigated as the cofactor of a corrinoid-dependent protein. The two resonances indicated distinct cofactor arrangements within the protein's active site. A 5-ppm high-field shift change suggested van der Waal's interactions between the fluorinated nucleotide of the cofactor and adjacent amino acid residues of the enzyme. Similarly, Propionibacterium freudenreichii and Methanobacterium thermoautotrophicum synthesized 5-fluorobenzimidazolyl cobamide. The human corrinoid binders intrinsic factor, transcobalamin, and haptocorrin recognized this corrinoid like vitamin B₁₂. Hence, it is possible to use ¹⁹F-labeled nuclear magnetic resonance spectroscopy for analyses of protein-bound cobamides.     

In Vivo Analysis of Cobinamide Salvaging in Rhodobacter sphaeroides Strain 2.4.1

The genome of Rhodobacter sphaeroides encodes the components of two distinct pathways for salvaging cobinamide (Cbi), a precursor of adenosylcobalamin (AdoCbl, coenzyme B₁₂). One pathway, conserved among bacteria, depends on a bifunctional kinase/guanylyltransferase (CobP) enzyme to convert adenosylcobinamide (AdoCbi) to AdoCbi-phosphate (AdoCbi-P), an intermediate in de novo AdoCbl biosynthesis. The other pathway, of archaeal origin, depends on an AdoCbi amidohydrolase (CbiZ) enzyme to generate adenosylcobyric acid (AdoCby), which is converted to AdoCbi-P by the AdoCbi-P synthetase (CobD) enzyme. Here we report that R. sphaeroides strain 2.4.1 synthesizes AdoCbl de novo and that it salvages Cbi using both of the predicted Cbi salvaging pathways. AdoCbl produced by R. sphaeroides was identified and quantified by high-performance liquid chromatography and bioassay. The deletion of cobB (encoding an essential enzyme of the de novo corrin ring biosynthetic pathway) resulted in a strain of R. sphaeroides that would not grow on acetate in the absence of exogenous corrinoids. The results from a nutritional analysis showed that the presence of either CbiZ or CobP was necessary and sufficient for Cbi salvaging, that CbiZ-dependent Cbi salvaging depended on the presence of CobD, and that CobP-dependent Cbi salvaging occurred in a cbiZ⁺ strain. Possible reasons why R. sphaeroides maintains two distinct pathways for Cbi salvaging are discussed.Cobamides, such as adenosylcobalamin (AdoCbl, coenzyme B₁₂), are a group of complex cobalt-containing cyclic tetrapyrrole cofactors whose biosynthesis by bacteria and archaea requires substantial genetic information (>25 genes) (reviewed in references 25, 47, and 56). Two pathways for the de novo synthesis of the corrin ring have been described on the basis of the timing of cobalt insertion into the ring. The late cobalt insertion or aerobic pathway has been well studied in Pseudomonas denitrificans (9), while the early cobalt insertion or anaerobic pathway has been best studied in Salmonella enterica serovar Typhimurium LT2 (25). Many organisms, including those that synthesize AdoCbl de novo, salvage incomplete corrinoids (e.g., cobinamide [Cbi]) from their environments and use them as precursors for the synthesis of complete cobamide cofactors. Cbi is not an intermediate of the de novo AdoCbl biosynthesis pathway but can be converted into one by a process known as Cbi salvaging (Fig. ​(Fig.1)1) (24).Open in a separate windowFIG. 1.Abbreviated view of cobinamide salvaging pathways. Corrin ring-containing intermediates are in bold text. The letter A indicates the de novo corrin ring biosynthesis pathway. Abbreviations: Ado-, adenosyl-; AP, 1-amino-2-propanol; AP-P, 1-amino-2-propanol-phosphate; CobB, hydrogenobyrinic acid a,c-diamide synthase; CobD, adenosylcobinamide-phosphate synthetase; CobP, NTP:adenosylcobinamide kinase, GTP:adenosylcobinamide-phosphate guanylyltransferase; CobY, GTP:adenosylcobinamide-phosphate guanylyltransferase; CbiZ, adenosylcobinamide amidohydrolase. Functional groups are indicated as follows: Me, methyl; Ac, acetamide; and Pr, propionamide.The first step of Cbi salvaging is adenosylation of the molecule to adenosylcobinamide (AdoCbi) (24). The adenosyltransferases which catalyze this reaction are broadly distributed throughout the three domains of life (13, 14, 20, 32, 38). Two distinct pathways for converting AdoCbi into an intermediate of the de novo AdoCbl biosynthesis pathway have been described for prokaryotes. One, which is to date found only in bacteria, relies on a bifunctional nucleoside triphosphate (NTP):AdoCbi kinase (EC 2.7.7.62), GTP:AdoCbi-phosphate (AdoCbi-P) guanylyltransferase (EC 2.7.1.156) enzyme (called CobP in P. denitrificans and CobU in S. Typhimurium), which phosphorylates AdoCbi to AdoCbi-P and converts AdoCbi-P to AdoCbi-GDP (10, 41, 55).Previous work from our laboratory has shown that archaea lack the bifunctional NTP:AdoCbi kinase, GTP:AdoCbi-P guanylyltransferase enzyme and rely on a second pathway for Cbi salvaging (54, 62). In this pathway, AdoCbi is converted to adenosylcobyric acid (AdoCby) by an AdoCbi amidohydrolase (EC 3.5.1.90) known as CbiZ (58, 59, 62). The conversion of AdoCbi-P to AdoCbi-GDP for de novo AdoCbl biosynthesis in archaea is catalyzed by a monofunctional GTP:AdoCbi-P guanylyltransferase (EC 2.7.7.62) called CobY (54, 60), which has not been found in any bacterium.We recently showed that a small percentage of bacterial genomes encode orthologs of both CobP-type and CbiZ-type Cbi salvaging enzymes, raising the question of why these organisms might contain two redundant Cbi salvaging systems (29). A phylogenetic analysis showed that CbiZ has its roots in the archaea and that the cbiZ gene was acquired by several bacterial lineages via horizontal gene transfer.We previously showed that the CbiZ and CobP enzymes from the photosynthetic alphaproteobacterium Rhodobacter sphaeroides are functional in vitro and in vivo in a heterologous complementation system (29). However, the question of how the two Cbi salvaging systems might function in R. sphaeroides remained unresolved.In this paper, we show that R. sphaeroides 2.4.1 synthesizes substantial amounts of cobalamin (Cbl) and that it salvages incomplete corrinoids from its environment. We present in vivo genetic evidence that both the bacterial-type CobP-dependent and archaeal-type CbiZ-dependent Cbi salvaging pathways are functional in this organism. This work represents the first in vivo genetic analysis of coenzyme B₁₂ synthesis and salvaging in R. sphaeroides.     

Specificity of cobamide remodeling,uptake and utilization in Vibrio cholerae

Cobamides are a group of compounds including vitamin B₁₂ that can vary at the lower base position of the nucleotide loop. They are synthesized de novo by only a subset of prokaryotes, but some organisms encode partial biosynthesis pathways for converting one variant to another (remodeling) or completing biosynthesis from an intermediate (corrinoid salvaging). Here, we explore the cobamide specificity in Vibrio cholerae through examination of three natural variants representing major cobamide groups: commercially available cobalamin, and isolated pseudocobalamin and p-cresolylcobamide. We show that BtuB, the outer membrane corrinoid transporter, mediates the uptake of all three variants and the intermediate cobinamide. Our previous work suggested that V. cholerae could convert pseudocobalamin produced by cyanobacteria into cobalamin. In this work, cobamide specificity in V. cholerae is demonstrated by remodeling of pseudocobalamin and salvaging of cobinamide to produce cobalamin. Cobamide remodeling in V. cholerae is distinct from the canonical pathway requiring amidohydrolase CbiZ, and heterologous expression of V. cholerae CobS was sufficient for remodeling. Furthermore, function of V. cholerae cobamide-dependent methionine synthase MetH was robustly supported by cobalamin and p-cresolylcobamide, but not pseudocobalamin. Notably, the inability of V. cholerae to produce and utilize pseudocobalamin contrasts with enteric bacteria like Salmonella.     

A new pathway for the synthesis of α‐ribazole‐phosphate in Listeria innocua

The genomes of Listeria spp. encode all but one of 25 enzymes required for the biosynthesis of adenosylcobalamin (AdoCbl; coenzyme B₁₂). Notably, all Listeria genomes lack CobT, the nicotinamide mononucleotide:5,6‐dimethylbenzimidazole (DMB) phosphoribosyltransferase (EC 2.4.2.21) enzyme that synthesizes the unique α‐linked nucleotide N¹‐(5‐phospho‐α‐d ‐ribosyl)‐DMB (α‐ribazole‐5′‐P, α‐RP), a precursor of AdoCbl. We have uncovered a new pathway for the synthesis of α‐RP in Listeria innocua that circumvents the lack of CobT. The cblT and cblS genes (locus tags lin1153 and lin1110) of L. innocua encode an α‐ribazole (α‐R) transporter and an α‐R kinase respectively. Results from in vivo experiments indicate that L. innocua depends on CblT and CblS activities to salvage exogenous α‐R, allowing conversion of the incomplete corrinoid cobinamide (Cbi) into AdoCbl. Expression of the L. innocua cblT and cblS genes restored AdoCbl synthesis from Cbi and α‐R in a Salmonella enterica cobT strain. LinCblT transported α‐R across the cell membrane, but not α‐RP or DMB. UV‐visible spectroscopy and mass spectrometry data identified α‐RP as the product of the ATP‐dependent α‐R kinase activity of LinCblS. Bioinformatics analyses suggest that α‐R salvaging occurs in important Gram‐positive human pathogens.     

ArsAB, a novel enzyme from Sporomusa ovata activates phenolic bases for adenosylcobamide biosynthesis

In the homoacetogenic bacterium Sporomusa ovata, phenol and p‐cresol are converted into α‐ribotides, which are incorporated into biologically active cobamides (Cbas) whose lower ligand bases do not form axial co‐ordination bonds with the cobalt ion of the corrin ring. Here we report the identity of two S. ovata genes that encode an enzyme that transfers the phosphoribosyl group of nicotinate mononucleotide (NaMN) to phenol or p‐cresol, yielding α‐O‐glycosidic ribotides. The alluded genes were named arsA and arsB (for alpha‐ribotide synthesis), arsA and arsB were isolated from a genomic DNA library of S. ovata. A positive selection strategy using an Escherichia coli strain devoid of NaMN:5,6‐dimethylbenzimidazole (DMB) phosphoribosyltransferase (CobT) activity was used to isolate a fragment of S. ovata DNA that contained arsA and arsB, whose nucleotide sequences overlapped by 8 bp. SoArsAB was isolated to homogeneity, shown to be functional as a heterodimer, and to have highest activity at pH 9. SoArsAB also activated DMB to its α‐N‐glycosidic ribotide. Previously characterized CobT‐like enzymes activate DMB but do not activate phenolics. NMR spectroscopy was used to confirm the incorporation of phenol into the cobamide, and mass spectrometry was used to identify SoArsAB reaction products.     

Fluorinated vitamin b(12) analogs are cofactors of corrinoid-dependent enzymes: a f-labeled nuclear magnetic resonance probe for identifying corrinoid-protein interactions

The homoacetogenic bacterium Sporomusa ovata synthesized the vitamin B(12) analog phenolyl cobamide or 4-fluorophenolyl cobamide when the methanol medium of growing cells was supplemented with 10 mM phenol or 5 mM 4-fluorophenol. Phenol and, presumably, 4-fluorophenol were specifically incorporated into these cobamides, since phenol was not metabolized significantly into amino acids or into acetic acid, the product of the catabolism. The phenol-containing cobamides contributed up to 90% of the protein-bound cobamides of the 1,300 to 1,900 nmol of corrinoid per g of dry cell material formed. Fluorine-19 nuclear magnetic resonance spectroscopy of 4-fluorophenolyl cobamide exhibited a resonance near 30 ppm. An additional signal emerged at 25 ppm when 4-fluorophenolyl cobamide was investigated as the cofactor of a corrinoid-dependent protein. The two resonances indicated distinct cofactor arrangements within the protein's active site. A 5-ppm high-field shift change suggested van der Waal's interactions between the fluorinated nucleotide of the cofactor and adjacent amino acid residues of the enzyme. Similarly, Propionibacterium freudenreichii and Methanobacterium thermoautotrophicum synthesized 5-fluorobenzimidazolyl cobamide. The human corrinoid binders intrinsic factor, transcobalamin, and haptocorrin recognized this corrinoid like vitamin B(12). Hence, it is possible to use F-labeled nuclear magnetic resonance spectroscopy for analyses of protein-bound cobamides.     

Substitution of Co alpha-(5-hydroxybenzimidazolyl)cobamide (factor III) by vitamin B12 in Methanobacterium thermoautotrophicum.

Methanobacterium thermoautotrophicum grown on mineral medium contains 120 nmol of Co alpha-(5-hydroxybenzimidazolyl)cobamides (derivatives of factor III) per g of dry cell mass as the sole cobamide. The bacterium assimilated several corrinoids and benzimidazole bases during autotrophic growth. The corrinoids were converted into factor III; however, after three transfers in 5,6-dimethylbenzimidazole (200 microM)-supplemented mineral medium, derivatives of factor III were completely replaced by derivatives of vitamin B12, which is atypical for methanogens. The total cobamide content of these cells and their growth rate were not affected compared with factor III-containing cells. Therefore, the high cobamide content rather than a particular type of cobamide is required for metabolism of methanogens. Derivatives of factor III are not essential cofactors of cobamide-containing enzymes from methanogenic bacteria, but they are the result of a unique biosynthetic ability of these archaebacteria. The cobamide biosynthesis include unspecific enzymes, which made it possible either to convert non-species-derived corrinoids into derivatives of factor III or to synthesize other types of cobamides than factor III. The cobamide biosynthesis is regulated by its end product. In addition, the uptake of extracellular cobamides is controlled, and the assimilated corrinoids regulate cellular cobamide biosynthesis.     

Role of the precorrin 6-X reductase gene in cobamide biosynthesis in Methanococcus maripaludis

In Methanococcus maripaludis strain JJ, deletion of the homolog to cbiJ, which encodes the corrin biosynthetic enzyme precorrin 6-X reductase, yielded an auxotroph that required either cobamide or acetate for good growth. This phenotype closely resembled that of JJ117, a mutant in which tandem repeats were introduced into the region immediately downstream of the homolog of cbiJ. Mutant JJ117 also produced low quantities of cobamides, about 15 nmol g(-1) protein or 1-2% of the amount found in wild-type cells. These results confirm the role of the cbiJ homolog in cobamide biosynthesis in the Archaea and suggest the presence of low amounts of a bypass activity in these organisms.     

Blue LED and succinic acid enhance the growth of Rhodobacter sphaeroides

Rhodobacter sphaeroides is a purple non-sulfur photosynthetic bacteria that participates in the anoxic cycling of carbon both as the primary producer and as the light-stimulated consumers of the reduced organic compounds. In this study, six different organic acids, i.e. acetate, lactate, oxaloacetate, malate, succinate, and citrate, were selected and used to analyze the relationships between the organic acid source and the cell growth. The C₄ compound exhibited an enhanced cell growth compared to the other organic acids, and the growth rate of R. sphaeroides that was grown with 0.03 M succinic acid was significantly 3.2-fold faster than the C₆ compound of 0.03 M citrate. Additionally, the cell growth of R. sphaeroides was enhanced with increasing light intensity, and the growth rate and the dry cell weight of R. sphaeroides that were grown under the light conditions of 15 W/m² were 2.0- and 1.2-fold higher than R. sphaeroides at 3 W/m². Therefore, the high light intensity probably affected the growth of R. sphaeroides. Moreover, the blue-colored light emitting diode (LED) exhibited a highest growth rate and cell concentration of R. sphaeroides among the various types of LEDs, and the enhanced cell growth phenomenon under the blue LED conditions was dramatically stimulated at low concentrations of succinic acid, which was compensatory for succinic acid. Therefore, a high light intensity and a blue LED as the light source were necessary for the enhanced cell growth for the C₄ organic acid, i.e. succinic acid.     

Salmonella enterica synthesizes 5,6‐dimethylbenzimidazolyl‐(DMB)‐α‐riboside. Why some Firmicutes do not require the canonical DMB activation system to synthesize adenosylcobalamin

5,6‐Dimethylbenzimidazolyl‐(DMB)‐ α ‐ribotide [ α ‐ribazole‐5′‐phosphate ( α ‐RP)] is an intermediate in the biosynthesis of adenosylcobalamin (AdoCbl) in many prokaryotes. In such microbes, α ‐RP is synthesized by nicotinate mononucleotide (NaMN):DMB phosphoribosyltransferases (CobT in Salmonella enterica), in a reaction that is considered to be the canonical step for the activation of the base of the nucleotide present in adenosylcobamides. Some Firmicutes lack CobT‐type enzymes but have a two‐protein system comprised of a transporter (i.e., CblT) and a kinase (i.e., CblS) that can salvage exogenous α ‐ribazole ( α ‐R) from the environment using CblT to take up α ‐R, followed by α ‐R phosphorylation by CblS. We report that Geobacillus kaustophilus CblT and CblS proteins restore α ‐RP synthesis in S. enterica lacking the CobT enzyme. We also show that a S. enterica cobT strain that synthesizes GkCblS ectopically makes only AdoCbl, even under growth conditions where the synthesis of pseudoCbl is favored. Our results indicate that S. enterica synthesizes α ‐R, a metabolite that had not been detected in this bacterium and that GkCblS has a strong preference for DMB‐ribose over adenine‐ribose as substrate. We propose that in some Firmicutes DMB is activated to α ‐RP via α ‐R using an as‐yet‐unknown route to convert DMB to α ‐R and CblS to convert α ‐R to α ‐RP.     

Specificity of localization and phosphotransfer in the CheA proteins of Rhodobacter sphaeroides

Specificity of protein–protein interactions plays a vital role in signal transduction. The chemosensory pathway of Rhodobacter sphaeroides comprises multiple homologues of chemotaxis proteins characterized in organisms such as Escherichia coli. Three CheA homologues are essential for chemotaxis in R. sphaeroides under laboratory conditions. These CheAs are differentially localized to two chemosensory clusters, one at the cell pole and one in the cytoplasm. The polar CheA, CheA₂, has the same domain structure as E. coli CheA and can phosphorylate all R. sphaeroides chemotaxis response regulators. CheA₃ and CheA₄ independently localize to the cytoplasmic cluster; each protein has a subset of the CheA domains, with CheA₃ phosphorylating CheA₄ together making a functional CheA protein. Interestingly, CheA₃‐P can only phosphorylate two response regulators, CheY₆ and CheB₂. R. sphaeroides CheAs exhibit two interesting differences in specificity: (i) the response regulators that they phosphorylate and (ii) the chemosensory cluster to which they localize. Using a domain‐swapping approach we investigated the role of the P1 and P5 CheA domains in determining these specificities. We show that the P1 domain is sufficient to determine which response regulators will be phosphorylated in vitro while the P5 domain is sufficient to localize the CheAs to a specific chemosensory cluster.     

Rhodobacter sphaeroides,a novel tumor‐targeting bacteria that emits natural near‐infrared fluorescence

Several optical imaging techniques have been used to monitor bacterial tropisms for cancer. Most such techniques require genetic engineering of the bacteria to express optical reporter genes. This study investigated a novel tumor‐targeting strain of bacteria, Rhodobacter sphaeroides 2.4.1 (R. sphaeroides), which naturally emits near‐infrared fluorescence, thereby facilitating the visualization of bacterial tropisms for cancer. To determine the penetration depth of bacterial fluorescence, various numbers of cells (from 10⁸ to 10¹⁰ CFU) of R. sphaeroides and two types of Escherichia coli, which stably express green fluorescent protein (GFP) or red fluorescent protein (RFP), were injected s.c. or i.m. into mice. Bacterial tropism for cancer was determined after i.v. injection of R. sphaeroides (10⁸ CFU) into mice implanted s.c. with eight types of tumors. The intensity of the fluorescence signal in deep tissue (muscle) from R. sphaeroides was much stronger than from E. coli‐expressing GFP or RFP. The near‐infrared fluorescence signal from R. sphaeroides was visualized clearly in all types of human or murine tumors via accumulation of bacteria. Analyses of C‐reactive protein and procalcitonin concentrations and body weights indicated that i.v. injection of R. sphaeroides does not induce serious systemic immune reactions. This study suggests that R. sphaeroides could be used as a tumor‐targeting microorganism for the selective delivery of drugs to tumor tissues without eliciting a systemic immune reaction and for visualizing tumors.     

Mutants of Rhodopseudomonas sphaeroides useful in genetic analysis

Two kinds of mutants of Rhodopseudomonas sphaeroides that should be useful in extending genetic analysis of this organism have been isolated. One is deficient in recombination and has been used to isolate derivatives of the plasmid R 68.45 which incorporate chromosomal genes of R. sphaeroides. The other is apparently defective in a DNA restriction enzyme; transfer of plasmid borne chromosomal genes of R. sphaeroides from Escherichia coli back to R. sphaeroides is greatly enhanced in these mutants.In memory of R. Y. Stanier     

Overproducton of mannitol dehydrogenase in Rhodobacter sphaeroides

Mannitol dehydrogenase (MDH) from Rhodobacter sphaeroides Si4 was overproduced by constructing a strain that overexpresses the MDH gene and by producing high cell concentrations via fed-batch cultivation in a bioreactor. With the gene of mannitol dehydrogenase (mtlK) cloned into the expression vector pKK223-3 expression of MDH in Escherichia coli was obtained, but the specific enzyme activity was lower than in R. sphaeroides Si4. In order to overexpress mtlK in R. sphaeroides, plasmid pAK82 was constructed by cloning a DNA fragment carrying mtlK into the broad-host-range expression vector pRK415. When pAK82 was introduced into R. sphaeroides Si4 the specific mannitol dehydrogenase activity in the strain obtained was 0.48 unit (U)mg^–1, 3.4-fold higher thain in the wild type. In this way the enzyme yield from cultivation in a bioreactor could be improved from 110 Ul^–1 to 350 Ul^–1. A further increase in productivity was obtained by fed-batch cultivation of R. sphaeroides Si4 [pAK82]. Using this cultivation method can optical density of 27.6 was reached in the bioreactor, corresponding to a dry mass of 16.6 g l^–1. Since MDH formation correlated with biomass production, the MDH yield could be raised to 918 Ul^–1, an 8.3-fold increase in comparison to batch cultivation of the wild-type strain.Dedicated to Prof. Fritz Wagner on the occasion of his 65th birthday.     

Photooxidative stress‐induced and abundant small RNAs in Rhodobacter sphaeroides

Exposure to oxygen and light generates photooxidative stress by the bacteriochlorophyll a mediated formation of singlet oxygen (¹O₂) in Rhodobacter sphaeroides. Our study reports the genome‐wide search for small RNAs (sRNAs) involved in the regulatory response to ¹O₂. By using 454 pyrosequencing and Northern blot analysis, we identified 20 sRNAs from R. sphaeroides aerobic cultures or following treatment with ¹O₂ or superoxide (O^–₂). One sRNA was specifically induced by ¹O₂ and its expression depends on the extracytoplasmic function sigma factor RpoE. Two sRNAs induced by ¹O₂ and O^–₂ were cotranscribed with upstream genes preceded by promoters with target sequences for the alternative sigma factors RpoH_I and RpoH_II. The most abundant sRNA was processed in the presence of ¹O₂ but not by O^–₂. From this and a second sRNA a conserved 3′‐segment accumulated from a larger precursor. Absence of the RNA chaperone Hfq changed the half‐lives, abundance and processing of ¹O₂‐affected sRNAs. Orthologues of three sRNA genes are present in different alpha‐proteobacteria, but the majority was unique to R. sphaeroides or Rhodobacterales species. Our discovery that abundant sRNAs are affected by ¹O₂ exposure extends the knowledge on the role of sRNAs and Hfq in the regulatory response to oxidative stress.     

Patient mutations in human ATP:cob(I)alamin adenosyltransferase differentially affect its catalytic versus chaperone functions

Human ATP:cob(I)alamin adenosyltransferase (ATR) is a mitochondrial enzyme that catalyzes an adenosyl transfer to cob(I)alamin, synthesizing 5′-deoxyadenosylcobalamin (AdoCbl) or coenzyme B₁₂. ATR is also a chaperone that escorts AdoCbl, transferring it to methylmalonyl-CoA mutase, which is important in propionate metabolism. Mutations in ATR lead to methylmalonic aciduria type B, an inborn error of B₁₂ metabolism. Our previous studies have furnished insights into how ATR protein dynamics influence redox-linked cobalt coordination chemistry, controlling its catalytic versus chaperone functions. In this study, we have characterized three patient mutations at two conserved active site residues in human ATR, R190C/H, and E193K and obtained crystal structures of R190C and E193K variants, which display only subtle structural changes. All three mutations were found to weaken affinities for the cob(II)alamin substrate and the AdoCbl product and increase K_M(ATP). ³¹P NMR studies show that binding of the triphosphate product, formed during the adenosylation reaction, is also weakened. However, although the k_cat of this reaction is significantly diminished for the R190C/H mutants, it is comparable with the WT enzyme for the E193K variant, revealing the catalytic importance of Arg-190. Furthermore, although the E193K mutation selectively impairs the chaperone function by promoting product release into solution, its catalytic function might be unaffected at physiological ATP concentrations. In contrast, the R190C/H mutations affect both the catalytic and chaperoning activities of ATR. Because the E193K mutation spares the catalytic activity of ATR, our data suggest that the patients carrying this mutation are more likely to be responsive to cobalamin therapy.     

Differences in the control of bacteriochlorophyll formation by light and oxygen

Control of bacteriochlorophyll formation was studied with continuous cultures of Rhodospirillum rubrum, Rhodopseudomonas sphaeroides, and Rhodopseudomonas capsulata. Oxygen controlled specific bacteriochlorophyll contents of the three species in a hyperbolical fashion irrespective of the presence of light. In Rps. sphaeroides, this applied to oxygen concentrations above 16% air saturation of the medium while at lower oxygen concentrations control followed a kinetics with negative cooperativity. Cell protein formation of R. rubrum and Rsp. sphaeroides was independent of oxygen concentrations while protein formation of Rps. capsulata increased at lower concentrations. Light controlled bacteriochlorphyll contents of R. rubrum and Rps. sphaeroides in a sigmoidal fashion. When growing at a constant low oxygen concentration cell protein formation increased with light energy flux in Rps. sphaeroides but remained unaffected in R. rubrum. Protein formation of R. rubrum increased with light energy flux only under anaerobic conditions. Two factor analyses were performed with R. rubrum and Rps. sphaeroides to study the combined effects of light and oxygen on bacteriochlorophyll formation. The results showed that both factors act independent of each other.Abbreviations ALA 5-aminolevulinic acid - R Rhodospirillum - Rsp. Rhodopseudomonas     

Analysis of the expression of the Rhodobacter sphaeroides lexA gene

The regulation of the Rhodobacter sphaeroides lexA gene has been analyzed using both gel-mobility experiments and lacZ gene fusions. PCR-mediated mutagenesis demonstrated that the second GAAC motif in the sequence GAACN₇GAACN₇GAAC located upstream of the R. sphaeroides lexA gene is absolutely necessary for its DNA damage-mediated induction. Moreover, mutagenesis of either the first or the third GAAC motif in this sequence reduced, but did not abolish, the inducibility of the R. sphaeroides lexA gene. A R. sphaeroides lexA-defective (Def) mutant has also been constructed by replacing the active lexA gene with an inactivated gene copy constructed in vitro. Crude extracts of the R. sphaeroides lexA(Def) strain are unable to form any protein-DNA complex when added to the wild-type lexA promoter of R. sphaeroides. Likewise, the R. sphaeroides lexA(Def) cells constitutively express the recA and lexA genes. All these data clearly indicate that the lexA gene product is the negative regulator of the R. sphaeroides SOS response. Furthermore, the morphology, growth and viability of R. sphaeroides lexA(Def) cultures do not show any significant change relative to those of the wild-type strain. Hence, R. sphaeroides is so far the only bacterial species whose viability is known not to be affected by the presence of a lexA(Def) mutation. Received: 31 January 2000 / Accepted: 3 April 2000     

Occurrence of corrinoid-containing membrane proteins in anaerobic bacteria

In Methanobacterium thermoautotrophicum a corrinoid-carrying membrane protein complex has been found, to which a tentative role in methane formation has been ascribed. To test this hypothesis representatives from different orders of methanogenic bacteria were examined for membrane-bound cobamides. These species differed in cell carbon precursor, in methane precursor, in occurrence of cytochromes and of the enzyme CO dehydrogenase, and in the systematic position (Methanobacteriales, Methanomicrobiales). All methanogenic bacteria contained cobamides in the membranes in amounts of about 60 nmol/g cell dry weight, in addition to different amounts of cobamides in the soluble cell fraction. The only central metabolic reaction obviously common to all of these methanogens was methyl coenzyme M reduction to CH₄. It is concluded that the membrane corrinoid participates in this energy-conserving reaction.Sulfate-reducing and acetogenic bacteria were included in this survey. They contained different amounts of cobamides in the soluble cell fraction but not in the membrane, a possible exception being Acetobacterium woodii.     

Treatment of high strength organic wastewater by a mixed culture of photosynthetic microorganisms

The growth characteristics and nutrient removal fromsynthetic wastewater by Rhodobacter sphaeroides,Chlorella sorokiniana and Spirulinaplatensis were investigated under aerobic dark(heterotrophic) and aerobic light (photoheterotrophic)conditions. Both in terms of economy and efficiency,aerobic dark conditions were the best for wastewatertreatment using R. sphaeroides and C.sorokiniana, but light was necessary with S.platensis. Neither growth nor nutrient removalcharacteristics of the cells were affected insynthetic wastewater with as high as 10 000 ppmacetate, 1000 ppm propionate, 700 ppm nitrate and 100 ppmphosphate. Although R. sphaeroides and C. sorokiniana showed good growth in syntheticwastewater containing 400 ppm of ammonia, S.platensis was completely inhibited.When grown as a monoculture, none of thestrains could simultaneously remove acetate,propionate, ammonia, nitrate and phosphate from thewastewater. R. sphaeroides could remove allthe above nutrients except nitrate, but the rate of removal was relatively low. The rate of nutrientsremoval by C. sorokiniana was higher, but theorganism could not remove propionate; S.platensis could efficiently remove nitrate, ammoniaand phosphate, but none of the organic acids. A mixedculture of R. sphaeroides and C.sorokiniana was therefore used for simultaneousremoval of organic acids, nitrate, ammonia andphosphate. The optimum ratio of the cells depended onthe composition of the wastewater.