Cobalamin-dependent 1,2-propanediol utilization by Salmonella typhimurium

The enteric bacterium Salmonella typhimurium utilizes 1,2-propanediol as a sole carbon and energy source during aerobic growth, but only when the cells are also provided with cobalamin as a nutritional supplement. This metabolism is mediated by the cobalamin-dependent propanediol dehydratase enzyme pathway. Thirty-three insertion mutants were isolated that lacked the ability to utilize propanediol, but retained the ability to degrade propionate. This phenotype is consistent with specific blocks in one or more steps of the propanediol dehydratase pathway. Enzyme assays confirmed that propanediol dehydratase activity was absent in some of the mutants. Thus, the affected genes were designated pdu (for defects in propanediol utilization). Seventeen mutants carried pdu::lac operon fusions, and these fusions were induced by propanediol in the culture medium. All of the pdu mutations were located in a single region (41 map units) on the S. typhimurium chromosome between the his (histidine biosynthesis) and branch I cob (cobalamin biosynthesis) operons. They were shown to be P22-cotransducible with a branch I cob marker at a mean frequency of 12%. Mutants that carried deletions of the genetic material between his and cob also failed to utilize propanediol as a sole carbon source. Based upon the formation of duplications and deletions between different pairs of his::MudA and pdu::MudA insertions, the pdu genes were transcribed in a clockwise direction relative to the S. typhimurium genetic map.     

Salmonella typhimurium synthesizes cobalamin (vitamin B12) de novo under anaerobic growth conditions.

In this paper, we report that the enteric bacterium Salmonella typhimurium synthesized cobalamin de novo under anaerobic culture conditions. Aerobically, metE mutants of S. typhimurium need either methionine or cobalamin as a nutritional supplement for growth. The growth response to cobalamin depends upon a cobalamin-requiring enzyme, encoded by the gene metH, that catalyzes the same reaction as the metE enzyme. Anaerobically, metE mutants grew without any nutritional supplements; the metH enzyme functioned under these conditions due to the endogenous biosynthesis of cobalamin. This conclusion was confirmed by using a radiochemical assay to measure cobalamin production. Insertion mutants defective in cobalamin biosynthesis (designated cob) were isolated in the three major branches of the cobalamin biosynthetic pathway. Type I mutations blocked the synthesis of cobinamide, type II mutations blocked the synthesis of 5,6-dimethylbenzimidazole, and type III mutations blocked the synthesis of cobalamin from cobinamide and 5,6-dimethylbanzimidazole. Mutants that did not synthesize siroheme (cysG) were blocked in cobalamin synthesis. Genetic mapping experiments showed that the cob mutations are clustered in the region of the S. typhimurium chromosome between supD (40 map units) and his (42 map units). The discovery that S. typhimurium synthesizes cobalamin de novo only under anaerobic conditions raises the possibility that anaerobically grown cells possess a variety of enzymes which are dependent upon cobalamin as a cofactor.     

Characterization of the cobalamin (vitamin B12) biosynthetic genes of Salmonella typhimurium.

Salmonella typhimurium synthesizes cobalamin (vitamin B12) de novo under anaerobic conditions. Of the 30 cobalamin synthetic genes, 25 are clustered in one operon, cob, and are arranged in three groups, each group encoding enzymes for a biochemically distinct portion of the biosynthetic pathway. We have determined the DNA sequence for the promoter region and the proximal 17.1 kb of the cob operon. This sequence includes 20 translationally coupled genes that encode the enzymes involved in parts I and III of the cobalamin biosynthetic pathway. A comparison of these genes with the cobalamin synthetic genes from Pseudomonas denitrificans allows assignment of likely functions to 12 of the 20 sequenced Salmonella genes. Three additional Salmonella genes encode proteins likely to be involved in the transport of cobalt, a component of vitamin B12. However, not all Salmonella and Pseudomonas cobalamin synthetic genes have apparent homologs in the other species. These differences suggest that the cobalamin biosynthetic pathways differ between the two organisms. The evolution of these genes and their chromosomal positions is discussed.     

A Salmonella typhimurium cobalamin-deficient mutant blocked in 1-amino-2-propanol synthesis.

Salmonella typhimurium synthesizes cobalamin (vitamin B12) when grown under anaerobic conditions. All but one of the biosynthetic genes (cob) are located in a single operon which includes genes required for the production of cobinamide and dimethylbenzimidazole, as well as the genes needed to form cobalamin from these precursors. We isolated strains carrying mutations (cobD) which are unlinked to any of the previously described B12 biosynthetic genes. Mutations in cobD are recessive and map at minute 14 of the linkage map, far from the major cluster of B12 genes at minute 41. The cobD mutants appear to be defective in the synthesis of 1-amino-2-propanol, because they can synthesize B12 when this compound is provided exogenously. Labeling studies in other organisms have shown that aminopropanol, derived from threonine, is the precursor of the chain linking dimethylbenzimidazole to the corrinoid ring of B12. Previously, a three-step pathway has been proposed for the synthesis of aminopropanol from threonine, including two enzymatic steps and a spontaneous nonenzymatic decarboxylation. We assayed the two enzymatic steps of the hypothetical pathway; cobD mutants are not defective in either. Furthermore, mutants blocked in one step of the proposed pathway continue to make B12. We conclude that the aminopropanol for B12 synthesis is not made by this pathway. Expression of a lac operon fused to the cobD promoter is unaffected by vitamin B12 or oxygen, both of which are known to repress the main cob operon, suggesting that the cobD gene is not regulated.     

The cobalamin (coenzyme B12) biosynthetic genes of Escherichia coli.

The enteric bacterium Escherichia coli synthesizes cobalamin (coenzyme B12) only when provided with the complex intermediate cobinamide. Three cobalamin biosynthetic genes have been cloned from Escherichia coli K-12, and their nucleotide sequences have been determined. The three genes form an operon (cob) under the control of several promoters and are induced by cobinamide, a precursor of cobalamin. The cob operon of E. coli comprises the cobU gene, encoding the bifunctional cobinamide kinase-guanylyltransferase; the cobS gene, encoding cobalamin synthetase; and the cobT gene, encoding dimethylbenzimidazole phosphoribosyltransferase. The physiological roles of these sequences were verified by the isolation of Tn10 insertion mutations in the cobS and cobT genes. All genes were named after their Salmonella typhimurium homologs and are located at the corresponding positions on the E. coli genetic map. Although the nucleotide sequences of the Salmonella cob genes and the E. coli cob genes are homologous, they are too divergent to have been derived from an operon present in their most recent common ancestor. On the basis of comparisons of G+C content, codon usage bias, dinucleotide frequencies, and patterns of synonymous and nonsynonymous substitutions, we conclude that the cob operon was introduced into the Salmonella genome from an exogenous source. The cob operon of E. coli may be related to cobalamin synthetic genes now found among non-Salmonella enteric bacteria.     

The CobII and CobIII regions of the cobalamin (vitamin B12) biosynthetic operon of Salmonella typhimurium.

A detailed deletion map of the CobII and CobIII regions of the cobalamin biosynthetic (cob) operon of Salmonella typhimurium LT2 has been constructed. The CobII region encodes functions needed for the synthesis of lower ligand 5,6-dimethylbenzimidazole (DMB); CobIII encodes functions needed for the synthesis of the nucleotide loop that joins DMB to the corrin macrocycle. The genetic analysis of 117 deletion, insertion, and point mutations indicates that (i) the CobII and CobIII mutations are contiguous--that is, they are grouped according to function; (ii) the CobII region is composed of four complementation groups (cobJKLM); (iii) cobM mutations do not complement mutations in any of the other three CobII groups; and (iv) CobIII mutations include three complementation groups that correspond to the cobU, cobS, and cobT genes.     

Evolution of Coenzyme B(12) Synthesis among Enteric Bacteria: Evidence for Loss and Reacquisition of a Multigene Complex

We have examined the distribution of cobalamin (coenzyme B(12)) synthetic ability and cobalamin-dependent metabolism among enteric bacteria. Most species of enteric bacteria tested synthesize cobalamin under both aerobic and anaerobic conditions and ferment glycerol in a cobalamin-dependent fashion. The group of species including Escherichia coli and Salmonella typhimurium cannot ferment glycerol. E. coli strains cannot synthesize cobalamin de novo, and Salmonella spp. synthesize cobalamin only under anaerobic conditions. In addition, the cobalamin synthetic genes of Salmonella spp. (cob) show a regulatory pattern different from that of other enteric taxa tested. We propose that the cobalamin synthetic genes, as well as genes providing cobalamin-dependent diol dehydratase, were lost by a common ancestor of E. coli and Salmonella spp. and were reintroduced as a single fragment into the Salmonella lineage from an exogenous source. Consistent with this hypothesis, the S. typhimurium cob genes do not hybridize with the genomes of other enteric species. The Salmonella cob operon may represent a class of genes characterized by periodic loss and reacquisition by host genomes. This process may be an important aspect of bacterial population genetics and evolution.     

Reduction of Cob(III)alamin to Cob(II)alamin in Salmonella enterica serovar typhimurium LT2

Reduction of the cobalt ion of cobalamin from the Co(III) to the Co(I) oxidation state is essential for the synthesis of adenosylcobalamin, the coenzymic form of this cofactor. A cob(II)alamin reductase activity in Salmonella enterica serovar Typhimurium LT2 was isolated to homogeneity. N-terminal analysis of the homogeneous protein identified NAD(P)H:flavin oxidoreductase (Fre) (EC 1.6.8.1) as the enzyme responsible for this activity. The fre gene was cloned, and the overexpressed protein, with a histidine tag at its N terminus, was purified to homogeneity by nickel affinity chromatography. His-tagged Fre reduced flavins (flavin mononucleotide [FMN] and flavin adenine dinucleotide [FAD]) and cob(III)alamin to cob(II)alamin very efficiently. Photochemically reduced FMN substituted for Fre in the reduction of cob(III)alamin to cob(II)alamin, indicating that the observed cobalamin reduction activity was not Fre dependent but FMNH(2) dependent. Enzyme-independent reduction of cob(III)alamin to cob(II)alamin by FMNH(2) occurred at a rate too fast to be measured. The thermodynamically unfavorable reduction of cob(II)alamin to cob(I)alamin was detectable by alkylation of the cob(I)alamin nucleophile with iodoacetate. Detection of the product, caboxymethylcob(III)alamin, depended on the presence of FMNH(2) in the reaction mixture. FMNH(2) failed to substitute for potassium borohydride in in vitro assays for corrinoid adenosylation catalyzed by the ATP:co(I)rrinoid adenosyltransferase (CobA) enzyme, even under conditions where Fre and NADH were present in the reaction mixture to ensure that FMN was always reduced. These results were interpreted to mean that Fre was not responsible for the generation of cob(I)alamin in vivo. Consistent with this idea, a fre mutant displayed wild-type cobalamin biosynthetic phenotypes. It is proposed that S. enterica serovar Typhimurium LT2 may not have a cob(III)alamin reductase enzyme and that, in vivo, nonadenosylated cobalamin and other corrinoids are maintained as co(II)rrinoids by reduced flavin nucleotides generated by Fre and other flavin oxidoreductases.     

An adenosyl-cobalamin (coenzyme-B12)-repressed translational enhancer in the cob mRNA of Salmonella typhimurium

Expression of the cobalamin (Cbl) biosynthetic cob operon in Salmonella typhimurium is repressed by the end-product. This regulation is conferred mainly at the translational level and involves a cobalamin-induced folding of an RNA hairpin that sequesters the ribosomal binding site (RBS) of the cob mRNA and prevents translation initiation. A combined structural and mutational analysis shows that a cis-acting translational enhancer (TE) element, located 83 nucleotides upstream of the Shine-Dalgarno sequence in the 5'-untranslated region (5'-UTR) of the cob mRNA, is required to unfold the inhibitory RBS hairpin in the absence of cobalamin. The TE element, which consists of 5 nucleotides, is proposed to confer its enhancer function in the absence of cobalamin by interacting with nucleotides in the stem of the RBS hairpin. This interaction destabilizes the RNA hairpin and allows ribosome binding. In the presence of cobalamin, the enhancer function is inhibited. As a result, the RBS hairpin forms and prevents translation initiation. Several additional RNA hairpins in the 5'-UTR were also identified and are suggested to be important for repression. The above data suggest that normal cobalamin repression of the cob operon requires that the 5'-UTR has a defined secondary and tertiary structure.     

cobA function is required for both de novo cobalamin biosynthesis and assimilation of exogenous corrinoids in Salmonella typhimurium

Salmonella typhimurium is able to synthesize cobalamin (B12) under anaerobic growth conditions. The previously described cobalamin biosynthetic mutations (phenotypic classes CobI, CobII, and CobIII) map in three operons located near the his locus (minute 41). A new class of mutant (CobIV) defective in B12 biosynthesis was isolated and characterized. These mutations map between the cysB and trp loci (minute 34) and define a new genetic locus, cobA. The anaerobic phenotype of cobA mutants suggests an early block in corrin ring formation; mutants failed to synthesize cobalamin de novo but did so when the corrin ring is provided as cobyric acid dicyanide or as cobinamide dicyanide. Under aerobic conditions, cobA mutants were unable to convert either cobyric acid dicyanide or cobinamide dicyanide to cobalamin but could use adenosylcobyric acid or adenosylcobinamide as a precursor; this suggests that the mutants are unable to adenosylate exogenous corrinoids. To explain the anaerobic CobI phenotype of a cobA mutant, we propose that the cobA gene product catalyzes adenosylation of an early intermediate in the de novo B12 pathway and also adenosylates exogenous corrinoids. Under anaerobic conditions, a substitute function, known to be encoded in the main Cob operons, is induced; this substitute function can adenosylate exogenous cobyric acid and cobinamide but not the early biosynthetic intermediate. The cobA gene of S. typhimurium appears to be functionally equivalent to the btuR gene of Escherichia coli.     

Kinetics of cobalamin repression of the cob operon in Salmonella typhimurium

Abstract The cob operon in Salmonella typhimurium encodes 25 proteins involved in the biosynthesis of cobalamin. Expression of the cob operon is negatively feedback regulated by cobalamin via a translational control mechanism. The concentration of cobalamin required to repress cob expression to half-maximal was determined in vivo and in vitro to 0.4 μM and 0.6 μM, respectively. These results suggest that cob expression in wild-type cells is partially repressed by de novo synthesized cobalamin.     

Cobalamin (vitamin B(12)) biosynthesis in Rhodobacter capsulatus

In Rhodobacter capsulatus, cobalamin biosynthesis has been shown to occur when the bacteria are grown either aerobically or anaerobically. However, a comparison of the main cobalamin biosynthetic operon found within R. capsulatus would suggest that the encoded proteins belong to the oxygen-dependent pathway for cobalamin biosynthesis, although, significantly, no homologue of the essential mono-oxygenase CobG has yet been detected. Nonetheless, within this main cob operon is found a large open reading frame termed orf663 that is not found in any other cobalamin biosynthetic operon. When overproduced in Escherichia coli, orf663 was found to encode a 90 kDa integral membrane protein. Some of this protein is cleaved within E. coli to give a soluble N-terminal region that can easily be purified and yields a 50 kDa flavoprotein. When expressed in harness with the genes for precorrin-3a synthesis, ORF663 appears to mediate the transformation of precorrin-3a into a new chromophoric compound. Another open reading frame in close proximity to orf663 is termed orf647, and was found to encode a 2Fe-2S ferredoxin-like protein. We suggest that these two proteins may provide an alternative oxygen-independent mechanism for ring contraction within R. capsulatus.     

Effect of plasmid pKM101 on the expression of bacterial genes not related to DNa metabolism]

An experimental system ensuring fusion of bacterial genes to the lac operon of the Mu dl(Aplac) phage was used. Fusion operons in which the lac operon was under the control of promoters of the elt gene, responsible for synthesis of the LT toxin, of the tetracyclin-resistance tet gene, and sfiA gene encoding filament production, was studied. Using this experimental system, plasmid pKM101 was shown to be capable of activating the expression of the above Escherichia coli and Salmonella typhimurium genes, which is manifested as the activation of beta-galactosidase synthesis. The activation of the elt gene expression by the pKM101 plasmid was also confirmed in experiments on detecting the LT toxin synthesized by bacteria carrying this plasmid. Effect of the plasmid on the activation of elt operon expression, unlike the effect of this plasmid on mutability, does not depend on the functioning of the lexA and recA genes, i.e., this is not a SOS-regulated process. The mutant plasmid pGW12, a derivative of pKM101, deficient in the mucAB genes responsible for mutagenesis, causes a more pronounced activation of the elt gene than plasmid pKM101.     

Oxygen-regulated stimulons of Salmonella typhimurium identified by Mu d(Ap lac) operon fusions

Using the technique of Mu d1(Ap lac)-directed lacZ operon fusions, several oxygen-regulated genetic loci were identified in Salmonella typhimurium. Thirteen anaerobically inducible and six aerobically inducible operon fusions were identified. Based on control by the oxrA and oxrB regulatory loci, the anti-lacZ fusions were grouped into three classes: class I loci were regulated by both oxr loci, class II genes were regulated by oxrA only, and class III loci were not affected by either regulatory locus. Several of the anti-lacZ fusions required growth in complex medium before they exhibited the inducible phenotype. While the expression of some of these loci was repressed when organisms were grown in nitrate, others were stimulated by nitrate. Fusions into the hyd and phs loci were identified among the isolated anti-lacZ fusions. Six oxygen-inducible (oxi) operon fusions were also identified. Two of the oxi loci mapped near oxygen-regulatory loci: oxiC near oxrA and oxiE near oxyR. However, neither fusion appeared to occur within the regulatory locus. The data presented serve to further define the aerobic and anaerobic stimulons of S. typhimurium but indicate additional regulatory circuits above those already defined.