Suppression of the btuB451 mutation by mutations in the tonB gene suggests a direct interaction between TonB and TonB-dependent receptor proteins in the outer membrane of Escherichia coli

In cells of Escherichia coli, the function of the tonB gene is needed for energy-dependent transport processes mediated by the outer-membrane receptors for iron siderophore complexes and vitamin B12. The btuB451 mutation has the same effect on vitamin B12 transport as does a tonB mutation. When a btuB451 strain carried a plasmid with the intact tonB gene, partial revertant strains were isolated which had acquired the ability to grow on 5 nM vitamin B12. This suppression activity was associated with the plasmid, suggesting that a mutation within the tonB gene on the plasmid allowed the mutant BtuB receptor to function in the transport of the vitamin. The nucleotide sequence of the entire tonB gene of ten independently isolated suppressing plasmids was determined. Only a single nucleotide change had occurred in each of the cases. The same codon was always affected resulting in the conversion of glutamine-165 to a leucine in seven of the ten isolates and to a lysine in the other three. The phenotype of strains carrying both types of altered tonB genes showed the retention of their function for other TonB-dependent processes in addition to their suppressor properties with respect to the btuB451 mutation. The fact that mutations suppressing the btuB451 mutation occurred in the tonB gene suggests that there is a direct interaction between TonB and TonB-dependent receptors in the outer membrane of E. coli.     

Two outer membrane transport systems for vitamin B12 in Salmonella typhimurium.

The involvement of an outer membrane transport component for vitamin B12 uptake in Salmonella typhimurium, analogous to the btuB product in Escherichia coli, was investigated. Mutants of S. typhimurium selected for resistance to bacteriophage BF23 carried mutations at the btuB locus (butBS) (formerly called bfe, at the analogous map position as the E. coli homolog) and were defective in high-affinity vitamin B12 uptake. The cloned E. coli btuB gene (btuBE) hybridized to S. typhimurium genomic DNA and restored vitamin B12 transport activity to S. typhimurium btuBS mutants. An Mr-60,000 protein in the S. typhimurium outer membrane was repressed by growth with vitamin B12 and was eliminated in a btuBS mutant. The btuBS product thus appears to play the same role in vitamin B12 transport by S. typhimurium as does the E. coli btuBE product. A second vitamin B12 transport system that is not present in E. coli was found by cloning a fragment of S. typhimurium DNA that complemented btuB mutants for vitamin B12 utilization. In addition to this plasmid with a 6-kilobase insert of S. typhimurium DNA, vitamin B12 utilization by E. coli btuB strains required the btuC and btuD products, necessary for transport across the cytoplasmic membrane, but not the btuE or tonB product. The plasmid conferred low levels of vitamin B12-binding and energy-dependent transport activity but not susceptibility to phage BF23 or utilization of dicyanocobinamide. The cloned S. typhimurium DNA encoding this new transport system did not hybridize to the btuBE gene or to E. coli chromosomal DNA and therefore does not carry the S. typhimurium btuBS locus. Increased production of an Mr -84,000 polypeptide associated with the outer membrane was seen. The new locus appears to be carried on the large plasmid in most S. typhimurium strains. Thus S. typhimurium possesses both high- and low-affinity systems for uptake of cobalamins across the outer membrane.     

Mutations affecting regulation of methionine biosynthetic genes isolated by use of met-lac fusions.

Fusions of the lac genes to the promoters of four structural genes in the methionine biosynthetic pathway, metA, metB, metE, and metF, were obtained by the use of the Mu d(Ap lac) bacteriophage. The levels of beta-galactosidase in these strains could be derepressed by growth under methionine-limiting conditions. Furthermore, growth in the presence of vitamin B12 repressed the synthesis of beta-galactosidase in strains containing a fusion of lacZ to the metE promoter, phi(metE'-lacZ+). Mutations affecting the regulation of met-lac fusions were generated by the insertion of Tn5. Tn5 insertions were obtained at the known regulatory loci metJ and metK. Interestingly, a significant amount of methionine adenosyltransferase activity remained in the metK mutant despite the fact that the mutation was generated by an insertion. Several Tn5-induced regulatory mutations were isolated by screening for high-level beta-galactosidase expression in a phi(metE'-lacZ+) strain in the presence of vitamin B12. Tn5 insertions mapping at the btuB (B12 uptake), metH (B12 dependent tetrahydropteroylglutamate methyltransferase), and metF (5,10-methylenetetrahydrofolate reductase) loci were obtained. The isolation of the metH mutant was consistent with previous suggestions that the metH gene product is required for the repression of metE by vitamin B12. The metF::Tn5 insertion was of particular interest since it suggested that a functional metf gene product was also needed for repression of metE by vitamin B12.     

Investigation of the regulation of the Escherichia coli btuB gene using operon fusions

Operon fusions were isolated between Mu dX (lac CmR ApR) and btuB, the gene encoding the multivalent vitamin B12 outer membrane receptor. Using these fusions, vitamin B12-mediated repression of btuB in Escherichia coli was demonstrated. Mutations in metH, metE and ompR as well as exogenous methionine, membrane pertubants, high osmolar conditions and temperature had no major effect on the expression of the btuB gene.     

Nucleotide sequence of the gene for the vitamin B12 receptor protein in the outer membrane of Escherichia coli.

The nucleotide sequence of a 2220-base-pair fragment containing the btuB gene of Escherichia coli was determined. There was a single open reading frame which was translated into a 614-amino-acid polypeptide, the first 20 amino acids of which comprised a typical leader sequence. The putative mature or processed form had a molecular weight (66,400) and a composition in close agreement with that determined for the purified receptor. The distribution of amino acids in the receptor protein was similar to that of other outer membrane proteins, showing a fairly even distribution of charged residues and the absence of extensive hydrophobic stretches. The btuB451 mutation appears to alter the receptor to eliminate its ability to function in vitamin B12 uptake without affecting its ligand binding properties. The sequence of the DNA from this mutant was determined and revealed a leucine-to-proline (C-to-T transition) change in the eighth amino acid of the mature form.     

Colicin A receptor: role of two Escherichia coli outer membrane proteins (OmpF protein and btuB gene product) and lipopolysaccharide.

ompF cells were completely resistant to colicin A, whereas btuB cells were partially resistant. The OmpF protein, in the presence of added lipopolysaccharide, inactivated colicin A. This inactivation was enhanced by added btuB gene product, btuB gene product with lipopolysaccharide did not inactivate colicin A. These data, together with the observation that vitamin B12 protected btuB+ cells from the killing effect of colicin A, suggest that the colicin A receptor in Escherichia coli K-12 is composed of the OmpF protein, the btuB gene product, and lipopolysaccharide.     

Genetic suppression demonstrates interaction of TonB protein with outer membrane transport proteins in Escherichia coli.

Energy-coupled reactions of the Escherichia coli outer membrane transport proteins BtuB and Cir require the tonB product. Some point mutations in a region of btuB and cir that is highly conserved in TonB-dependent transport proteins led to loss of TonB-coupled uptake of vitamin B12 and colicin Ia, whereas binding was unaffected. Most other point mutations in this region had no detectable effect on transport activity. Mutations in tonB that suppressed the transport defect phenotype of these btuB mutations were isolated. All carried changes of glutamine 165 to leucine, lysine, or proline. The various tonB mutations differed markedly in their suppression activities on different btuB or cir mutations. This allele specificity of suppression indicates that TonB interacts directly with the outer membrane transport proteins in a manner that recognizes the local conformation but not specific side chains within this conserved region. An effect of the context of the remainder of the protein was seen, since the same substitution (valine 10----glycine) in btuB and cir responded differently to the suppressors. This finding supports the proposal that TonB interacts with more of the transport proteins than the first conserved domain alone.     

Transport of vitamin B12 in Escherichia coli: cloning of the btuCD region.

The transport of vitamin B12 in Escherichia coli requires a specific vitamin B12 receptor protein in the outer membrane and the tonB gene product. In addition, the btuC gene, located at min 38 on the genetic map, has been found to influence vitamin B12 uptake or utilization. The btuC function is required for the growth response to vitamin B12 when the outer membrane transport process (btuB or tonB function) is defective. However, even in a wild-type strain, btuC is required for proper transport of vitamin B12. Additional mutations in the vicinity of btuC were isolated as lac fusions that produced a phenotype similar to that of a btuC mutant. The btuC region was cloned by selection for complementation of a btuC mutation. Complementation testing with plasmids carrying various deletions or transposon Tn1000 insertions demonstrated that the new mutations defined a separate, independently expressed locus, termed btuD. The coding regions for both genes were identified on a 3.4-kilobase HindIII-HincII fragment and were 800 to 1,000 base pairs in length. They were separated by a 600- to 800-base-pair region. The gene order in this portion of the chromosome map was found to be pps-zdh-3::Tn10-btuD-btuC-pheS. Expression of beta-galactosidase in the btuD-lac fusion-bearing strains, whether proficient or defective in vitamin B12 transport, was not regulated by the presence of vitamin B12 in the growth medium.     

Genetic analysis of components involved in vitamin B12 uptake in Escherichia coli.

The products of three genes are involved in cyanocobalamin (B(12)) uptake in Escherichia coli. btuB (formerly bfe), located at min 88 on the Escherichia coli linkage map, codes for a protein component of the outer membrane which serves as receptor for B(12), the E colicins, and bacteriophage BF23. Four phenotypic classes of mutants varying in response to these agents were found to carry mutations that, based on complementation and reversion analyses, reside in the single btuB cistron. In one mutant class, ligand binding to the receptor appeared to be normal, but subsequent B(12) uptake was defective. The level of receptor and rate of uptake were responsive to btuB gene dosage. Previous studies showed that the tonB product was necessary for energy-dependent B(12) uptake but not for its binding. Other than those in tonB, no mutations that conferred insensitivity to group B colicins affected B(12) utilization. The requirement for the btuB and tonB products could be bypassed by elevated levels of B(12) (>1 muM) or by mutations compromising the integrity of the outer membrane as a permeability barrier. Utilization of elevated B(12) concentrations in strains lacking the btuB-tonB uptake system was dependent on the function of the btuC product. This gene was located at 37.7 min on the linkage map, with the order pps-btuC-pheS. Strains altered in btuC but with an intact btuB-tonB system were only slightly impaired in B(12) utilization, being defective in its accumulation. This defect was manifested as inability to retain B(12), such that intracellular label was almost completely lost by exchange or efflux. It is proposed that btuC encodes a transport system for B(12) in the periplasm.     

Cloning and expression of the gene for the vitamin B12 receptor protein in the outer membrane of Escherichia coli.

The transport of cyanocobalamin (vitamin B12) in cells of Escherichia coli is dependent on a receptor protein (BtuB protein) located in the outer membrane. A 9.1-kilobase pair BamHI fragment carrying the btuB gene was cloned from a specialized transducing phage into multicopy plasmids. Insertions of transposon Tn1000 which prevented production of the receptor localized btuB to a 2-kilobase pair region. Further subcloning allowed isolation of this region as a 2.3-kilobase pair Sau3A fragment. The BtuB+ plasmids were shown by maxicell analysis to encode a polypeptide with a molecular weight of 66,000 in the outer membrane. This polypeptide was missing in cells with Tn1000 insertions in btuB and was reduced in amount upon growth of plasmid-bearing cells in repressing concentrations of vitamin B12. Several Tn1000 insertions outside the 5' end of the coding region exhibited reduced production of receptor. A deletion at the 3' end of btuB resulted in formation of an altered receptor. Amplified production of this polypeptide was associated with increased levels of binding of the receptor's ligands (vitamin B12 and phage BF23), increased rates of vitamin B12 uptake, and altered susceptibility to the group E colicins. Deficiency in various major outer membrane proteins did not affect production of the btuB product, and the amplified levels of this protein partially reversed the tolerance to E colicins seen in these mutants.     

The 17-Gene Ethanolamine (eut) Operon of Salmonella typhimurium Encodes Five Homologues of Carboxysome Shell Proteins

The eut operon of Salmonella typhimurium encodes proteins involved in the cobalamin-dependent degradation of ethanolamine. Previous genetic analysis revealed six eut genes that are needed for aerobic use of ethanolamine; one (eutR), encodes a positive regulator which mediates induction of the operon by vitamin B12 plus ethanolamine. The DNA sequence of the eut operon included 17 genes, suggesting a more complex pathway than that revealed genetically. We have correlated an open reading frame in the sequence with each of the previously identified genes. Nonpolar insertion and deletion mutations made with the Tn10-derived transposable element T-POP showed that at least 10 of the 11 previously undetected eut genes have no Eut phenotype under the conditions tested. Of the dispensable eut genes, five encode apparent homologues of proteins that serve (in other organisms) as shell proteins of the carboxysome. This bacterial organelle, found in photosynthetic and sulfur-oxidizing bacteria, may contribute to CO2 fixation by concentrating CO2 and excluding oxygen. The presence of these homologues in the eut operon of Salmonella suggests that CO2 fixation may be a feature of ethanolamine catabolism in Salmonella.     

Analysis of btuB receptor function by use of nonsense suppression.

Informational suppression of btuB nonsense mutants allows the study of the effect of known, single amino acid substitutions on receptor function. We found that ligand uptake is largely unaffected by such amino acid changes. The few instances in which certain substitutions destroyed sensitivity to the two lethal agents (phage BF23, colicin E3) without affecting vitamin B12 uptake suggest a common region on the btuB receptor involved in the binding of these proteinaceous agents.     

Isolation and genetic characterizations of Bacillus megaterium cobalamin biosynthesis-deficient mutants

Ethanolamine is deaminated by the action of ethanolamine ammonia-lyase (EC 4.3.1.7), an adenosylcobalamin-dependent enzyme. Consequently, to grow on ethanolamine as a sole nitrogen source, Bacillus megaterium requires vitamin B12. Identification of B. megaterium mutants deficient for growth on ethanolamine as the sole nitrogen source yielded a total of 34 vitamin B12 auxotrophs. The vitamin B12 auxotrophs were divided into two major phenotypic groups: Cob mutants, which could use cobinamide or vitamin B12 to grow on ethanolamine, and Cbl mutants, which could be supplemented only by vitamin B12. The Cob mutants were resolved into six classes and the Cbl mutants were resolved into three, based on the spectrum of cobalt-labeled corrinoid compounds which they accumulated. Although some radiolabeled cobalamin was detected in the wild type, little or none was evident in the auxotrophs. The results indicate that Cob mutants contain lesions in biosynthetic steps before the synthesis of combinamide, while Cbl mutants are defective in the conversion of cobinamide to cobalamin. Analysis of phage-mediated transduction experiments revealed tight genetic linkage within the Cob class and within the Cbl class. Similar transduction analysis indicated the Cob and Cbl classes are weakly linked. In addition, cross-feeding experiments in which extracts prepared from mutants were examined for their effect on growth of various other mutants allowed a partial ordering of mutations within the cobalamin biosynthetic pathway.     

Biosynthesis of corriphyrins - a new branch of metabolism of tetrapyrrole compounds

Experiments were carried out to study biosynthesis of tetrapyrrole pigments--corriphyrins which are methylated reduced derivatives of uroporphyrin III. It was shown that the pattern of corriphyrin synthesis was close to that of vitamin B12. The mutant strain of propionic bacteria which was active in the vitamin B12 formation synthesized significantly more corriphyrins than the original strain. The corriphyrin synthesis was stimulated by delta-aminolevulinic acid and methionine and was inhibited by hydroxylamine and aeration. The formation of corriphyrins was repressed by vitamin B12. It is concluded that corriphyrins are precursors of vitamin B12 at the stage between uroporphyrinogene III and cobyrinic acid. The paper discusses further investigations of metabolism of methylated derivatives of uroporphyrinogene III as a method of elucidating the evolution of tetrapyrrole compounds and clarifying the processes involved in porphyrin metabolism in higher plants and animals.     

Operator-constitutive mutants in the threonine operon of Escherichia coli K-12.

Three Escherichia coli K-12 mutant strains resistant to DL-alpha-amino-beta-hydroxyvaleric acid were isolated in which the expression of the thr operon is constitutive. The localization and dominance properties of the mutations involved, called thrO, are those of operator mutations. The gene sequence is OABC as suggested by earlier studies.