The Escherichia coli CcmG protein fulfils a specific role in cytochrome c assembly.

In Escherichia coli K-12, c-type cytochromes are synthesized only during anaerobic growth with trimethylamine-N-oxide, nitrite or low concentrations of nitrate as the terminal electron acceptor. A thioredoxin-like protein, CcmG, is one of 12 proteins required for their assembly in the periplasm. Its postulated function is to reduce disulphide bonds formed between correctly paired cysteine residues in the cytochrome c apoproteins prior to haem attachment by CcmF and CcmH. We report that loss of CcmG synthesis by mutation was not compensated by a second mutation in disulphide-bond-forming proteins, DsbA or DsbB, or by the chemical reductant, 2-mercaptoethanesulphonic acid. An anti-CcmG polyclonal antibody was used in Western-blot analysis to probe the redox state of CcmG in mutants defective in the synthesis of other proteins essential for cytochrome c assembly. The oxidized form of CcmG accumulated not only in trxA or dipZ mutants defective in the transfer of electrons from the cytoplasm for disulphide isomerization and reduction reactions in the periplasm, but also in ccmF and ccmH mutants. The requirement of both CcmF and CcmH for the reduction of the disulphide bond in CcmG indicates that CcmG functions later than CcmF and CcmH in cytochrome c assembly, rather than in electron transfer from the membrane-associated DipZ (also known as DsbD) to CcmH. The data support a model proposed by others in which CcmG catalyses one of the last reactions specific to cytochrome c assembly.

The CcmE protein from Escherichia coli is a haem-binding protein.

We previously reported that a 17.5-kDa haem-binding polypeptide accumulates in Escherichia coli K-12 mutants defective in an essential gene for cytochrome c assembly, ccmF, and speculated that this polypeptide is either CcmE or CcmG. The haem-containing polypeptide, which is associated with the cytoplasmic membrane, has now been identified by N-terminal sequencing to be CcmE. The haem-dependent peroxidase activity of CcmE is clearly visible not only in a ccmF mutant, but also in ccmG and ccmH mutants, implying that CcmE functions either before or in the same step as CcmF, CcmG and CcmH in cytochrome c maturation. A trxA mutant, like the dipZ mutant, was unable to assemble c-type cytochromes or catalyse formate-dependent nitrite reduction: both activities were restored in the trxA and dipZ, but not ccmG, mutants by the reducing agent, 2-mercaptoethanesulphonic acid. Our data suggest that haem transferred across the cytoplasmic membrane by the CcmABCD complex becomes associated with CcmE, possibly by a labile covalent bond, before it is transferred to the cytochrome c apoproteins by the periplasmic haem lyase encoded by ccmF and ccmH. We further propose that CcmG is essential to reduce the disulphide bonds formed in cytochrome c apoproteins by DsbA, before haem is attached by the haem lyase. Electrons for disulphide bond reduction are supplied from thioredoxin in the cytoplasm via DipZ in the membrane, but can be replaced by the chemical reductant, 2-mercaptoethanesulphonic acid. According to this model, CcmG is the last protein in the reducing pathway which interacts stereospecifically with the apoprotein.

Involvement of products of the nrfEFG genes in the covalent attachment of haem c to a novel cysteine-lysine motif in the cytochrome c552 nitrite reductase from Escherichia coli.

Cytochrome c552 is the terminal component of the formate-dependent nitrite reduction pathway of Escherichia coli. In addition to four 'typical' haem-binding motifs, CXXCH-, characteristic of c-type cytochromes, the N-terminal region of NrfA includes a motif, CWSCK. Peptides generated by digesting the cytochrome from wild-type bacteria with cyanogen bromide followed by trypsin were analysed by on-line HPLC MS/MS in parent scanning mode. A strong signal at mass 619, corresponding to haem, was generated by fragmentation of a peptide of mass 1312 that included the sequence CWSCK. Neither this signal nor the haem-containing peptide of mass 1312 was detected in parallel experiments with cytochrome that had been purified from a transformant unable to synthesize NrfE, NrfF and NrfG: this is consistent with our previous report that NrfE and NrfG (but not NrfF) are essential for formate-dependent nitrite reduction. Redox titrations clearly revealed the presence of high and low mid-point potential redox centres. The best fit to the experimental data is for three n=1 components with mid-point redox potentials (pH 7.0) of +45 mV (21% of the total absorbance change), -90 mV (36% of the total) and -210mV (43% of the total). Plasmids in which the lysine codon of the cysteine-lysine motif, AAA, was changed to the histidine codon CAT (to create a fifth 'typical' haem c-binding motif), or to the isoleucine and leucine codons, ATT and CTT, were unable to transform a Nrf deletion mutant to Nrf+ or to restore formate-dependent nitrite reduction to the transformants. The presence of a 50 kDa periplasmic c-type cytochrome was confirmed by staining proteins separated by SDS-PAGE for covalently bound haem, but the methyl-viologen-dependent nitrite reductase activities associated with the mutated proteins, although still detectable, were far lower than that of the native protein. The combined data establish not only that there is a haem group bound covalently to the cysteine-lysine motif of cytochrome c552 but also that one or more products of the last three genes of the nrf operon are essential for the haem ligation to this motif.

The product of the molybdenum cofactor gene mobB of Escherichia coli is a GTP-binding protein.

The mob mutants of Escherichia coli are pleiotropically defective in molybdoenzyme activities because they are unable to catalyse the conversion of molybdopterin guanine dinucleotide, the active form of the molybdenum cofactor. The mob locus comprises two genes. The product of mobA, protein FA, has previously been purified to homogeneity and is able to restore molybdoenzyme activities following incubation with cell extracts of mob strains. The mobB gene, although not essential for the biosynthesis of active molybdoenzymes, encodes a protein which, sequence analysis strongly suggests, contains a nucleotide-binding site. We have overproduced the products of both the mobA and mobB genes in engineered E. coli strains and purified each to homogeneity. The preparation of protein FA (MobA) is simpler than that previously published and produces a much greater yield of active protein. The isolated MobB protein, which is dimeric in solution, acts in the presence of protein FA, to enhance the level of nitrate reductase activation achieved on incubation with mob cell extracts. Equilibrium dialysis experiments show that purified MobB binds 0.83 mol GTP/mol protein with a Kd of 2.0 microM. Isolated MobB also catalyses a low GTPase activity (turnover number of 3 x 10(-3) min-1) with a K(m) for GTP to GDP of 7.5 microM. Under the conditions tested, protein FA did not affect the GTP-binding or GTPase activity of MobB. Intrinsic (tryptophan) protein fluorescence measurements show that MobB also binds the nucleotides ATP, TTP and GDP, but with lower affinity than GTP. These results are consistent with a model whereby MobB binds the guanine nucleotide which is attached to molybdopterin during the biosynthesis of the molybdenum cofactor.

Involvement of the narJ and mob gene products in distinct steps in the biosynthesis of the molybdoenzyme nitrate reductase in Escherichia coli.

The Escherichia coli mob locus is required for synthesis of active molybdenum cofactor, molybdopterin guanine dinucleotide. The mobB gene is not essential for molybdenum cofactor biosynthesis because a deletion of both mob genes can be fully complemented by just mobA. Inactive nitrate reductase, purified from a mob strain, can be activated in vitro by incubation with protein FA (the mobA gene product), GTP, MgCl2, and a further protein fraction, factor X. Factor X activity is present in strains that lack MobB, indicating that it is not an essential component of factor X, but over-expression of MobB increases the level of factor X. MobB, therefore, can participate in nitrate reductase activation. The narJ protein is not a component of mature nitrate reductase but narJ mutants cannot express active nitrate reductase A. Extracts from narJ strains are unable to support the in vitro activation of purified mob nitrate reductase: they lack factor X activity. Although the mob gene products are necessary for the biosynthesis of all E. coli molybdoenzymes as a result of their requirement for molybdopterin guanine dinucleotide, NarJ action is specific for nitrate reductase A. The inactive nitrate reductase A derivative in a narJ strain can be activated in vitro following incubation with cell extracts containing the narJ protein. NarJ acts to activate nitrate reductase after molybdenum cofactor biosynthesis is complete.

Surface characteristics of Pseudomonas cepacia.

Two major surface characteristics of Pseudomonas cepacia were examined in this study: reactivity with lectins and hydrophobicity. The results indicated that the surfaces of P. cepacia strains are heterogeneous with regard to the distribution of lectin receptors. Only lima bean agglutinin was found to strongly agglutinate all strains. The strains were also heterogeneous with regard to hydrophobicity as determined by adhesion to hexadecane. The degree of hydrophobicity, however, was not significantly altered when selected strains were mixed with either fibronectin or bovine serum albumin. In addition, the strains exhibited no apparent affinities for buccal epithelial cells and gave no evidence for an ability to haemagglutinate human red cells.