Induction of the ferritin gene (ftnA) of Escherichia coli by Fe(2+)-Fur is mediated by reversal of H-NS silencing and is RyhB independent.

FtnA is the major iron-storage protein of Escherichia coli accounting for < or = 50% of total cellular iron. The FtnA gene (ftnA) is induced by iron in an Fe(2+)-Fur-dependent fashion. This effect is reportedly mediated by RyhB, the Fe(2+)-Fur-repressed, small, regulatory RNA. However, results presented here show that ftnA iron induction is independent of RyhB and instead involves direct interaction of Fe(2+)-Fur with an 'extended' Fur binding site (containing five tandem Fur boxes) located upstream (-83) of the ftnA promoter. In addition, H-NS acts as a direct repressor of ftnA transcription by binding at multiple sites (I-VI) within, and upstream of, the ftnA promoter. Fur directly competes with H-NS binding at upstream sites (II-IV) and consequently displaces H-NS from the ftnA promoter (sites V-VI) which in turn leads to derepression of ftnA transcription. It is proposed that H-NS binding within the ftnA promoter is facilitated by H-NS occupation of the upstream sites through H-NS oligomerization-induced DNA looping. Consequently, Fur displacement of H-NS from the upstream sites prevents cooperative H-NS binding at the downstream sites within the promoter, thus allowing access to RNA polymerase. This direct activation of ftnA transcription by Fe(2+)-Fur through H-NS antisilencing represents a new mechanism for iron-induced gene expression.

Switching aconitase B between catalytic and regulatory modes involves iron-dependent dimer formation.

In addition to being the major citric acid cycle aconitase in Escherichia coli the aconitase B protein (AcnB) is also a post-transcriptional regulator of gene expression. The AcnB proteins represent a distinct branch of the aconitase superfamily that possess a HEAT-like domain (domain 5). The HEAT domains of other proteins are implicated in protein:protein interactions. Gel filtration analysis has now shown that cell-free extracts contain high-molecular-weight species of AcnB. Furthermore, in vitro and in vivo protein interaction experiments have shown that AcnB forms homodimers. Addition of the iron chelator bipyridyl to cultures inhibited the dimer-dependent readout from an AcnB bacterial two-hybrid system. A similar response was observed with a catalytically inactive AcnB variant, AcnB(C769S), suggesting that the monomer-dimer transition is not mediated by the state of the AcnB iron-sulphur cluster. The iron-responsive interacting unit was accordingly traced to the N-terminal region (domains 4 and 5) of the AcnB protein, and not to domain 3 that houses the iron-sulphur cluster. Thus, it was shown that a polypeptide containing AcnB N-terminal domains 5 and 4 (AcnB5-4) interacts with a second AcnB5-4 to form a homodimer. AcnB has recently been shown to initiate a regulatory cascade controlling flagella biosynthesis in Salmonella enterica by binding to the ftsH transcript and inhibiting the synthesis of the FtsH protease. A plasmid encoding AcnB5-4 complemented the flagella-deficient phenotype of a S. enterica acnB mutant, and the isolated AcnB5-4 polypeptide specifically recognized and bound to the ftsH transcript. Thus, the N-terminal region of AcnB is necessary and sufficient for promoting the formation of AcnB dimers and also for AcnB binding to target mRNA. Furthermore, the relative effects of iron on these processes provide a simple iron-mediated dimerization mechanism for switching the AcnB protein between catalytic and regulatory roles.

Transcription and transcript processing in the sdhCDAB-sucABCD operon of Escherichia coli.

The genes encoding succinate dehydrogenase (sdhCDAB), the specific components of the 2-oxoglutarate dehydrogenase complex (ODH, E1o and E2o; sucAB) and succinyl-CoA synthetase (sucCD) form a cluster containing two promoters at 16.3 min in the chromosome of Escherichia coli: Psdh sdhCDAB-Psuc sucAB-sucCD. The gene encoding the lipoamide dehydrogenase component of both the 2-oxoglutarate and pyruvate dehydrogenase complexes (E3; lpdA) is the distal gene of another cluster containing two promoters located at 2.7 min: Ppdh pdhR-aceEF-Plpd lpdA. The responses of the suc and lpd promoters to different environmental conditions and to regulator defects were investigated with appropriate lacZ fusions, in order to understand how expression of the sucAB genes is co-regulated with other genes in the sdhCDAB-sucABCD cluster and with lpdA expression. Expression from the suc promoter was repressed by IHF and partially activated by sigma 38 but it was not regulated by ArcA, FNR, CRP, FruR or Fis, and not repressed by glucose or anaerobiosis, indicating that the well-established catabolite and anaerobic repression of ODH synthesis is imposed elsewhere. In contrast, the lpd promoter was repressed by both glucose (via a CRP-independent mechanism) and anaerobiosis (mediated by ArcA), and activated by Fis, but it was not regulated by FNR, FruR, IHF or sigma 38. These observations support the view that transcription of the sucABCD genes is primarily initiated and regulated at the upstream sdh promoter, and that the lpd promoter is independently co-regulated with Psdh (primarily by ArcA-mediated repression) rather than with Psuc. Direct evidence for co-transcription of the entire sdhCDAB-sucABCD region from Psdh was obtained by detecting a 10 kb transcript in rnc and rne mutants, but not in the parental strains. Three RNaseIII-specific processing sites, which contribute to the extreme instability of the readthrough transcript, were identified in the sdhCDAB-sucABCD intergenic region. Other sites of endonuclease processing were located by interpreting the patterns of transcript subfragments observed in Northern blotting.

Direct evidence for mRNA binding and post-transcriptional regulation by Escherichia coli aconitases.

Escherichia coli contains a stationary-phase aconitase (AcnA) that is induced by iron and oxidative stress, and a major but less stable aconitase (AcnB) synthesized during exponential growth. These enzymes were shown to resemble the bifunctional iron-regulatory proteins (IRP1)/cytoplasmic aconitases of vertebrates in having alternative mRNA-binding and catalytic activities. Affinity chromatography and gel retardation analysis showed that the AcnA and AcnB apo-proteins each interact with the 3' untranslated regions (3'UTRs) of acnA and acnB mRNA at physiologically significant protein concentrations. AcnA and AcnB synthesis was enhanced in vitro by the apoaconitases and this enhancement was abolished by 3'UTR deletion from the DNA templates, presumably by loss of acn-mRNA stabilization by bound apoaconitase. In vivo studies showed that although total aconitase activity is lowered during oxidative stress, synthesis of the AcnA and AcnB proteins and the stabilities of acnA and acnB mRNAs both increase, suggesting that inactive aconitase mediates a post-transcriptional positive autoregulatory switch. Evidence for an iron-sulphur-cluster-dependent switch was inferred from the more than threefold higher mRNA-binding affinities of the apo-aconitases relative to the holo-enzymes. Thus by modulating translation via site-specific interactions between apo-enzyme and relevant transcripts, the aconitases provide a new and rapidly reacting component of the bacterial oxidative stress response.

Transcriptional regulation of the aconitase genes (acnA and acnB) of Escherichia coli.

Escherichia coli contains two differentially regulated aconitase genes, acnA and acnB. Two acnA promoters transcribing from start points located 407 bp (P1acnA) and 50 bp (P2acnA) upstream of the acnA coding region, and one acnB promoter (PacnB) with a start point 95 bp upstream of the acnB coding region, were identified by primer extension analysis. A 2.8 kb acnA monocistronic transcript was detected by Northern blot hybridization, but only in redox-stressed (methyl-viologen-treated) cultures, and a 2.5 kb acnB monocistronic transcript was detected in exponential- but not stationary-phase cultures. These findings are consistent with previous observations that acnA is specifically subject to SoxRS-mediated activation, whereas acnB encodes the major aconitase that is synthesized earlier in the growth cycle than AcnA. Further studies with acn-lacZ gene fusions and a wider range of transcription regulators indicated that acnA expression is initiated by sigma 38 from P1acnA, and from P2acnA it is activated directly or indirectly by CRP, FruR, Fur and SoxRS, and repressed by ArcA and FNR. In contrast, acnB expression is activated by CRP and repressed by ArcA, FruR and Fis from PacnB. Comparable studies with fum-lacZ fusions indicated that transcription of fumC, but not of fumA or fumB, is initiated by RNA polymerase containing sigma 38. It is concluded that AcnB is the major citric acid cycle enzyme, whereas AcnA is an aerobic stationary-phase enzyme that is specifically induced by iron and redox-stress.

FNR-dependent repression of ndh gene expression requires two upstream FNR-binding sites.

The ndh gene of Escherichia coli encodes a non-proton-translocating NADH dehydrogenase (NdhII) that is anaerobically repressed by the global transcription regulator, FNR. FNR binds at two sites (centred at -50.5 and -94.5) in the ndh promoter but the mechanism of FNR-mediated repression appears not to be due to promoter occlusion. This mechanism has been investigated using an aerobically active derivative of FNR, FNR* (FNR-D154A), with ndh promoters containing altered FNR-binding sites. FNR* repressed ndh gene expression both aerobically and anaerobically in vivo. Gel retardation analysis and DNase I footprinting with purified FNR* protein confirmed that FNR interacts at two sites in the ndh promoter, and that FNR and RNA polymerase (RNAP) can bind simultaneously. Studies with three altered ndh promoters, each containing an impaired or improved FNR-site, indicated that both FNR-sites are needed for efficient repression in vivo. The alpha-subunit of RNAP interacted with two regions (centred at -105 and -46), each overlapping one of the FNR-sites in the ndh promoter. Footprints of the FNR*-RNAP-ndh ternary complex indicated that FNR*-binding at -50.5 prevents the alpha-subunit of RNAP from docking with the DNA just upstream of the -35 element. Binding of a second FNR* molecule at the -105 site likewise prevents binding of the alpha-subunit at its alternative site, thus providing a plausible mechanism for FNR-mediated repression based on displacement of the alpha-subunit of RNAP.

Construction and properties of aconitase mutants of Escherichia coli.

Escherichia coli contains two genes (acnA and acnB) encoding aconitase activities. An acnB mutant was engineered by replacing the chromosomal acnB gene by an internally deleted derivative containing a tetR cassette. An acnB double mutant was then made by transducing a previously constructed acnA::kanR mutation into the acnB::tetR strain. Western blotting confirmed that the AcnA and AcnB proteins were no longer produced by the corresponding mutants and PCR analysis showed that the chromosomal acnB gene had been replaced by the disrupted gene. Aerobic and anaerobic growth in glucose minimal medium were impaired but not abolished by the acnB mutation, indicating that the lesion is partially complemented by the acnA+ gene, and growth was enhanced by glutamate. The acnAB double mutant would not grow on unsupplemented glucose minimal medium and although it responded to glutamate like a typical auxotroph under anaerobic conditions, under aerobic conditions no response to glutamate was observed before it was over-grown by 'revertants' lacking citrate synthase (acnAB gltA). The acnAB double mutant retained a low but significant aconitase activity (< or = 5% of wild-type), designated AcnC. Enzymological and regulatory studies with acn-lacZ fusions indicated that AcnB is the major aconitase, which is synthesized earlier in the growth cycle than AcnA, and subject to catabolite and anaerobic repression.

Regulation of the ndh gene of Escherichia coli by integration host factor and a novel regulator, Arr.

The ndh gene of Escherichia coli encodes the non-proton-translocating NADH dehydrogenase II. Expression of the ndh gene is subject to a complex network of regulatory controls at the transcriptional level. Under anaerobic conditions ndh is repressed by the regulator of fumarate and nitrate reduction (FNR). However, in the absence of FNR, ndh expression is activated by the amino acid response regulator (Arr) during anaerobic growth in rich medium. Expression of the ndh gene varies during the growth cycle in response to the intracellular concentration of the heat-stable DNA-binding protein, Fis. In this work two additional heat-stable proteins, integration host factor (IHF) and the histone-like protein HU were found to interact with the ndh promoter. IHF was shown to bind at three sites centred at +26, -17 and -58 in the ndh promoter (Kd = 10(-8) M), to prevent open-complex formation and to repress ndh transcription in vitro. Studies with an ndh-lacZ fusion confirmed that IHF represses ndh expression in vivo. Two putative binding sites for Arr, which overlap the two FNR boxes in the ndh promoter, were identified. Studies with the FNR-activated and amino-acid-inducible asparaginase II gene (ansB) showed that IHF and a component of the Arr-containing fraction (but not HU) interact with the corresponding ansB promoter.

AcnC of Escherichia coli is a 2-methylcitrate dehydratase (PrpD) that can use citrate and isocitrate as substrates.

Escherichia coli possesses two well-characterized aconitases (AcnA and AcnB) and a minor activity (designated AcnC) that is retained by acnAB double mutants and represents no more than 5% of total wild-type aconitase activity. Here it is shown that a 2-methylcitrate dehydratase (PrpD) encoded by the prpD gene of the propionate catabolic operon (prpRBCDE) is identical to AcnC. Inactivation of prpD abolished the residual aconitase activity of an AcnAB-null strain, whereas inactivation of ybhJ, an unidentified acnA paralogue, had no significant effect on AcnC activity. Purified PrpD catalysed the dehydration of citrate and isocitrate but was most active with 2-methylcitrate. PrpD also catalysed the dehydration of several other hydroxy acids but failed to hydrate cis-aconitate and related substrates containing double bonds, indicating that PrpD is not a typical aconitase but a dehydratase. Purified PrpD was shown to be a monomeric iron-sulphur protein (M(r) 54000) having one unstable [2Fe-2S] cluster per monomer, which is needed for maximum catalytic activity and can be reconstituted by treatment with Fe(2+) under reducing conditions.

Metabolic engineering in Escherichia coli: lowering the lipoyl domain content of the pyruvate dehydrogenase complex adversely affects the growth rate and yield.

Isogenic strains of Escherichia coli W3110 containing pyruvate dehydrogenase complexes with three (wild-type), two or one lipoyl domains per lipoate acetyltransferase (E2p) chain, were constructed. The maximum growth rates (mumax) for batch cultures growing in minimal medium containing different carbon sources showed that reducing the number of lipoyl domains adversely mumax value of the mutant containing one lipoyl domain per E2p chain was restored by the presence of compatible multicopy plasmids encoding PDH complexes with either one or three lipoyl domains per E2p chain. In glucose-limited chemostat cultures the protein contents of all strains were similar and substrate carbon was totally accounted for in the biomass and CO2 produced. However, the carbon efficiencies (percentage carbon conversion to biomass) were significantly lower when the lipoyl domain content of the E2p subunit was reduced from three to one. Similarly, the cellular maintenance energy (m(e)) and the maximum growth yield (Ymax) were lower in bacteria containing PDH complexes with fewer than three lipoyl domains per E2p chain. Wild-type values were restored by supplementing the medium with either casamino acids (0.01%) or acetate (up to 0.1 mM). The lower growth efficiencies of the mutants were further confirmed in competition experiments where equal numbers of genetically marked (NalR) mutant and wild-type bacteria were used to inoculate glucose-limited chemostat cultures (dilution rate 0.075 h-1). The mutants with one or two lipoyl domains per E2p chain were washed out, whereas in controls, the initial ratio of wild-type (Nals) to reconstructed wild-type (NalR) bacteria was maintained over 50 generations.

YeiL, the third member of the CRP-FNR family in Escherichia coli.

The yeiL open reading frame located at 48.5 min (2254 kb) in the nfo-fruA region of the Escherichia coli chromosome was predicted to encode a CRP and FNR paralogue capable of forming inter- or intra-molecular disulphide bonds and incorporating one iron-sulphur centre per 25 kDa subunit. Purified MBP-YeiL (a maltose-binding-protein-YeiL fusion protein) was a high-molecular-mass oligomer or aggregate which released unstable monomers (68 kDa) under reducing conditions. The MBP-YeiL protein contained substoichiometric amounts of iron and acid-labile sulphide, and an average of one disulphide bond per monomer. The iron and sulphide contents increased consistent with the acquisition of one [4Fe-4S] cluster per monomer after anaerobic NifS-catalysed reconstitution. By analogy with FNR and FLP (the FNR-like protein of Lactobacillus casei) it was suggested that the transcription-regulatory activity of YeiL might be modulated by a sensory iron-sulphur cluster and/or by reversible disulphide bond formation. A yeiL-lacZ transcriptional fusion showed that aerobic yeiL expression increases at least sixfold during stationary phase, requires RpoS, and is positively autoregulated by YeiL, positively activated by Lrp (and IHF in the absence of FNR) and negatively regulated by FNR. A regulatory link between the synthesis of YeiK (a potential nucleoside hydrolase) and YeiL was inferred by showing that the yeiK and yeiL genes are divergently transcribed from overlapping promoters. A 10-15% deficiency in aerobic growth yield and an enhanced loss of viability under nitrogen starvation conditions were detected with a yeiL::kan(R) mutant, suggesting that YeiL might function as a post-exponential-phase nitrogen-starvation regulator.

A novel regulatory switch mediated by the FNR-like protein of Lactobacillus casei.

FNR (regulator for fumarate and nitrate reduction) and CRP (cAMP receptor protein) are global regulators which regulate the transcription of overlapping modulons of target genes in response to anaerobiosis and carbon source in Escherichia coli. An ORF, designated flp because it encodes an FNR-like protein of the FNR-CRP family, has been found in Lactobacillus casei. The product of the flp coding region (FLP) was overproduced in E. coli, purified and crystallized. FLP is a homodimeric protein in which each subunit can form an intramolecular disulphide bond. The isolated protein also contains non-stoichiometric amounts of Cu and Zn. Although the DNA recognition helix of FLP resembles that of FNR, the flp gene failed to complement the anaerobic respiratory deficiency of an fnr mutant when expressed in E. coli and it neither activated nor interfered with transcription from FNR- or CRP-dependent promoters in E. coli. Site-specific DNA binding by oxidized FLP (the form containing intrasubunit disulphide bonds) was abolished by reduction. The interconversion between disulphide and dithiol forms thus provides the basis for a novel redox-mediated transcriptional switch. Two non-identical FLP-binding sites, distinct from FNR- and CRP-binding sites, were identified in the meIR region of E. coli by gel-retardation analysis. A further eight FLP-binding sites were selected from a random library. A synthetic oligonucleotide conforming to a putative FLP site consensus, CA/CTGA-N4-TCAG/TG (the most significant bases are underlined), was retarded by FLP. Functional tests showed that FLP represses the aerobic transcription of a semi-synthetic promoter in E. coli. A C5S variant of FLP lacking the ability to form intramolecular disulphide bonds was unable to bind to FLP sites and failed to repress transcription in vivo.

Post-transcriptional regulation of bacterial motility by aconitase proteins.

Escherichia coli and Bacillus subtilis aconitases can act as iron and oxidative stress-responsive post-transcriptional regulators. Here, it is shown that a Salmonella enterica serovar Typhimurium LT2 acnB mutant exhibits impaired binding to the surface of J774 macrophage-like cells. Proteomic analyses were used to investigate further the binding defect of the acnB mutant. These revealed that the levels of the flagellum protein FliC were much lower for the acnB mutant. This strain was correspondingly less motile and possessed fewer flagella than either the parental strain or the acnA and acnAB mutants. The acnB lesion did not alter fliC transcription, nor did apo-AcnB select the fliC transcript from a library of S. enterica transcripts; thus, the effect of AcnB on FliC is indirect. Evidence is presented to show that apo-AcnB regulates FliC synthesis via interaction with the ftsH transcript to decrease the intracellular levels of FtsH. The lower levels of FtsH protease activity then influence sigma32, DnaK and, ultimately, FliC production.

Escherichia coli aconitases and oxidative stress: post-transcriptional regulation of sodA expression.

Escherichia coli possesses two aconitases, a stationary-phase enzyme (AcnA), which is induced by iron and oxidative stress, and a major but less stable enzyme (AcnB), synthesized during exponential growth. In addition to the catalytic activities of the holo-proteins, the apo-proteins function as post-transcriptional regulators by site-specific binding to acn mRNAs. Thus, it has been suggested that inactivation of the enzymes could mediate a rapidly reacting post-transcriptional component of the bacterial oxidative stress response. Here it is shown that E. coli acn mutants are hypersensitive to the redox-stress reagents H(2)O(2) and methyl viologen. Proteomic analyses further revealed that the level of superoxide dismutase (SodA) is enhanced in acnB and acnAB mutants, and by exposure to methyl viologen. The amounts of other proteins, including thioredoxin reductase, 2-oxoglutarate dehydrogenase, succinyl-CoA synthetase and chaperone proteins, were also affected in the acn mutants. The altered patterns of sodA expression were confirmed in studies with sodA-lacZ reporter strains. Quantitative Northern blotting indicated that AcnA enhances the stability of the sodA transcript, whereas AcnB lowers its stability. Direct evidence that the apo-proteins have positive (AcnA) and negative (AcnB) effects on SodA synthesis was obtained from in vitro transcription-translation experiments. It is suggested that the aconitase proteins of E. coli serve as a protective buffer against the basal level of oxidative stress that accompanies aerobic growth by acting as a sink for reactive oxygen species and by modulating translation of the sodA transcript.

The second aconitase (AcnB) of Escherichia coli.

The second aconitase (AcnB) of Escherichia coli was partially purified from an acnA::kanR mutant lacking AcnA, and the corresponding polypeptide identified by activity staining and weak cross-reactivity with AcnA antiserum. The acnB gene was located at 2 center dot 85 min (131 center dot 6 kb) in a region of the chromosome previously assigned to two unidentified ORFs. Aconitase specific activities were amplified up to fivefold by infection with lambdaacnB phages from the Kohara lambda-E. coli gene library, and up to 120-fold (50% of soluble protein) by inducing transformants containing a plasmid (pGS783) in which the acnB coding region is expressed from a regulated T7 promoter. The AcnB protein was purified to > or = 98% homogeneity from a genetically enriched source (JRG3171) and shown to be a monomeric protein of Mr 100 000 (SDS-PAGE) and 105 000 (gel filtration analysis) compared with Mr 93 500 predicted from the nucleotide sequence. The sequence identity between AcnA and AcnB is only 17% and the domain organization of AcnA and related proteins (1-2-3-linker-4) is rearranged in AcnB (4-1-2-3).

Pyruvate oxidase contributes to the aerobic growth efficiency of Escherichia coli.

The metabolic importance of pyruvate oxidase (PoxB), which converts pyruvate directly to acetate and CO(2), was assessed using an isogenic set of genetically engineered strains of Escherichia coli. In a strain lacking the pyruvate dehydrogenase complex (PDHC), PoxB supported acetate-independent aerobic growth when the poxB gene was expressed constitutively or from the IPTG-inducible tac promoter. Using aerobic glucose-limited chemostat cultures of PDH-null strains, it was found that steady-states could be maintained at a low dilution rate (0.05 h(-1)) when PoxB is expressed from its natural promoter, but not at higher dilution rates (up to at least 0.25 h(-1)) unless expressed constitutively or from the tac promoter. The poor complementation of PDH-deficient strains by poxB plasmids was attributed to several factors including the stationary-phase-dependent regulation of the natural poxB promoter and deleterious effects of the multicopy plasmids. As a consequence of replacing the PDH complex by PoxB, the growth rate (mu(max)), growth yield (Y(max)) and the carbon conversion efficiency (flux to biomass) were lowered by 33%, 9-25% and 29-39% (respectively), indicating that more carbon has to be oxidized to CO(2) for energy generation. Extra energy is needed to convert PoxB-derived acetate to acetyl-CoA for further metabolism and enzyme analysis indicated that acetyl-CoA synthetase is induced for this purpose. In similar experiments with a PoxB-null strain it was shown that PoxB normally makes a significant contribution to the aerobic growth efficiency of E. coli. In glucose minimal medium, the respective growth rates (mu(max)), growth yields (Y(max)) and carbon conversion efficiencies were 16%, 14% and 24% lower than the parental values, and correspondingly more carbon was fluxed to CO(2) for energy generation. It was concluded that PoxB is used preferentially at low growth rates and that E. coli benefits from being able to convert pyruvate to acetyl-CoA by a seemingly wasteful route via acetate.

A 12-cistron Escherichia coli operon (hyf) encoding a putative proton-translocating formate hydrogenlyase system.

The nucleotide sequence has been determined for a twelve-gene operon of Escherichia coli designated the hyf operon (hyfABCDEFGHIR-focB). The hyf operon is located at 55.8-56.0 min and encodes a putative nine-subunit hydrogenase complex (hydrogenase four or Hyf), a potential formate- and sigma 54-dependent transcriptional activator, HyfR (related to FhlA), and a possible formate transporter, FocB (related to FocA). Five of the nine Hyf-complex subunits are related to subunits of both the E. coli hydrogenase-3 complex (Hyc) and the proton-translocating NADH:quinone oxidoreductases (complex I and Nuo), whereas two Hyf subunits are related solely to NADH:quinone oxidoreductase subunits. The Hyf components include a predicted 523 residue [Ni-Fe] hydrogenase (large subunit) with an N-terminus (residues 1-170) homologous to the 30 kDa or NuoC subunit of complex I. It is proposed that Hyf, in conjunction with formate dehydrogenase H (Fdh-H), forms a hitherto unrecognized respiration-linked proton-translocating formate hydrogenlyase (FHL-2). It is likely that HyfR acts as a formate-dependent regulator of the hyf operon and that FocB provides the Hyf complex with external formate as substrate.

Enzymological and physiological consequences of restructuring the lipoyl domain content of the pyruvate dehydrogenase complex of Escherichia coli.

The core-forming lipoate acetyltransferase (E2p) subunits of the pyruvate dehydrogenase (PDH) complex of Escherichia coli contain three tandemly repeated lipoyl domains although one lipoyl domain is apparently sufficient for full catalytic activity in vitro. Plasmids containing IPTG-inducible aceEF-IpdA operons which express multilip-PDH complexes bearing one N-terminal lipoyl domain and up to seven unlipoylated (mutant) domains per E2p chain, were constructed. Each plasmid restored the nutritional lesion of a strain lacking the PDH complex and expressed a sedimentable PDH complex, although the catalytic activities declined significantly as the number of unlipoylated domains increased above four per E2p chain. It was concluded that the extra domains protrude from the 24-meric E2p core without affecting assembly of the E1p and E3 subunits, and that the lipoyl cofactor bound to the outermost domain can participate successfully at each of the three types of active site in the assembled complex. Physiological studies with two series of isogenic strains expressing multilip-PDH complexes from modified chromosomal pdh operons (pdhR-aceEF-IpdA) showed that three lipoyl domains per E2p chain is optimal and that only the outermost domain need be lipoylated for optimal activity. It is concluded that the reason for retaining three lipoyl domains is to extend the reach of the outermost lipoyl cofactor rather than to provide extra cofactors for catalysis.

Structure of the pyruvate dehydrogenase multienzyme complex E1 component from Escherichia coli at 1.85 A resolution.

The crystal structure of the recombinant thiamin diphosphate-dependent E1 component from the Escherichia coli pyruvate dehydrogenase multienzyme complex (PDHc) has been determined at a resolution of 1.85 A. The E. coli PDHc E1 component E1p is a homodimeric enzyme and crystallizes with an intact dimer in an asymmetric unit. Each E1p subunit consists of three domains: N-terminal, middle, and C-terminal, with all having alpha/beta folds. The functional dimer contains two catalytic centers located at the interface between subunits. The ThDP cofactors are bound in the "V" conformation in clefts between the two subunits (binding involves the N-terminal and middle domains), and there is a common ThDP binding fold. The cofactors are completely buried, as only the C2 atoms are accessible from solution through the active site clefts. Significant structural differences are observed between individual domains of E1p relative to heterotetrameric multienzyme complex E1 components operating on branched chain substrates. These differences may be responsible for reported alternative E1p binding modes to E2 components within the respective complexes. This paper represents the first structural example of a functional pyruvate dehydrogenase E1p component from any species. It also provides the first representative example for the entire family of homodimeric (alpha2) E1 multienzyme complex components, and should serve as a model for this class of enzymes.

E. coli aconitase B structure reveals a HEAT-like domain with implications for protein-protein recognition.

The major bifunctional aconitase of Escherichia coli (AcnB) serves as either an enzymic catalyst or a mRNA-binding post-transcriptional regulator, depending on the status of its iron sulfur cluster. AcnB represents a large, distinct group of Gram-negative bacterial aconitases that have an altered domain organization relative to mitochondrial aconitase and other aconitases. Here the 2.4 A structure of E. coli AcnB reveals a high degree of conservation at the active site despite its domain reorganization. It also reveals that the additional domain, characteristic of the AcnB subfamily, is a HEAT-like domain, implying a role in protein protein recognition. This domain packs against the remainder of the protein to form a tunnel leading to the aconitase active site, potentially for substrate channeling.