On the operon structure of the cfx gene clusters in Alcaligenes eutrophus

The energy metabolism of Cupriavidus necator in different trophic conditions

The "knallgas" bacterium Cupriavidus necator is attracting interest due to its extremely versatile metabolism. C. necator can use hydrogen or formic acid as an energy source, fixes CO2 via the Calvin-Benson-Bassham (CBB) cycle, and grows on organic acids and sugars. Its tripartite genome is notable for its size and duplications of key genes (CBB cycle, hydrogenases, and nitrate reductases). Little is known about which of these isoenzymes and their cofactors are actually utilized for growth on different substrates. Here, we investigated the energy metabolism of C. necator H16 by growing a barcoded transposon knockout library on succinate, fructose, hydrogen (H2/CO2), and formic acid. The fitness contribution of each gene was determined from enrichment or depletion of the corresponding mutants. Fitness analysis revealed that (i) some, but not all, molybdenum cofactor biosynthesis genes were essential for growth on formate and nitrate respiration. (ii) Soluble formate dehydrogenase (FDH) was the dominant enzyme for formate oxidation, not membrane-bound FDH. (iii) For hydrogenases, both soluble and membrane-bound enzymes were utilized for lithoautotrophic growth. (iv) Of the six terminal respiratory complexes in C. necator H16, only some are utilized, and utilization depends on the energy source. (v) Deletion of hydrogenase-related genes boosted heterotrophic growth, and we show that the relief from associated protein cost is responsible for this phenomenon. This study evaluates the contribution of each of C. necator's genes to fitness in biotechnologically relevant growth regimes. Our results illustrate the genomic redundancy of this generalist bacterium and inspire future engineering strategies.IMPORTANCEThe soil bacterium Cupriavidus necator can grow on gas mixtures of CO2, H2, and O2. It also consumes formic acid as carbon and energy source and various other substrates. This metabolic flexibility comes at a price, for example, a comparatively large genome (6.6 Mb) and a significant background expression of lowly utilized genes. In this study, we mutated every non-essential gene in C. necator using barcoded transposons in order to determine their effect on fitness. We grew the mutant library in various trophic conditions including hydrogen and formate as the sole energy source. Fitness analysis revealed which of the various energy-generating iso-enzymes are actually utilized in which condition. For example, only a few of the six terminal respiratory complexes are used, and utilization depends on the substrate. We also show that the protein cost for the various lowly utilized enzymes represents a significant growth disadvantage in specific conditions, offering a route to rational engineering of the genome. All fitness data are available in an interactive app at https://m-jahn.shinyapps.io/ShinyLib/.

RubisCO selection using the vigorously aerobic and metabolically versatile bacterium Ralstonia eutropha

Recapturing atmospheric CO2 is key to reducing global warming and increasing biological carbon availability. Ralstonia eutropha is a biotechnologically useful aerobic bacterium that uses the Calvin-Benson-Bassham (CBB) cycle and the enzyme ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) for CO2 utilization, suggesting that it may be a useful host to bioselect RubisCO molecules with improved CO2 -capture capabilities. A host strain of R. eutropha was constructed for this purpose after deleting endogenous genes encoding two related RubisCOs. This strain could be complemented for CO2 -dependent growth by introducing native or heterologous RubisCO genes. Mutagenesis and suppressor selection identified amino acid substitutions in a hydrophobic region that specifically influences RubisCO's interaction with its substrates, particularly O2 , which competes with CO2 at the active site. Unlike most RubisCOs, the R. eutropha enzyme has evolved to retain optimal CO2 -fixation rates in a fast-growing host, despite the presence of high levels of competing O2 . Yet its structure-function properties resemble those of several commonly found RubisCOs, including the higher plant enzymes, allowing strategies to engineer analogous enzymes. Because R. eutropha can be cultured rapidly under harsh environmental conditions (e.g., with toxic industrial flue gas), in the presence of near saturation levels of oxygen, artificial selection and directed evolution studies in this organism could potentially impact efforts toward improving RubisCO-dependent biological CO2 utilization in aerobic environments.

ENZYMES

d-ribulose 1,5-bisphosphate carboxylase/oxygenase, EC 4.1.1.39; phosphoribulokinase, EC 2.7.1.19.

Impact of the iron-sulfur cluster proximal to the active site on the catalytic function of an O2-tolerant NAD(+)-reducing [NiFe]-hydrogenase

The soluble NAD(+)-reducing hydrogenase (SH) from Ralstonia eutropha H16 belongs to the O2-tolerant subtype of pyridine nucleotide-dependent [NiFe]-hydrogenases. To identify molecular determinants for the O2 tolerance of this enzyme, we introduced single amino acids exchanges in the SH small hydrogenase subunit. The resulting mutant strains and proteins were investigated with respect to their physiological, biochemical, and spectroscopic properties. Replacement of the four invariant conserved cysteine residues, Cys41, Cys44, Cys113, and Cys179, led to unstable protein, strongly supporting their involvement in the coordination of the iron-sulfur cluster proximal to the catalytic [NiFe] center. The Cys41Ser exchange, however, resulted in an SH variant that displayed up to 10% of wild-type activity, suggesting that the coordinating role of Cys41 might be partly substituted by the nearby Cys39 residue, which is present only in O2-tolerant pyridine nucleotide-dependent [NiFe]-hydrogenases. Indeed, SH variants carrying glycine, alanine, or serine in place of Cys39 showed increased O2 sensitivity compared to that of the wild-type enzyme. Substitution of further amino acids typical for O2-tolerant SH representatives did not greatly affect the H2-oxidizing activity in the presence of O2. Remarkably, all mutant enzymes investigated by electron paramagnetic resonance spectroscopy did not reveal significant spectral changes in relation to wild-type SH, showing that the proximal iron-sulfur cluster does not contribute to the wild-type spectrum. Interestingly, exchange of Trp42 by serine resulted in a completely redox-inactive [NiFe] site, as revealed by infrared spectroscopy and H2/D(+) exchange experiments. The possible role of this residue in electron and/or proton transfer is discussed.

Phosphotransferase protein EIIANtr interacts with SpoT, a key enzyme of the stringent response, in Ralstonia eutropha H16

EIIA(Ntr) is a member of a truncated phosphotransferase (PTS) system that serves regulatory functions and exists in many Proteobacteria in addition to the sugar transport PTS. In Escherichia coli, EIIA(Ntr) regulates K(+) homeostasis through interaction with the K(+) transporter TrkA and sensor kinase KdpD. In the β-Proteobacterium Ralstonia eutropha H16, EIIA(Ntr) influences formation of the industrially important bioplastic poly(3-hydroxybutyrate) (PHB). PHB accumulation is controlled by the stringent response and induced under conditions of nitrogen deprivation. Knockout of EIIA(Ntr) increases the PHB content. In contrast, absence of enzyme I or HPr, which deliver phosphoryl groups to EIIA(Ntr), has the opposite effect. To clarify the role of EIIA(Ntr) in PHB formation, we screened for interacting proteins that co-purify with Strep-tagged EIIA(Ntr) from R. eutropha cells. This approach identified the bifunctional ppGpp synthase/hydrolase SpoT1, a key enzyme of the stringent response. Two-hybrid and far-Western analyses confirmed the interaction and indicated that only non-phosphorylated EIIA(Ntr) interacts with SpoT1. Interestingly, this interaction does not occur between the corresponding proteins of E. coli. Vice versa, interaction of EIIA(Ntr) with KdpD appears to be absent in R. eutropha, although R. eutropha EIIA(Ntr) can perfectly substitute its homologue in E. coli in regulation of KdpD activity. Thus, interaction with KdpD might be an evolutionary 'ancient' task of EIIA(Ntr) that was subsequently replaced by interaction with SpoT1 in R. eutropha. In conclusion, EIIA(Ntr) might integrate information about nutritional status, as reflected by its phosphorylation state, into the stringent response, thereby controlling cellular PHB content in R. eutropha.

Characterization of a second functional gene cluster for the catabolism of phenylacetic acid in Pseudomonas sp. strain Y2

Pseudomonas sp. strain Y2 is a styrene degrading bacterium that mineralises this compound through its oxidation to phenylacetic acid (PAA). We previously identified a complete gene cluster (paa1 cluster) for the degradation of phenylacetate, but, surprisingly, some paa1 deletion mutants were still able to catabolize styrene (STY) suggesting that this strain contained a second catabolic pathway. We report here the characterization of a second and novel paa2 gene cluster comprising 17 genes related to the catabolism of phenylacetate. We have identified a new gene (paaP) that is most likely involved in a transport process. Remarkably, the organization of the paa2 gene cluster is more similar to that of Pseudomonas putida KT2440 than to the paa1 gene cluster. Two new genes of undefined function were located inside the paa2 cluster. Sequence comparison between the paa2 genes and the paa1 and paa clusters of Pseudomonas sp. strain Y2 and P. putida KT2440, respectively, revealed a similar degree of divergence among the three sets of genes. Differences in the gene organization between paa1 and paa2 clusters of Pseudomonas sp. strain Y2 can be explained by an independent evolutionary history, probably associated with the adjacent sty genes. Deletion of either the first (paa1) or the second (paa2) gene cluster did not affect the ability of strain Y2 to grow in phenylacetate, whereas the deletion of both clusters led to the loss of this ability. The co-existence of two functional gene clusters for the degradation of phenylacetic acid in a bacterium has not been reported so far.

The transcription of the cbb operon in Nitrosomonas europaea

Nitrosomonas europaeais an aerobic ammonia-oxidizing bacterium that participates in the C and N cycles.N. europaeautilizes CO2as its predominant carbon source, and is an obligate chemolithotroph, deriving all the reductant required for energy and biosynthesis from the oxidation of ammonia (NH3) to nitrite (). This bacterium fixes carbon via the Calvin–Benson–Bassham (CBB) cycle via a type I ribulose bisphosphate carboxylase/oxygenase (RubisCO). The RubisCO operon is composed of five genes,cbbLSQON. This gene organization is similar to that of the operon for ‘green-like’ type I RubisCOs in other organisms. ThecbbRgene encoding the putative regulatory protein for RubisCO transcription was identified upstream ofcbbL. This study showed that transcription ofcbbgenes was upregulated when the carbon source was limited, whileamo,haoand other energy-harvesting-related genes were downregulated.N. europaearesponds to carbon limitation by prioritizing resources towards key components for carbon assimilation. Unlike the situation foramogenes, NH3was not required for the transcription of thecbbgenes. All fivecbbgenes were only transcribed when an external energy source was provided. In actively growing cells, mRNAs from the five genes in the RubisCO operon were present at different levels, probably due to premature termination of transcription, rapid mRNA processing and mRNA degradation.

Carbonic anhydrase is essential for growth of Ralstonia eutropha at ambient CO(2) concentrations

Mutant strain 25-1 of the facultative chemoautotroph Ralstonia eutropha H16 had previously been shown to exhibit an obligately high-CO(2)-requiring (HCR) phenotype. Although the requirement varied with the carbon and energy sources utilized, none of these conditions allowed growth at the air concentration of CO(2). In the present study, a gene designated can and encoding a beta-carbonic anhydrase (CA) was identified as the site altered in strain 25-1. The mutation caused a replacement of the highly conserved glycine residue 98 by aspartate in Can. A can deletion introduced into wild-type strain H16 generated mutant HB1, which showed the same HCR phenotype as mutant 25-1. Overexpression of can in Escherichia coli and mass spectrometric determination of CA activity demonstrated that can encodes a functional CA. The enzyme is inhibited by ethoxyzolamide and requires 40 mM MgSO(4) for maximal activity. Low but significant CA activities were detected in wild-type H16 but not in mutant HB1, strongly suggesting that the CA activity of Can is essential for growth of the wild type in the presence of low CO(2) concentrations. The HCR phenotype of HB1 was overcome by complementation with heterologous CA genes, indicating that growth of the organism at low CO(2) concentrations requires sufficient CA activity rather than the specific function of Can. The metabolic function(s) depending on CA activity remains to be identified.

Two similar gene clusters coding for enzymes of a new type of aerobic 2-aminobenzoate (anthranilate) metabolism in the bacterium Azoarcus evansii

In the beta-proteobacterium Azoarcus evansii, the aerobic metabolism of 2-aminobenzoate (anthranilate), phenylacetate, and benzoate proceeds via three unprecedented pathways. The pathways have in common that all three substrates are initially activated to coenzyme A (CoA) thioesters and further processed in this form. The two initial steps of 2-aminobenzoate metabolism are catalyzed by a 2-aminobenzoate-CoA ligase forming 2-aminobenzoyl-CoA and by a 2-aminobenzoyl-CoA monooxygenase/reductase (ACMR) forming 2-amino-5-oxo-cyclohex-1-ene-1-carbonyl-CoA. Eight genes possibly involved in this pathway, including the genes encoding 2-aminobenzoate-CoA ligase and ACMR, were detected, cloned, and sequenced. The sequence of the ACMR gene showed that this enzyme is an 87-kDa fusion protein of two flavoproteins, a monooxygenase (similar to salicylate monooxygenase) and a reductase (similar to old yellow enzyme). Besides the genes for the initial two enzymes, genes for three enzymes of a beta-oxidation pathway were found. A substrate binding protein of an ABC transport system, a MarR-like regulator, and a putative translation inhibitor protein were also encoded by the gene cluster. The data suggest that, after monooxygenation/reduction of 2-aminobenzoyl-CoA, the nonaromatic CoA thioester intermediate is metabolized further by beta-oxidation. This implies that all subsequent intermediates are CoA thioesters and that the alicyclic carbon ring is not cleaved oxygenolytically. Surprisingly, the cluster of eight genes, which form an operon, is duplicated. The two copies differ only marginally within the coding regions but differ substantially in the respective intergenic regions. Both copies of the genes are coordinately expressed in cells grown aerobically on 2-aminobenzoate.

Mutational analysis of the cbb operon (CO2 assimilation) promoter of Ralstonia eutropha

PL promoters direct the transcription of the duplicated cbb operons from the facultative chemoautotroph Ralstonia eutropha H16. The operons encode most enzymes of the Calvin-Benson-Bassham carbon reduction cycle required for CO2 assimilation. Their transcription depends on the activator protein CbbR. Structure-function relationships in the cloned chromosomal promoter region were analyzed by site-directed mutagenesis. PL was altered in its presumed hexameric -35 and/or -10 box or in the spacer region between the boxes to achieve a greater or lesser resemblance to the structure of the sigma70 consensus promoter of Escherichia coli. PL::lacZ transcriptional fusions of various promoter variants were assayed in transconjugant strains of R. eutropha as well as in corresponding cbbR deletion mutants. Mutations increasing the similarity of the -35 and/or -10 box to the consensus sequence stimulated PL activity to various extents, whereas mutations deviating from the consensus decreased the activity. The length of the spacer region also proved to be critical. The conversion of the boxes, either individually or simultaneously, into the consensus sequences resulted in a highly active PL. All improved PL mutants, however, retained the activation under inducing or derepressing growth conditions, although the full-consensus promoter was nearly constitutive. They were also activated in the cbbR mutants. The activity of the overlapping, divergently oriented cbbR promoter was less affected by the mutations. The half- and full-consensus PL mutants were comparably active in E. coli. Two major conclusions were drawn from the results: (i) the location and function of PL were verified, and (ii) indirect evidence was obtained for the involvement of another regulator(s), besides CbbR, in the transcriptional control of the R. eutropha cbb operons.

Something from almost nothing: carbon dioxide fixation in chemoautotrophs

The last decade has seen significant advances in our understanding of the physiology, ecology, and molecular biology of chemoautotrophic bacteria. Many ecosystems are dependent on CO2 fixation by either free-living or symbiotic chemoautotrophs. CO2 fixation in the chemoautotroph occurs via the Calvin-Benson-Bassham cycle. The cycle is characterized by three unique enzymatic activities: ribulose bisphosphate carboxylase/oxygenase, phosphoribulokinase, and sedoheptulose bisphosphatase. Ribulose bisphosphate carboxylase/oxygenase is commonly found in the cytoplasm, but a number of bacteria package much of the enzyme into polyhedral organelles, the carboxysomes. The carboxysome genes are located adjacent to cbb genes, which are often, but not always, clustered in large operons. The availability of carbon and reduced substrates control the expression of cbb genes in concert with the LysR-type transcriptional regulator, CbbR. Additional regulatory proteins may also be involved. All of these, as well as related topics, are discussed in detail in this review.

Organization and regulation of cbb CO2 assimilation genes in autotrophic bacteria

The Calvin-Benson-Bassham cycle constitutes the principal route of CO2 assimilation in aerobic chemoautotrophic and in anaerobic phototrophic purple bacteria. Most of the enzymes of the cycle are found to be encoded by cbb genes. Despite some conservation of the internal gene arrangement cbb gene clusters of the various organisms differ in size and operon organization. The cbb operons of facultative autotrophs are more strictly regulated than those of obligate autotrophs. The major control is exerted by the cbbR gene, which codes for a transcriptional activator of the LysR family. This gene is typically located immediately upstream of and in divergent orientation to the regulated cbb operon, forming a control region for both transcriptional units. Recent studies suggest that additional protein factors are involved in the regulation. Although the metabolic signal(s) received by the regulatory components of the operons is (are) still unknown, the redox state of the cell is believed to play a key role. It is proposed that the control of the cbb operon expression is integrated into a regulatory network.

Regulation of CO2 assimilation in Ralstonia eutropha: premature transcription termination within the cbb operon

In the facultatively chemoautotrophic bacterium Ralstonia eutropha (formerly Alcaligenes eutrophus), most genes required for CO2 assimilation via the Calvin cycle are organized within two highly homologous cbb operons located on the chromosome and on megaplasmid pHG1, respectively, of strain H16. These operons are subject to tight control exerted by a promoter upstream of the 5'-terminal cbbL gene that is regulated by the activator CbbR. The existence of subpromoters within the operons was now excluded, as determined with lacZ operon fusions to suitable cbb gene fragments in the promoter-probe vector pBK. Nevertheless, marked differential expression of the promoter-proximal ribulose-1,5-bisphosphate carboxylase-oxygenase genes cbbLS and the remaining distal genes occurs within the operons. Computer analysis revealed a potential stem-loop structure immediately downstream of cbbS that was suspected to be involved in the differential gene expression. Nuclease S1 mapping identified a major 3' end and a minor 3' end of the relatively stable cbbLS partial transcript just downstream of this structure. Moreover, operon fusions containing progressively deleted stem-loop structures showed that the structure primarily caused transcriptional termination downstream of cbbS rather than increased the segmental stability of the cbbLS transcript. Premature transcription termination thus represents an important mechanism leading to differential gene expression within the cbb operons.

Operator binding of the CbbR protein, which activates the duplicate cbb CO2 assimilation operons of Alcaligenes eutrophus

The regulatory protein CbbR, which activates the transcription of the duplicate, chromosomally and megaplasmid pHG1-borne cbb CO2 assimilation operons of Alcaligenes eutrophus H16, was purified to homogeneity from Escherichia coli after heterologous expression of the cloned cbbR gene. The pure protein occurred as either a 63-kDa dimer at room temperature or a 125-kDa tetramer at 4 degrees C. CbbR bound to the 167-bp cbb control region separating the divergently oriented cbbR gene (defective copy on pHG1) from the cbb operon. DNase I footprinting revealed binding of the protein between position -29 and -74 relative to the transcriptional start point of the cbb operon, with a hypersensitive site at positions -47 and -48, suggesting potential DNA bending. Hydroxyl radical footprinting disclosed the same central binding region. The region was found to consist of two subsites to which the activator apparently bound in a cooperative manner. At higher CbbR concentrations, the binding region extended to position +13. The overlapping arrangement of the operon promoter and CbbR-binding region (operator) suggests an interaction between CbbR and RNA polymerase to cause transcription activation. Transcriptional fusions with fragments carrying 1- or 2-bp insertions within the central region showed no operon promoter activity, although CbbR binding was not prevented by these mutations. Dissection of the central region enabled the differentiation of two apparently independent binding subsites. Strongly increased cbbR promoter activity originating from a fragment that contained only a part of the central region indicated negative autoregulation of cbbR transcription.

Fructosebisphosphatase isoenzymes of the chemoautotroph Xanthobacter flavus

Xanthobacter flavus employs two fructosebisphosphatase (FBPase)-sedoheptulosebisphosphatase (SBPase) enzymes. One of these is constitutively expressed and has a high FBPase-to-SBPase ratio. The alternative enzyme, which is encoded by cbbF, is induced during autotrophic growth. The cbbF gene was expressed in Escherichia coli, and the FBPase was purified to homogeneity. The purified enzyme has a specific FBPase activity of 114 mumol/min/mg of protein, a Michaelis constant for fructosebisphosphate of 3 microM, and a low FBPase-to-SBPase ratio. CbbF was activated by ATP and inhibited by Ca2+.

Characterization of the duplicate ribulose-1,5-bisphosphate carboxylase genes and cbb promoters of Alcaligenes eutrophus

Autotrophic CO2 fixation via the Calvin carbon reduction cycle in Alcaligenes eutrophus H16 is genetically determined by two highly homologous cbb operons, one of which is located on the chromosome and the other on megaplasmid pHG1 of the organism. An activator gene, cbbR, lies in divergent orientation only 167 bp upstream of the chromosomal operon and controls the expression of both cbb operons. The two 5'-terminal genes of the operons, cbbLS, coding for ribulose-1,5-bisphosphate carboxylase/oxygenase, were sequenced. Mapping of the 5' termini of the 2.1-kb cbbLS transcripts by primer extension and by nuclease S1 treatment revealed a single transcriptional start point at the same relative position for the chromosomal and plasmid-borne cbb operons. The derived cbb operon promoter showed similarity to sigma 70-dependent promoters of Escherichia coli. For the 1.4-kb transcripts of cbbR, the transcriptional start points were different in autotrophic and heterotrophic cells. The two corresponding cbbR promoters overlapped the cbb operon promoter and also displayed similarities to sigma 70-dependent promoters. The deficient cbbR gene located on pHG1 was transcribed as well. A newly constructed double operon fusion vector was used to determine the activities of the cbb promoters. Fusions with fragments carrying the cbb intergenic control regions demonstrated that the cbb operon promoters were strongly regulated in response to autotrophic versus heterotrophic growth conditions. In contrast, the cbbR promoters displayed low constitutive activities. The data suggest that the chromosomal and plasmid-borne cbb promoters of A. eutrophus H16 are functionally equivalent despite minor structural differences.

Analysis of the cbbF genes from Alcaligenes eutrophus that encode fructose-1,6-/sedoheptulose-1,7-bisphosphatase

The cbbF genes of the facultative chemoautotroph Alcaligenes eutrophus H16 are part of two highly homologous cbb operons. Both the chromosomal and the megaplasmid pHG1-borne copy of cbbF were cloned and sequenced. Subsequent analyses including comparison with known sequences from other organisms and heterologous expression in Escherichia coli revealed that each of the genes encodes fructose-1,6-bisphosphatase (FBPase). A closely related activity likewise operating in the Calvin carbon reduction cycle, sedoheptulose-1,7-bisphosphatase, was also catalyzed by the two isoenzymes which were purified from autotrophically grown cells of A. eutrophus. Two-dimensional gel electrophoresis allowed the separation of the cbbF gene products. Preliminary physical evidence by Southern hybridization with a heterologous gene probe was obtained for the existence of a third FBPase gene, fbp, on the chromosome of the organism. Its product is probably involved in the heterotrophic carbon metabolism.

Analysis of the genes forming the distal parts of the two cbb CO2 fixation operons from Alcaligenes eutrophus

In the facultative chemoautotroph Alcaligenes eutrophus H16, most of the genes (cbb genes) encoding enzymes of the Calvin carbon reduction cycle are organized within two highly homologous cbb operons, one located on the chromosome and the other on the megaplasmid pHG1. Nucleotide sequencing of the promoter-distal part of the operons revealed three open reading frames, designated cbbG, cbbK, and cbbA. Similarity searches in databases and heterologous expressions of the subcloned genes in Escherichia coli identified them as genes encoding the Calvin cycle enzymes glyceraldehyde-3-phosphate dehydrogenase, 3-phosphoglycerate kinase, and a class II fructose-1,6-bisphosphate aldolase, respectively. The aldolase could be grouped together with the enzymes from Rhodobacter sphaeroides and Bacillus subtilis as a new subtype of class II aldolases. A phenotypic complementation analysis with a cbb operon mutant of A. eutrophus showed that the cbbG product is essential for autotrophic growth of the organism, whereas the products of cbbK and cbbA can apparently be substituted by isoenzymes encoded elsewhere on the chromosome. No or only low constitutive promoter activity was associated with cbbK and cbbA, respectively, confirming the two genes as parts of the cbb operon. Downstream of cbbA, the very high overall nucleotide sequence identity (about 94%) prevailing throughout the two cbb operons discontinues, suggesting that cbbA is the most promoter-distal gene of the operon.

Transcription control of ribulose bisphosphate carboxylase/oxygenase activase and adjacent genes in Anabaena species

The gene encoding ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) activase (rca) was uniformly localized downstream from the genes encoding the large and small subunits of RubisCO (rbcL and rbcS) in three strains of Anabaena species. However, two open reading frames (ORF1 and ORF2), situated between rbcS and rca in Anabaena sp. strain CA, were not found in the intergenic region of Anabaena variabilis and Anabaena sp. strain PCC 7120. During autotrophic growth of Anabaena cells, rca and rbc transcripts accumulated in the light and diminished in the dark; light-dependent expression of these genes was not affected by the nitrogen source and the concentration of exogenous CO2 supplied to the cells. When grown on fructose, rca- and rbc-specific transcripts accumulated in A. variabilis regardless of whether the cells were illuminated. Transcript levels, however, were much lower in dark-grown heterotrophic cultures than in photoheterotrophic cultures. In photoheterotrophic cultures, the expression of the rca and rbc genes was similar to that in cultures grown with CO2 as the sole source of carbon. Although the rbcL-rbcS and rca genes are linked and are in the same transcriptional orientation in Anabaena strains, hybridization of rbc and rca to distinct transcripts suggested that these genes are not cotranscribed, consistent with the results of primer extension and secondary structure analysis of the nucleotide sequence. Transcription from ORF1 and ORF2 was not detected under the conditions examined, and the function of these putative genes remains unknown.

Identification of a novel gene, aut, involved in autotrophic growth of Alcaligenes eutrophus

The aerobic facultative chemoautotroph Alcaligenes eutrophus was found to possess a novel gene, designated aut, required for both lithoautotrophic (hydrogen plus carbon dioxide) and organoautotrophic (formate) growth (Aut+ phenotype). Insertional mutagenesis by transposon Tn5-Mob localized the gene on a chromosomal 13-kbp EcoRI fragment. Physiological characterization of various Aut- mutants revealed pleiotropic effects caused by the transposon insertion. Heterotrophic growth of the mutants on substrates catabolized via the glycolytic pathway was slower than that of the parent strains, and the colony morphology of the mutants was altered when grown on nutrient agar. The heterotrophic derepression of the cbb operons encoding Calvin cycle enzymes was abolished, although their expression was still inducible in the presence of formate. Apparently, the mutation did not affect the cbb genes directly but impaired the autotrophic growth in a more general manner. The conjugally transferred wild-type EcoRI fragment allowed phenotypic in trans complementation of the mutants. Further subcloning and sequencing identified a single open reading frame (aut) of 495 bp that was sufficient for complementation. The monocistronic aut gene was constitutively transcribed into a 0.65-kb mRNA. However, its expression appeared to be low. Heterologous expression of aut was achieved in Escherichia coli, resulting in overproduction of an 18-kDa protein. Database searches yielded weak partial sequence similarities of the deduced Aut protein sequence to some cytidylyltransferases, but no indication for the exact function of the aut gene was obtained. Hybridizing DNA sequences that might be similar to the aut gene were detected by Southern hybridization in the genome of two other autotrophic bacteria.

The cbb operons of the facultative chemoautotroph Alcaligenes eutrophus encode phosphoglycolate phosphatase

The two highly homologous cbb operons of Alcaligenes eutrophus H16 that are located on the chromosome and on megaplasmid pHG1 contain genes encoding several enzymes of the Calvin carbon reduction cycle. Sequence analysis of a region from the promoter-distal part revealed two open reading frames, designated cbbT and cbbZ, at equivalent positions within the operons. Comparisons with known sequences suggested cbbT to encode transketolase (TK; EC 2.2.1.1) as an additional enzyme of the cycle. No significant overall sequence similarities were observed for cbbZ. Although both regions exhibited very high nucleotide identities, 93% (cbbZ) and 96% (cbbT), only the chromosomally encoded genes were heterologously expressed to high levels in Escherichia coli. The molecular masses of the observed gene products, CbbT (74 kDa) and CbbZ (24 kDa), correlated well with the values calculated on the basis of the sequence information. TK activities were strongly elevated in E. coli clones expressing cbbT, confirming the identity of the gene. Strains of E. coli harboring the chromosomal cbbZ gene showed high levels of activity of 2-phosphoglycolate phosphatase (PGP; EC 3.1.3.18), a key enzyme of glycolate metabolism in autotrophic organisms that is not present in wild-type E. coli. Derepression of the cbb operons during autotrophic growth resulted in considerably increased levels of TK activity and the appearance of PGP activity in A. eutrophus, although the pHG1-encoded cbbZ gene was apparently not expressed. To our knowledge, this study represents the first cloning and sequencing of a PGP gene from any organism.

Complementation analysis and regulation of CO2 fixation gene expression in a ribulose 1,5-bisphosphate carboxylase-oxygenase deletion strain of Rhodospirillum rubrum

A ribulose 1,5-bisphosphate carboxylase-oxygenase (RubisCO) deletion strain of Rhodospirillum rubrum that was incapable of photolithoautotrophic growth was constructed. Photoheterotrophic growth, however, was possible for the R. rubrum RubisCO deletion strain when oxidized carbon compounds such as malate were supplied. The R. rubrum RubisCO-deficient strain was not complemented to photolithoautotrophic growth by various R. rubrum DNA fragments that contain the gene encoding RubisCO, cbbM. When the R. rubrum cbbM deletion strain harbored plasmids containing R. rubrum DNA inserts with at least 2.0 kb preceding the translational start site of the cbbM gene, RubisCO activity and RubisCO antigen were detected. Lack of RubisCO expression was therefore not the cause for the failure to complement the cbbM mutant strain. Interestingly, DNA fragments encoding either of two complete Calvin-Benson-Bassham CO2- fixation (cbb) gene operons from Rhodobacter sphaeroides were able to complement the R. rubrum RubisCO deletion strain to photolithoautotrophic growth. The same R. rubrum DNA fragments that failed to complement the R. rubrum cbbM deletion strain successfully complemented the RubisCO deletion strain of R. sphaeroides, pointing to distinct differences in the regulation of metabolism and the genetics of photolithoautotrophic growth in these two organisms. A number of cbb genes were identified by nucleotide sequence analysis of the region upstream of cbbM. Included among these was an open reading frame encoding a cbbR gene showing a high degree of sequence similarity to known lysR-type CO2 fixation transcriptional activator genes. The placement and orientation of the cbbR transcriptional regulator gene in R. rubrum are unique.

The Calvin cycle enzyme pentose-5-phosphate 3-epimerase is encoded within the cfx operons of the chemoautotroph Alcaligenes eutrophus

Several genes (cfx genes) encoding Calvin cycle enzymes in Alcaligenes eutrophus are organized in two highly homologous operons comprising at least 11 kb. One cfx operon is located on the chromosome; the other is located on megaplasmid pHG1 of the organism (B. Bowien, U. Windhövel, J.-G. Yoo, R. Bednarski, and B. Kusian, FEMS Microbiol. Rev. 87:445-450, 1990). Corresponding regions of about 2.7 kb from within the operons were sequenced. Three open reading frames, designated cfxX (954 bp), cfxY (765 bp), and cfxE (726 bp), were detected at equivalent positions in the two sequences. The nucleotide identity of the sequences amounted to 94%. Heterologous expression of the subcloned pHG1-encoded open reading frames in Escherichia coli suggested that they were functional genes. The observed sizes of the gene products CfxX (35 kDa), CfxY (27 kDa), and CfxE (25.5 kDa) closely corresponded to the values calculated on the basis of the sequence information. E. coli clones harboring the cfxE gene showed up to about 19-fold-higher activities of pentose-5-phosphate 3-epimerase (PPE; EC 5.1.3.1) than did reference clones, suggesting that cfxE encodes PPE, another Calvin cycle enzyme. These data agree with the finding that in A. eutrophus, PPE activity is significantly enhanced under autotrophic growth conditions which lead to a derepression of the cfx operons. No functions could be assigned to CfxX and CfxY.