Impact of each individual component of the mutated PTS(Nag) on glucose uptake and phosphorylation in Ralstonia eutropha G⁺1.

A recent study of the UV-generated glucose-utilizing mutant Ralstonia eutropha G⁺1 comprising transcriptomic and proteomic analyses revealed clear evidence that glucose is transported by the N-acetylglucosamine-specific phosphotransferase system (PTS(Nag)), which is overexpressed in this mutant due to a derepression of the encoding nag operon by an identified insertion mutation in nagR (Raberg et al., Appl Environ Microbiol 77:2058-2070, 2011). The inability of the defined deletion mutant R. eutropha G⁺1∆nagFEC to utilize glucose confirms this finding. Furthermore, a missense mutation in nagE (membrane component comprising the cell membrane spanning EIIC(Nag) and the cytosolic domain EIIB(Nag)) was identified, which yields a substitution of an alanine by threonine at aa 153 of NagE and may affect glucose specificity of the mutated PTS(Nag) in R. eutropha G⁺1. The investigation of various generated deletion and substitution mutants of R. eutropha H16 and G⁺1 in this study was able to elucidate these phenomena. It could be shown that the porin NagC, encoded by nagC being part of the nag operon, is not necessary, while NagE is required and is probably responsible for glucose transport through the cell membrane. The intracellular phosphorylation of glucose is obviously mediated by the glucokinase GLK and not by NagF (cytosolic component comprising the three soluble domains EIIA(Nag), HPr(Nag), and EI(Nag)). Our data clearly indicate that the derepression of the nag operon is essential for glucose uptake. The point mutation in NagE is not an essential prerequisite for glucose transport although it increased glucose transport as observed in this study.

Complete genome sequence of the type strain Cupriavidus necator N-1.

Here we announce the complete genome sequence of the copper-resistant bacterium Cupriavidus necator N-1, the type strain of the genus Cupriavidus. The genome consists of two chromosomes and two circular plasmids. Based on genome comparison, the chromosomes of C. necator N-1 share a high degree of similarity with the two chromosomal replicons of the bioplastic-producing hydrogen bacterium Ralstonia eutropha H16. The two strains differ in their plasmids and the presence of hydrogenase genes, which are absent in strain N-1.

Sulfoacetate is degraded via a novel pathway involving sulfoacetyl-CoA and sulfoacetaldehyde in Cupriavidus necator H16.

Bacterial degradation of sulfoacetate, a widespread natural product, proceeds via sulfoacetaldehyde and requires a considerable initial energy input. Whereas the fate of sulfoacetaldehyde in Cupriavidus necator (Ralstonia eutropha) H16 is known, the pathway from sulfoacetate to sulfoacetaldehyde is not. The genome sequence of the organism enabled us to hypothesize that the inducible pathway, which initiates sau (sulfoacetate utilization), involved a four-gene cluster (sauRSTU; H16_A2746 to H16_A2749). The sauR gene, divergently orientated to the other three genes, probably encodes the transcriptional regulator of the presumed sauSTU operon, which is subject to inducible transcription. SauU was tentatively identified as a transporter of the major facilitator superfamily, and SauT was deduced to be a sulfoacetate-CoA ligase. SauT was a labile protein, but it could be separated and shown to generate AMP and an unknown, labile CoA-derivative from sulfoacetate, CoA, and ATP. This unknown compound, analyzed by MALDI-TOF-MS, had a relative molecular mass of 889.7, which identified it as protonated sulfoacetyl-CoA (calculated 889.6). SauS was deduced to be sulfoacetaldehyde dehydrogenase (acylating). The enzyme was purified 175-fold to homogeneity and characterized. Peptide mass fingerprinting confirmed the sauS locus (H16_A2747). SauS converted sulfoacetyl-CoA and NADPH to sulfoacetaldehyde, CoA, and NADP(+), thus confirming the hypothesis.

Essential role of the hprK gene in Ralstonia eutropha H16.

Ralstonia eutropha H16 possesses an incomplete phosphoenolpyruvate (PEP):sugar phosphotransferase system (PTS) composed of EI, HPr, EIIA(Ntr) (PtsN) and EIIA(Man) (PtsM). We could show that in vitro the incomplete PTS phosphorylation cascade is partially functional. HPr becomes phosphorylated by PEP and EI, and transfers the phosphoryl group to EIIA(Ntr), but only extremely slowly to EIIA(Man). Components of this system have previously been shown to regulate the metabolism of polyhydroxybutyrate. Downstream from ptsN this organism contains an hprK gene, which codes for a homologue of HPr kinase/phosphorylase. We show that this enzyme phosphorylates HPr using ATP as phosphoryl donor. Interestingly, hprK appeared to be essential in R. eutropha because this gene could not be deleted in the wild-type strain, but could be deleted in mutants lacking ptsH or ptsI. This suggests that an increase in the HPr and/or P approximate His-HPr concentrations might be responsible for the growth defect. To test this hypothesis, various ptsH alleles were introduced into the ptsH hprK double mutant. Complementation of this mutant was possible only with the ptsH(His15Ala) allele, but not with the wild-type or ptsH(Ser46Ala) alleles. We conclude that elevated amounts of His-15-phosphorylated HPr, formed in the hprK mutant, are responsible for its growth defect.

The genome organization of Ralstonia eutropha strain H16 and related species of the Burkholderiaceae.

Ralstonia eutropha strain H16 is a facultatively chemolithoautotrophic, hydrogen-oxidizing bacterium belonging to the family Burkholderiaceae of the Betaproteobacteria. The genome of R. eutropha H16 consists of two chromosomes (Chr1, Chr2) and one megaplasmid (pHG1), and thus shows a multi-replicon architecture, which is characteristic for all members of the Burkholderiaceae sequenced so far. The genes for housekeeping cell functions are located on Chr1. In contrast, many characteristic traits of R. eutropha H16 such as the ability to switch between alternative lifestyles and to utilize a broad variety of growth substrates are primarily encoded on the smaller replicons Chr2 and pHG1. The latter replicons also differ from Chr1 by carrying a repA-associated origin of replication typically found on plasmids. Relationships between the individual replicons from various Burkholderiaceae genomes were studied by multiple sequence alignments and whole-replicon protein comparisons. While strong conservation of gene content and order among the largest replicons indicate a common ancestor, the resemblance between the smaller replicons is considerably lower, suggesting a species-specific origin of Chr2. The megaplasmids, however, in most cases do not show any taxonomically related similarities. Based on the results of the comparative studies, a hypothesis for the evolution of the multi-replicon genomes of the Burkholderiaceae is proposed.

Genome sequence of the bioplastic-producing "Knallgas" bacterium Ralstonia eutropha H16.

The H(2)-oxidizing lithoautotrophic bacterium Ralstonia eutropha H16 is a metabolically versatile organism capable of subsisting, in the absence of organic growth substrates, on H(2) and CO(2) as its sole sources of energy and carbon. R. eutropha H16 first attracted biotechnological interest nearly 50 years ago with the realization that the organism's ability to produce and store large amounts of poly[R-(-)-3-hydroxybutyrate] and other polyesters could be harnessed to make biodegradable plastics. Here we report the complete genome sequence of the two chromosomes of R. eutropha H16. Together, chromosome 1 (4,052,032 base pairs (bp)) and chromosome 2 (2,912,490 bp) encode 6,116 putative genes. Analysis of the genome sequence offers the genetic basis for exploiting the biotechnological potential of this organism and provides insights into its remarkable metabolic versatility.

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.

Genetics and control of CO(2) assimilation in the chemoautotroph Ralstonia eutropha.

The nutritional versatility of facultative autotrophs requires efficient overall control of their metabolism. Most of these organisms are Proteobacteria that assimilate CO(2) via the highly energy-demanding Calvin-Benson-Bassham reductive pentose-phosphate cycle. The enzymes of the cycle are encoded by cbb genes organized in cbb operons differing in size and composition, although conserved features are apparent. Transcription of the operons, which may form regulons, is strictly controlled, being induced during autotrophic but repressed to varying extents during heterotrophic growth of the bacteria. The chemoautotroph Ralstonia eutropha is one of the organisms studied extensively for the mechanisms involved in the expression of cbb gene systems. CbbR is a LysR-type transcriptional regulator and the key activator protein of cbb operons. The cbbR gene is typically located adjacent and in divergent orientation to its cognate operon. The activating function of CbbR seems to be modulated by metabolites signaling the nutritional state of the cell to the cbb system. Phosphoenolpyruvate is such a signal metabolite acting as a negative effector of R. eutropha CbbR, whereas NADPH has been proposed to be a coactivator of the protein in two other chemoautotrophs, Xanthobacter flavus and Hydrogenophilus thermoluteolus. There is evidence for the participation of additional regulators in cbb control. In the photoautotrophs Rhodobacter capsulatus and Rhodobacter sphaeroides, response regulator RegA of the global two-component signal transduction system RegBA serves this function. It is conceivable that specific variants of cbb control systems have evolved to ensure their optimal integration into regulatory networks operating in the diverse autotrophs characterized by different metabolic capabilities.