Reaction centers from three herbicide-resistant mutants of Rhodobacter sphaeroides 2.4.1: sequence analysis and preliminary characterization

Many herbicides that inhibit photosynthesis in plants also inhibit photosynthesis in bacteria. We have isolated three mutants of the photosynthetic bacterium Rhodobacter sphaeroides that were selected for increased resistance to the herbicide terbutryne. All three mutants also showed increased resistance to the known electron transfer inhibitor o-phenanthroline. The primary structures of the mutants were determined by recombinant DNA techniques. All mutations were located on the gene coding for the L-subunit resulting in these changes Ile²²⁹ Met, Ser²²³ Pro and Tyr²²² Gly. The mutations of Ser²²³ is analogous to the mutation of Ser²⁶⁴ in the D1 subunit of photosystem II in green plants, strengthening the functional analogy between D1 and the bacterial L-subunit. The changed amino acids of the mutant strains form part of the binding pocket for the secondary quinone, Q _b . This is consistent with the idea that the herbicides are competitive inhibitors for the Q _b binding site. The reaction centers of the mutants were characterized with respect to electron transfer rates, inhibition constants of terbutryne and o-phenanthroline, and binding constants of the quinone UQ₀ and the inhibitors. By correlating these results with the three-dimensional structure obtained from x-ray analysis by Allen et al. (1987a, 1987b), the likely positions of o-phenanthroline and terbutryne were deduced. These correspond to the positions deduced by Michel et al. (1986a) for Rhodopseudomonas viridis.Abbreviations ATP adenosine 5-triphosphate - Bchl bacteriochlorophyll - Bphe bacteriopheophytin - bp basepair - cyt c²⁺ reduced form of cytochrome c - DEAE diethylami-noethyl - EDTA ethylenediamine tetraacetic acid - Fe²⁺ non-heme iron atom - LDAO lauryl dimethylamine oxide - Pipes piperazine-N,N-bis-2-ethane-sulfonic acid - PSII photosystem II - RC reaction center - SDS sodium dodecylsulfate - Tris tris(hydroxy-methyl)aminomethane - UQ₀ 2,3-dimethoxy-5-methyl benzoquinone - UQ₁₀ ubiquinone 50     

DNA sequence duplication in Rhodobacter sphaeroides 2.4.1: evidence of an ancient partnership between chromosomes I and II

The complex genome of Rhodobacter sphaeroides 2.4.1, composed of chromosomes I (CI) and II (CII), has been sequenced and assembled. We present data demonstrating that the R. sphaeroides genome possesses an extensive amount of exact DNA sequence duplication, 111 kb or approximately 2.7% of the total chromosomal DNA. The chromosomal DNA sequence duplications were aligned to each other by using MUMmer. Frequency and size distribution analyses of the exact DNA duplications revealed that the interchromosomal duplications occurred prior to the intrachromosomal duplications. Most of the DNA sequence duplications in the R. sphaeroides genome occurred early in species history, whereas more recent sequence duplications are rarely found. To uncover the history of gene duplications in the R. sphaeroides genome, 44 gene duplications were sampled and then analyzed for DNA sequence similarity against orthologous DNA sequences. Phylogenetic analysis revealed that approximately 80% of the total gene duplications examined displayed type A phylogenetic relationships; i.e., one copy of each member of a duplicate pair was more similar to its orthologue, found in a species closely related to R. sphaeroides, than to its duplicate, counterpart allele. The data reported here demonstrate that a massive level of gene duplications occurred prior to the origin of the R. sphaeroides 2.4.1 lineage. These findings lead to the conclusion that there is an ancient partnership between CI and CII of R. sphaeroides 2.4.1.     

Interacting regulatory circuits involved in orderly control of photosynthesis gene expression in Rhodobacter sphaeroides 2.4.1

FnrL, the homolog of the global anaerobic regulator Fnr, is required for the induction of the photosynthetic apparatus in Rhodobacter sphaeroides 2.4.1. Thus, the precise role of FnrL in photosynthesis (PS) gene expression and its interaction(s) with other regulators of PS gene expression are of considerable importance to our understanding of the regulatory circuitry governing spectral complex formation. Using a CcoP and FnrL double mutant strain, we obtained results which suggested that FnrL is not involved in the transduction of the inhibitory signal, by which PS gene expression is "silenced," emanating from the cbb(3) oxidase encoded by the ccoNOQP operon under aerobic conditions. The dominant effect of the ccoP mutation in the FnrL mutant strain with respect to spectral complex formation under aerobic conditions and restoration of a PS-positive phenotype suggested that inactivation of the cbb(3) oxidase to some extent bypasses the requirement for FnrL in the formation of spectral complexes. Additional analyses revealed that anaerobic induction of the bchE, hemN, and hemZ genes, which are involved in the tetrapyrrole biosynthetic pathways, requires FnrL. Thus, FnrL appears to be involved at multiple loci involved in the regulation of PS gene expression. Additionally, bchE was also shown to be regulated by the PrrBA two-component system, in conjunction with hemN and hemZ. These and other results to be discussed permit us to more accurately describe the role of FnrL as well as the interactions between the FnrL, PrrBA, and other regulatory circuits in the regulation of PS gene expression.     

Revised Sequence and Annotation of the Rhodobacter sphaeroides 2.4.1 Genome

The DNA sequences of chromosomes I and II of Rhodobacter sphaeroides strain 2.4.1 have been revised, and the annotation of the entire genomic sequence, including both chromosomes and the five plasmids, has been updated. Errors in the originally published sequence have been corrected, and ∼11% of the coding regions in the original sequence have been affected by the revised annotation.     

Molecular genetic analysis suggesting interactions between AppA and PpsR in regulation of photosynthesis gene expression in Rhodobacter sphaeroides 2.4.1.

The AppA protein plays an essential regulatory role in development of the photosynthetic apparatus in the anoxygenic phototrophic bacterium Rhodobacter sphaeroides 2.4.1 (M. Gomelsky and S. Kaplan, J. Bacteriol. 177:4609-4618, 1995). To gain additional insight into both the role and site of action of AppA in the regulatory network governing photosynthesis gene expression, we investigated the relationships between AppA and other known regulators of photosynthesis gene expression. We determined that AppA is dispensable for development of the photosynthetic apparatus in a ppsR null background, where PpsR is an aerobic repressor of genes involved in photopigment biosynthesis and puc operon expression. Moreover, all suppressors of an appA null mutation thus far isolated, showing improved photosynthetic growth, were found to contain mutations in the ppsR gene. Because ppsR gene expression in R. sphaeroides 2.4.1 appears to be largely independent of growth conditions, we suggest that regulation of repressor activity occurs predominately at the protein level. We have also found that PpsR functions as a repressor not only under aerobic but under anaerobic photosynthetic conditions and thereby is involved in regulating the abundance of the light harvesting complex II, depending on light intensity. It seems likely therefore, that PpsR responds to an integral signal (e.g., changes in redox potential) produced either by changes in oxygen tension or light intensity. The profile of the isolated suppressor mutations in PpsR is in accord with this proposition. We propose that AppA may be involved in a redox-dependent modulation of PpsR repressor activity.     

Topological analysis of the membrane-localized redox-responsive sensor kinase PrrB from Rhodobacter sphaeroides 2.4.1.

Photosynthesis gene expression in Rhodobacter sphaeroides is controlled in part by the two-component (Prr) regulatory system composed of a membrane-bound sensor kinase (PrrB) and a response regulator (PrrA). Hydropathy profile-based computer analysis predicted that the PrrB polypeptide could contain six membrane-spanning domains at its amino terminus and a hydrophilic, cytoplasmic carboxyl terminus. Both the localization and the topology of the PrrB sensor kinase have been studied by generating a series of gene fusions with the Escherichia coli periplasmically localized alkaline phosphatase and the cytoplasmic beta-galactosidase. Eighteen prrB-phoA and five prrB-lacZ fusions were constructed and expressed in both E. coli and R. sphaeroides. Enzymatic activity assays and immunoblot analyses were performed to identify and to localize the different segments of PrrB in the membrane. The data obtained in E. coli generally correlated with the data obtained in R. sphaeroides and support the computer predictions. On the basis of the theoretical model and the results provided by these studies, a topological model for the membrane localization of the PrrB polypeptide is proposed.     

The home stretch,a first analysis of the nearly completed genome of Rhodobacter sphaeroides 2.4.1

Rhodobacter sphaeroides 2.4.1 is an α-3 purple nonsulfur eubacterium with an extensive metabolic repertoire. Under anaerobic conditions, it is able to grow by photosynthesis, respiration and fermentation. Photosynthesis may be photoheterotrophic using organic compounds as both a carbon and a reducing source, or photoautotrophic using carbon dioxide as the sole carbon source and hydrogen as the source of reducing power. In addition, R. sphaeroides can grow both chemoheterotrophically and chemoautotrophically. The structural components of this metabolically diverse organism and their modes of integrated regulation are encoded by a genome of ∼4.5 Mb in size. The genome comprises two chromosomes CI and CII (2.9 and 0.9 Mb, respectively) and five other replicons. Sequencing of the genome has been carried out by two groups, the Joint Genome Institute, which carried out shotgun-sequencing of the entire genome and The University of Texas-Houston Medical School, which carried out a targeted sequencing strategy of CII. Here we describe our current understanding of the genome when data from both of these groups are combined. Previous work had suggested that the two chromosomes are equal partners sharing responsibilities for fundamental cellular processes. This view has been reinforced by our preliminary analysis of the virtually completed genome sequence. We also have some evidence to suggest that two of the plasmids, pRS241a and pRS241b encode chromosomal type functions and their role may be more than that of accessory elements, perhaps representing replicons in a transition state. This revised version was published online in June 2006 with corrections to the Cover Date.     

In Vivo Analysis of Cobinamide Salvaging in Rhodobacter sphaeroides Strain 2.4.1

The genome of Rhodobacter sphaeroides encodes the components of two distinct pathways for salvaging cobinamide (Cbi), a precursor of adenosylcobalamin (AdoCbl, coenzyme B₁₂). One pathway, conserved among bacteria, depends on a bifunctional kinase/guanylyltransferase (CobP) enzyme to convert adenosylcobinamide (AdoCbi) to AdoCbi-phosphate (AdoCbi-P), an intermediate in de novo AdoCbl biosynthesis. The other pathway, of archaeal origin, depends on an AdoCbi amidohydrolase (CbiZ) enzyme to generate adenosylcobyric acid (AdoCby), which is converted to AdoCbi-P by the AdoCbi-P synthetase (CobD) enzyme. Here we report that R. sphaeroides strain 2.4.1 synthesizes AdoCbl de novo and that it salvages Cbi using both of the predicted Cbi salvaging pathways. AdoCbl produced by R. sphaeroides was identified and quantified by high-performance liquid chromatography and bioassay. The deletion of cobB (encoding an essential enzyme of the de novo corrin ring biosynthetic pathway) resulted in a strain of R. sphaeroides that would not grow on acetate in the absence of exogenous corrinoids. The results from a nutritional analysis showed that the presence of either CbiZ or CobP was necessary and sufficient for Cbi salvaging, that CbiZ-dependent Cbi salvaging depended on the presence of CobD, and that CobP-dependent Cbi salvaging occurred in a cbiZ⁺ strain. Possible reasons why R. sphaeroides maintains two distinct pathways for Cbi salvaging are discussed.Cobamides, such as adenosylcobalamin (AdoCbl, coenzyme B₁₂), are a group of complex cobalt-containing cyclic tetrapyrrole cofactors whose biosynthesis by bacteria and archaea requires substantial genetic information (>25 genes) (reviewed in references 25, 47, and 56). Two pathways for the de novo synthesis of the corrin ring have been described on the basis of the timing of cobalt insertion into the ring. The late cobalt insertion or aerobic pathway has been well studied in Pseudomonas denitrificans (9), while the early cobalt insertion or anaerobic pathway has been best studied in Salmonella enterica serovar Typhimurium LT2 (25). Many organisms, including those that synthesize AdoCbl de novo, salvage incomplete corrinoids (e.g., cobinamide [Cbi]) from their environments and use them as precursors for the synthesis of complete cobamide cofactors. Cbi is not an intermediate of the de novo AdoCbl biosynthesis pathway but can be converted into one by a process known as Cbi salvaging (Fig. ​(Fig.1)1) (24).Open in a separate windowFIG. 1.Abbreviated view of cobinamide salvaging pathways. Corrin ring-containing intermediates are in bold text. The letter A indicates the de novo corrin ring biosynthesis pathway. Abbreviations: Ado-, adenosyl-; AP, 1-amino-2-propanol; AP-P, 1-amino-2-propanol-phosphate; CobB, hydrogenobyrinic acid a,c-diamide synthase; CobD, adenosylcobinamide-phosphate synthetase; CobP, NTP:adenosylcobinamide kinase, GTP:adenosylcobinamide-phosphate guanylyltransferase; CobY, GTP:adenosylcobinamide-phosphate guanylyltransferase; CbiZ, adenosylcobinamide amidohydrolase. Functional groups are indicated as follows: Me, methyl; Ac, acetamide; and Pr, propionamide.The first step of Cbi salvaging is adenosylation of the molecule to adenosylcobinamide (AdoCbi) (24). The adenosyltransferases which catalyze this reaction are broadly distributed throughout the three domains of life (13, 14, 20, 32, 38). Two distinct pathways for converting AdoCbi into an intermediate of the de novo AdoCbl biosynthesis pathway have been described for prokaryotes. One, which is to date found only in bacteria, relies on a bifunctional nucleoside triphosphate (NTP):AdoCbi kinase (EC 2.7.7.62), GTP:AdoCbi-phosphate (AdoCbi-P) guanylyltransferase (EC 2.7.1.156) enzyme (called CobP in P. denitrificans and CobU in S. Typhimurium), which phosphorylates AdoCbi to AdoCbi-P and converts AdoCbi-P to AdoCbi-GDP (10, 41, 55).Previous work from our laboratory has shown that archaea lack the bifunctional NTP:AdoCbi kinase, GTP:AdoCbi-P guanylyltransferase enzyme and rely on a second pathway for Cbi salvaging (54, 62). In this pathway, AdoCbi is converted to adenosylcobyric acid (AdoCby) by an AdoCbi amidohydrolase (EC 3.5.1.90) known as CbiZ (58, 59, 62). The conversion of AdoCbi-P to AdoCbi-GDP for de novo AdoCbl biosynthesis in archaea is catalyzed by a monofunctional GTP:AdoCbi-P guanylyltransferase (EC 2.7.7.62) called CobY (54, 60), which has not been found in any bacterium.We recently showed that a small percentage of bacterial genomes encode orthologs of both CobP-type and CbiZ-type Cbi salvaging enzymes, raising the question of why these organisms might contain two redundant Cbi salvaging systems (29). A phylogenetic analysis showed that CbiZ has its roots in the archaea and that the cbiZ gene was acquired by several bacterial lineages via horizontal gene transfer.We previously showed that the CbiZ and CobP enzymes from the photosynthetic alphaproteobacterium Rhodobacter sphaeroides are functional in vitro and in vivo in a heterologous complementation system (29). However, the question of how the two Cbi salvaging systems might function in R. sphaeroides remained unresolved.In this paper, we show that R. sphaeroides 2.4.1 synthesizes substantial amounts of cobalamin (Cbl) and that it salvages incomplete corrinoids from its environment. We present in vivo genetic evidence that both the bacterial-type CobP-dependent and archaeal-type CbiZ-dependent Cbi salvaging pathways are functional in this organism. This work represents the first in vivo genetic analysis of coenzyme B₁₂ synthesis and salvaging in R. sphaeroides.     

The photosynthesis gene cluster of Rhodobacter sphaeroides

The photosynthetic bacteria are at the forefront of the study of many aspects of photosynthesis, including photopigment biosynthesis, photosynthetic-membrane assembly, light-harvesting, and reaction center photochemistry. The facultative growth of some photosynthetic bacteria, their simple photosystems, and their ease of genetic manipulation have all contributed to advances in these areas. Amongst these bacteria, the purple non-sulfur bacterium Rhodobacter sphaeroides has emerged as, arguably, the leading contender for a model system in which to integrate the studies of all the different aspects of the assembly and function of the photosynthetic apparatus. Many of the genes encoding photosynthesis-related proteins are known to be clustered within a small region of the genome in this organism. As a further aid to studying the assembly and function of the photosystem of Rb. sphaeroides, the DNA sequence for a genomic segment containing this photosynthesis gene cluster (PGC) has been assembled from previous EMBL submissions and formerly unpublished data. The Rb. sphaeroides PGC is 40.7 kb in length and consists of 38 open reading frames encoding the reaction center H, L and M subunits, the and polypeptides of the light-harvesting I (B875) complex, and the enzymes of bacteriochlorophyll and carotenoid biosynthesis. PGCs are a feature of gene organization in several photosynthetic bacteria, and the similarities between the clusters of Rb. sphaeroides and Rb. capsulatus have been apparent for some time. Here we present the first comprehensive analysis of the PGC of Rb. sphaeroides, as well as a comparison with that of Rb. capsulatus.     

Analysis of hemF gene function and expression in Rhodobacter sphaeroides 2.4.1

The hemF gene of Rhodobacter sphaeroides 2.4.1 is predicted to code for an oxygen-dependent coproporphyrinogen III oxidase. We found that a HemF- mutant strain is unable to grow under aerobic conditions. We also determined that hemF expression is controlled by oxygen, which is mediated, at least in part, by the response regulatory protein PrrA.     

Modifying the endogenous electron fluxes of Rhodobacter sphaeroides 2.4.1 for improved electricity generation

The purple bacteria Rhodobacter sphaeroides serve as a promising biocatalyst in the photo-microbial fuel cell system (photo-MFC). This gram-negative species performs highly efficient anoxygenic photosynthesis that ensures an anaerobic environment in the anode compartment. Previous studies incorporating R. sphaeroides into photo-MFC were conducted using platinum as the anode electrode. In this study, we detected a steady current generation of R. sphaeroides in a bioelectrochemical system where glassy carbon was the working electrode and a typical growth medium was the electrolyte. The bioelectricity generation synchronized with the supplementation of reduced carbon source and showed immediate response to illumination, which strongly indicated the correlation between the observed current and the cytoplasmic quinone activity. Modifications of the endogenous electron flows mediated by quinone pool are shown to have significantly enhanced the bioelectricity generation. We anticipate that the findings in this study would advance future optimization of R. sphaeroides as an anode strain, as well as facilitate the study of bioenergetics in photosynthetic bacteria.     

Dominant role of the cbb3 oxidase in regulation of photosynthesis gene expression through the PrrBA system in Rhodobacter sphaeroides 2.4.1

In this study, the H303A mutant form of the cbb(3) oxidase (H303A oxidase), which has the H303A mutation in its catalytic subunit (CcoN), was purified from Rhodobacter sphaeroides. The H303A oxidase showed the same catalytic activity as did the wild-type form of the oxidase (WT oxidase). The heme contents of the mutant and WT forms of the cbb(3) oxidase were also comparable. However, the puf and puc operons, which are under the control of the PrrBA two-component system, were shown to be derepressed aerobically in the R. sphaeroides strain expressing the H303A oxidase. Since the strain harboring the H303A oxidase exhibited the same cytochrome c oxidase activity as the stain harboring the WT oxidase did, the aerobic derepression of photosynthesis gene expression observed in the H303A mutant appears to be the result of a defective signaling function of the H303A oxidase rather than reflecting any redox changes in the ubiquinone/ubiquinol pool. It was also demonstrated that ubiquinone inhibits not only the autokinase activity of full-length PrrB but also that of the truncated form of PrrB lacking its transmembrane domain, including the proposed quinone binding sequence. These results imply that the suggested ubiquinone binding site within the PrrB transmembrane domain is not necessary for the inhibition of PrrB kinase activity by ubiquinone. Instead, it is probable that signaling through H303 of the CcoN subunit of the cbb(3) oxidase is part of the pathway through which the cbb(3) oxidase affects the relative kinase/phosphatase activity of the membrane-bound PrrB.