Two distinct pathways for thymidylate (dTMP) synthesis in (hyper)thermophilic Bacteria and Archaea.

The hyperthermophilic anaerobic archaeon Pyrococcus abyssi, which lacks thymidine kinase, incorporates label from extracellular uracil, but not from thymidine, into its DNA. This implies that P. abyssi must synthesize dTMP (thymidylate), an essential precursor for DNA synthesis, de novo. However, iterative similarity searches of the three completed Pyrococcus genomes fail to detect candidate genes for canonical thymidylate synthase ThyA, suggesting the presence of alternative pathways for dTMP synthesis. Indeed, by identifying a novel class of flavin-dependent thymidylate synthases, ThyX, we have recently proven that two distinct pathways for de novo synthesis of dTMP are operational in the microbial world. While both thyX and thyA can be found in hyperthermophilic micro-organisms, the phylogenetic distribution of thyX among hyperthermophiles is wider than that of thyA. In this contribution, we discuss the differences in the distinct mechanisms of dTMP synthesis, with a special emphasis on hyperthermophilic micro-organisms.

In vivo interactions of archaeal Cdc6/Orc1 and minichromosome maintenance proteins with the replication origin.

Although genome analyses have suggested parallels between archaeal and eukaryotic replication systems, little is known about the DNA replication mechanism in Archaea. By two-dimensional gel electrophoreses we positioned a replication origin (oriC) within 1 kb in the chromosomal DNA of Pyrococcus abyssi, an anaerobic hyperthermophile, and demonstrated that the oriC is physically linked to the cdc6 gene. Our chromatin immunoprecipitation assays indicated that P. abyssi Cdc6 and minichromosome maintenance (MCM) proteins bind preferentially to the oriC region in the exponentially growing cells. Whereas the oriC association of MCM was specifically inhibited by stopping DNA replication with puromycin treatment, Cdc6 protein stayed bound to the replication origin after de novo protein synthesis was inhibited. Our data suggest that archaeal and eukaryotic Cdc6 and MCM proteins function similarly in replication initiation and imply that an oriC association of MCM could be regulated by an unknown mechanism in Archaea.

The RegB/RegA two-component regulatory system controls synthesis of photosynthesis and respiratory electron transfer components in Rhodobacter capsulatus.

Recently, we demonstrated that the RegB/RegA two-component regulatory system from Rhodobacter capsulatus functions as a global regulator of metabolic processes that either generate or consume reducing equivalents. For example, the RegB/RegA system controls expression of such energy generating processes as photosynthesis and hydrogen utilization. In addition, RegB/RegA also control nitrogen and carbon fixation pathways that utilize reducing equivalents. Here, we use a combination of DNase I protection and plasmid-based reporter expression studies to demonstrate that RegA directly controls synthesis of cytochrome cbb3 and ubiquinol oxidases that function as terminal electron acceptors in a branched respiratory chain. We also demonstrate that RegA controls expression of cytochromes c2, c(y) and the cytochrome bc1 complex that are involved in both photosynthetic and respiratory electron transfer events. These data provide evidence that the RegB/RegA two-component system has a major role in controlling the synthesis of numerous processes that affect reducing equivalents in Rhodobacter capsulatus.

Mobile cytochrome c2 and membrane-anchored cytochrome cy are both efficient electron donors to the cbb3- and aa3-type cytochrome c oxidases during respiratory growth of Rhodobacter sphaeroides.

We have recently established that the facultative phototrophic bacterium Rhodobacter sphaeroides, like the closely related Rhodobacter capsulatus species, contains both the previously characterized mobile electron carrier cytochrome c2 (cyt c2) and the more recently discovered membrane-anchored cyt cy. However, R. sphaeroides cyt cy, unlike that of R. capsulatus, is unable to function as an efficient electron carrier between the photochemical reaction center and the cyt bc1 complex during photosynthetic growth. Nonetheless, R. sphaeroides cyt cy can act at least in R. capsulatus as an electron carrier between the cyt bc1 complex and the cbb3-type cyt c oxidase (cbb3-Cox) to support respiratory growth. Since R. sphaeroides harbors both a cbb3-Cox and an aa3-type cyt c oxidase (aa3-Cox), we examined whether R. sphaeroides cyt cy can act as an electron carrier to either or both of these respiratory terminal oxidases. R. sphaeroides mutants which lacked either cyt c2 or cyt cy and either the aa3-Cox or the cbb3-Cox were obtained. These double mutants contained linear respiratory electron transport pathways between the cyt bc1 complex and the cyt c oxidases. They were characterized with respect to growth phenotypes, contents of a-, b-, and c-type cytochromes, cyt c oxidase activities, and kinetics of electron transfer mediated by cyt c2 or cyt cy. The findings demonstrated that both cyt c2 and cyt cy are able to carry electrons efficiently from the cyt bc1 complex to either the cbb3-Cox or the aa3-Cox. Thus, no dedicated electron carrier for either of the cyt c oxidases is present in R. sphaeroides. However, under semiaerobic growth conditions, a larger portion of the electron flow out of the cyt bc1 complex appears to be mediated via the cyt c2-to-cbb3-Cox and cyt cy-to-cbb3-Cox subbranches. The presence of multiple electron carriers and cyt c oxidases with different properties that can operate concurrently reveals that the respiratory electron transport pathways of R. sphaeroides are more complex than those of R. capsulatus.

The membrane-extrinsic domain of cytochrome b(558/566) from the archaeon Sulfolobus acidocaldarius performs pivoting movements with respect to the membrane surface.

The orientation of the membrane-attached cytochrome b(558/566)-haem with respect to the membrane was determined by electron paramagnetic resonance spectroscopy on two-dimensionally ordered oxidised membrane fragments from Sulfolobus acidocaldarius. Unlike the other redox centres in the membrane, the cytochrome b(558/566)-haem was found to cover a range of orientations between 25 degrees and 90 degrees. The described results are reminiscent of those obtained on the Rieske cluster of bc complexes and indicate that the membrane-extrinsic domain of cytochrome b(558/566) can perform pivoting motion between two extreme positions. Such a conformational flexibility is likely to play a role in electron transfer with its redox partners.

Bacterial mode of replication with eukaryotic-like machinery in a hyperthermophilic archaeon.

Despite a rapid increase in the amount of available archaeal sequence information, little is known about the duplication of genetic material in the third domain of life. We identified a single origin of bidirectional replication in Pyrococcus abyssi by means of in silico analyses of cumulative oligomer skew and the identification of an early replicating chromosomal segment. The replication origin in three Pyrococcus species was found to be highly conserved, and several eukaryotic-like DNA replication genes were clustered around it. As in Bacteria, the chromosomal region containing the replication terminus was a hot spot of genome shuffling. Thus, although bacterial and archaeal replication proteins differ profoundly, they are used to replicate chromosomes in a similar manner in both prokaryotic domains.

The membrane-attached electron carrier cytochrome cy from Rhodobacter sphaeroides is functional in respiratory but not in photosynthetic electron transfer.

Rhodobacter species are useful model organisms for studying the structure and function of c type cytochromes (Cyt c), which are ubiquitous electron carriers with essential functions in cellular energy and signal transduction. Among these species, Rhodobacter capsulatus has a periplasmic Cyt c2Rc and a membrane-bound bipartite Cyt cyRc. These electron carriers participate in both respiratory and photosynthetic electron-transfer chains. On the other hand, until recently, Rhodobacter sphaeroides was thought to have only one of these two cytochromes, the soluble Cyt c2Rs. Recent work indicated that this species has a gene, cycYRs, that is highly homologous to cycYRc, and in the work presented here, functional properties of its gene product (Cyt cyRs) are defined. It was found that Cyt cyRs is unable to participate in photosynthetic electron transfer, although it is active in respiratory electron transfer, unlike its R. capsulatus counterpart, Cyt cyRc. Chimeric constructs have shown that the photosynthetic incapability of Cyt cyRs is caused, at least in part, by its redox active subdomain, which carries the covalently bound heme. It, therefore, seems that this domain interacts differently with distinct redox partners, like the photochemical reaction center and the Cyt c oxidase, and allows the bacteria to funnel electrons efficiently to various destinations under different growth conditions. These findings raise an intriguing evolutionary issue in regard to cellular apoptosis: why do the mitochondria of higher organisms, unlike their bacterial ancestors, use only one soluble electron carrier in their respiratory electron-transport chains?

Membrane-anchored cytochrome cy mediated microsecond time range electron transfer from the cytochrome bc1 complex to the reaction center in Rhodobacter capsulatus.

In Rhodobacter capsulatus, the soluble cytochrome (cyt) c2 and membrane-associated cyt cy are the only electron carriers which operate between the photochemical reaction center (RC) and the cyt bc1 complex. In this work, cyt cy mediated microsecond time range electron transfer kinetics were studied by light-activated time-resolved absorption spectroscopy using a mutant strain lacking cyt c2. In intact cells and in isolated chromatophores of this mutant, only approximately 30% of the RCs had their photooxidized primary donor rapidly rereduced by cyt cy. Of these 30%, about half were reduced with a half-time of approximately 5 micros attributed to preformed complexes, and the other half with a half-time of approximately 40 micros attributed to cyt cy having to move from another site. This slower phase was affected by addition of glycerol, indicating its dependence on the viscosity of the medium. Cyt cy, despite its rereduction by ubihydroquinone oxidation in the millisecond time range, remained virtually unable to deliver electrons to other RCs which stayed photooxidized for several seconds. Furthermore, using two flashes separated by a variable time interval, it was shown that the fast electron donating complex was reformed in about 60 micros, a time span probably reflecting electron transfer from cyt c1 to cyt cy. In the absence of the cyt bc1 complex, the steady-state level of cyt cy in the chromatophore membranes obtained using cells grown in minimal medium was decreased to approximately 50%. The remaining cyt cy , however, was able to form the fast electron donating complex with the RC (half-time of approximately 5 micros), whereas the slower phase with a half-time of approximately 40 micros was strongly decelerated. This finding suggests a role for the cyt bc1 complex in stabilizing cyt cy and providing its "other" site, possibly via a close association between these components. Taken together, it is concluded that although cyt cy is present in substoichiometric amount compared to the RCs, it supports efficiently photosynthetic growth of R. capsulatus in the absence of cyt c2 because it can mediate fast electron transfer from the cyt bc1 complex to the RC during multiple turnovers of the cyclic electron flow.

Cytochrome c(y) of Rhodobacter capsulatus is attached to the cytoplasmic membrane by an uncleaved signal sequence-like anchor.

During the photosynthetic growth of Rhodobacter capsulatus, electrons are conveyed from the cytochrome (cyt) bc1 complex to the photochemical reaction center by either the periplasmic cyt c2 or the membrane-bound cyt c(y). Cyt c(y) is a member of a recently established subclass of bipartite c-type cytochromes consisting of an amino (N)-terminal domain functioning as a membrane anchor and a carboxyl (C)-terminal domain homologous to cyt c of various sources. Structural homologs of cyt c(y) have now been found in several bacterial species, including Rhodobacter sphaeroides. In this work, a C-terminally epitope-tagged and functional derivative of R. capsulatus cyt c(y) was purified from intracytoplasmic membranes to homogeneity. Analyses of isolated cyt c(y) indicated that its spectral and thermodynamic properties are very similar to those of other c-type cytochromes, in particular to those from bacterial and plant mitochondrial sources. Amino acid sequence determination for purified cyt c(y) revealed that its signal sequence-like N-terminal portion is uncleaved; hence, it is anchored to the membrane. To demonstrate that the N-terminal domain of cyt c(y) is indeed its membrane anchor, this sequence was fused to the N terminus of cyt c2. The resulting hybrid cyt c (MA-c2) remained membrane bound and was able to support photosynthetic growth of R. capsulatus in the absence of the cyt c(y) and c2. Therefore, cyt c2 can support cyclic electron transfer during photosynthetic growth in either a freely diffusible or a membrane-anchored form. These findings should now allow for the first time the comparison of electron transfer properties of a given electron carrier when it is anchored to the membrane or is freely diffusible in the periplasm.

Rhodobacter capsulatus contains a novel cb-type cytochrome c oxidase without a CuA center.

The facultative phototrophic bacterium Rhodobacter capsulatus is capable of growth in a wide range of environmental conditions using a highly branched electron-transfer chain. During respiratory growth of this organism reducing equivalents are conveyed to oxygen via two terminal oxidases, previously called "cyt b410" (cytochrome c oxidase) and "cyt b260" (quinol oxidase). The cytochrome c oxidase was purified to homogeneity from a semiaerobically grown R. capsulatus strain. The purified enzyme consumes oxygen at a rate of 600 s-1, oxidizes reduced equine cyt c and R. capsulatus cyt c2, and has high sensitivity to cyanide. The complex is composed of three major polypeptides of apparent molecular masses 45, 32, and 28 kDa on SDS-PAGE. The 32- and 28-kDa proteins also stain with tetramethylbenzidine, indicating that they are c-type cytochromes. Partial amino acid sequences obtained from each of the subunits reveal significant homology to the fixN, fixO, and fixP gene products of Bradyrhizobium japonicum and Rhizobium meliloti. The reduced enzyme has an optical absorption spectrum with distinct features near 550 and 560 nm and an asymmetric Soret band centered at 418 nm, indicating the presence of both c- and b-type cytochromes. Two electrochemically distinct cyt c are apparent, with redox midpoint potentials (Em7) of 265 and 320 mV, while the low-spin cyt b has an Em7 value of 385 mV. The enzyme binds carbon monoxide, and the CO difference spectrum indicates that CO binds to a high-spin cyt b. Pyridine hemochrome and HPLC analyses suggest that the complex contains 1 mol of heme C to 1 mol of protoheme and that neither heme O nor heme A is present.(ABSTRACT TRUNCATED AT 250 WORDS)