A physical map of the sulfur-dependent archaebacterium Sulfolobus acidocaldarius 7 chromosome

Genetic fidelity under harsh conditions: analysis of spontaneous mutation in the thermoacidophilic archaeon Sulfolobus acidocaldarius

Microbes whose genomes are encoded by DNA and for which adequate information is available display similar genomic mutation rates (average 0.0034 mutations per chromosome replication, range 0.0025 to 0.0046). However, this value currently is based on only a few well characterized microbes reproducing within a narrow range of environmental conditions. In particular, no genomic mutation rate has been determined either for a microbe whose natural growth conditions may extensively damage DNA or for any member of the archaea, a prokaryotic lineage deeply diverged from both bacteria and eukaryotes. Both of these conditions are met by the extreme thermoacidophile Sulfolobus acidocaldarius. We determined the genomic mutation rate for this species when growing at pH 3.5 and 75 degrees C based on the rate of forward mutation at the pyrE gene and the nucleotide changes identified in 101 independent mutants. The observed value of about 0.0018 extends the range of DNA-based microbes with rates close to the standard rate simultaneously to an archaeon and to an extremophile whose cytoplasmic pH and normal growth temperature greatly accelerate the spontaneous decomposition of DNA. The mutations include base pair substitutions (BPSs) and additions and deletions of various sizes, but the S. acidocaldarius spectrum differs from those of other DNA-based organisms in being relatively poor in BPSs. The paucity of BPSs cannot yet be explained by known properties of DNA replication or repair enzymes of Sulfolobus spp. It suggests, however, that molecular evolution per genome replication may proceed more slowly in S. acidocaldarius than in other DNA-based organisms examined to date.

Cell cycle regulation in the hyperthermophilic crenarchaeon Sulfolobus acidocaldarius

The regulation and co-ordination of the cell cycle of the hyperthermophilic crenarchaeon Sulfolobus acidocaldarius was investigated with antibiotics. We provide evidence for a core regulation involving alternating rounds of chromosome replication and genome segregation. In contrast, multiple rounds of replication of the chromosome could occur in the absence of an intervening cell division event. Inhibition of the elongation stage of chromosome replication resulted in cell division arrest, indicating that pathways similar to checkpoint mechanisms in eukaryotes, and the SOS system of bacteria, also exist in archaea. Several antibiotics induced cell cycle arrest in the G2 stage. Analysis of the run-out kinetics of chromosome replication during the treatments allowed estimation of the minimal rate of replication fork movement in vivo to 250 bp s-1. An efficient method for the production of synchronized Sulfolobus populations by transient daunomycin treatment is presented, providing opportunities for studies of cell cycle-specific events. Possible targets for the antibiotics are discussed, including topoisomerases and protein glycosylation.

Archaeon Pyrococcus kodakaraensis KOD1: application and evolution

Archaea is the third domain which is phylogenetically differentiated from the other two domains, bacteria and eucarya. Hyperthermophile within the archaea domain has evolved most slowly retaining many ancestral features of higher eukaryotes. Pyrococcus kodakaraensis KOD1, which grows at 95 degrees C optimally, is a newly isolated hyperthermophilc archaeon. The KOD1 strain possesses a circular genome, whose size is estimated to be approximately 2,036 kb. KOD1 enzymes involved in the genetic information processing system, such as DNA polymerase, Rec protein, aspartyl tRNA synthetase and molecular chaperonin, share features of eukaryotic enzymes. Rapid and accurate PCR method by KOD1 DNA polymerase and enzyme stabilization system by KOD1 chaperonin are also introduced in this article.

Physiology and genetics of sulfur-oxidizing bacteria

Reduced inorganic sulfur compounds are oxidized by members of the domains Archaea and Bacteria. These compounds are used as electron donors for anaerobic phototrophic and aerobic chemotrophic growth, and are mostly oxidized to sulfate. Different enzymes mediate the conversion of various reduced sulfur compounds. Their physiological function in sulfur oxidation is considered (i) mostly from the biochemical characterization of the enzymatic reaction, (ii) rarely from the regulation of their formation, and (iii) only in a few cases from the mutational gene inactivation and characterization of the resulting mutant phenotype. In this review the sulfur-metabolizing reactions of selected phototrophic and of chemotrophic prokaryotes are discussed. These comprise an archaeon, a cyanobacterium, green sulfur bacteria, and selected phototrophic and chemotrophic proteobacteria. The genetic systems are summarized which are presently available for these organisms, and which can be used to study the molecular basis of their dissimilatory sulfur metabolism. Two groups of thiobacteria can be distinguished: those able to grow with tetrathionate and other reduced sulfur compounds, and those unable to do so. This distinction can be made irrespective of their phototrophic or chemotrophic metabolism, neutrophilic or acidophilic nature, and may indicate a mechanism different from that of thiosulfate oxidation. However, the core enzyme for tetrathionate oxidation has not been identified so far. Several phototrophic bacteria utilize hydrogen sulfide, which is considered to be oxidized by flavocytochrome c owing to its in vitro activity. However, the function of flavocytochrome c in vivo may be different, because it is missing in other hydrogen sulfide-oxidizing bacteria, but is present in most thiosulfate-oxidizing bacteria. A possible function of flavocytochrome c is discussed based on biophysical studies, and the identification of a flavocytochrome in the operon encoding enzymes involved in thiosulfate oxidation of Paracoccus denitrificans. Adenosine-5'-phosphosulfate reductase thought to function in the 'reverse' direction in different phototrophic and chemotrophic sulfur-oxidizing bacteria was analysed in Chromatium vinosum. Inactivation of the corresponding gene does not affect the sulfite-oxidizing ability of the mutant. This result questions the concept of its 'reverse' function, generally accepted for over three decades.

Cell cycle characteristics of thermophilic archaea

We have performed a cell cycle analysis of organisms from the Archaea domain. Exponentially growing cells of the thermophilic archaea Sulfolobus solfataricus and Sulfolobus acidocaldarius were analyzed by flow cytometry, and several unusual cell cycle characteristics were found. The cells initiated chromosome replication shortly after cell division such that the proportion of cells with a single chromosome equivalent was low in the population. The postreplication period was found to be long; i.e., there was a considerable time interval from termination of chromosome replication until cell division. A further unusual feature was that cells in stationary phase contained two genome equivalents, showing that they entered the resting stage during the postreplication period. Also, a reduction in cellular light scatter was observed during entry into stationary phase, which appeared to reflect changes not only in cell size but also in morphology and/or composition. Finally, the in vivo organization of the chromosome DNA appeared to be different from that of eubacteria, as revealed by variation in the relative binding efficiency of different DNA stains.

Molecular and phylogenetic characterization of isopropylmalate dehydrogenase of a thermoacidophilic archaeon, Sulfolobus sp. strain 7

The archaeal leuB gene encoding isopropylmalate dehydrogenase of Sulfolobus sp. strain 7 was cloned, sequenced, and expressed in Escherichia coli. The recombinant Sulfolobus sp. enzyme was extremely stable to heat. The substrate and coenzyme specificities of the archaeal enzyme resembled those of the bacterial counterparts. Sedimentation equilibrium analysis supported an earlier proposal that the archaeal enzyme is homotetrameric, although the corresponding enzymes studied so far have been reported to be dimeric. Phylogenetic analyses suggested that the archaeal enzyme is homologous to mitochondrial NAD-dependent isocitrate dehydrogenases (which are tetrameric or octameric) as well as to isopropylmalate dehydrogenases from other sources. These results suggested that the present enzyme is the most primitive among isopropylmalate dehydrogenases belonging in the decarboxylating dehydrogenase family.

The world of archaea: genome analysis, evolution and thermostable enzymes

Pyrococcus sp. KOD1 is a newly isolated hyperthermophilic archaeon from a solfatara at a wharf on Kodakara Island, Kagoshima, Japan. A physical map of the KOD1 chromosome was constructed using pulsed-field gel electrophoresis of restriction fragments generated by AscI, PacI and PmeI. The order of the AscI fragments was deduced from Southern hybridization using the AscI, PmeI and PacI fragments as a probe. The derived physical map indicates that KOD1 possesses a circular-form genome and its size was estimated to be 2036 kb. Several cloned genes were hybridized to restriction fragments to locate their positions on the physical map. Some genes involved in the central dogma were located on the restricted segment of the genome. Novel characteristics of KOD1 enzymes are also introduced in this article.

An archaebacterial homolog of pelota, a meiotic cell division protein in eukaryotes

An open reading frame (pelA) specifying a homolog of pelota and DOM34, proteins required for meiotic cell division in Drosophila melanogaster and Saccharomyces cerevisiae, respectively, has been cloned, sequenced and identified from the archaebacterium Sulfolobus solfataricus. The S. solfataricus PelA protein is about 20% identical with pelota, DOM34 and the hypothetical protein R74.6 of Caenorhabditis elegans. The presence of a pelota homolog in archaebacteria implies that the meiotic functions of the eukaryotic protein were co-opted from, or added to, other functions existing before the emergence of eukaryotes. The nuclear localization signal and negatively charged carboxy-terminus characteristic of eukaryotic pelota-like proteins are absent from the S. solfataricus homolog, and hence may be indicative of the acquired eukaryotic function(s).

The Sulfolobus solfataricus P2 genome project

Over 800 kbp of the 3-Mbp genome of Sulfolobus solfataricus have been sequenced to date. Our approach is to sequence subclones of mapped cosmids, followed by sequencing directly on cosmid templates with custom primers. Using a prototype automated system for genome-scale analysis, known as MAGPIE, along with other tools, we have discovered one open reading frame of at least 100 amino acids per kbp of sequence, and have been able to associate 50% of these with known genes through database searches. An examination of completely sequenced cosmids suggests a clustering of genes by function in the S. solfataricus genome.

Exchange of genetic markers at extremely high temperatures in the archaeon Sulfolobus acidocaldarius

When cells of two auxotrophic mutants of Sulfolobus acidocaldarius are mixed and incubated on solid medium, they form stable genetic recombinants which can be selected, enumerated, and characterized. Any of a variety of auxotrophic markers can recombine with each other, and the phenomenon has been observed at temperatures of up to 84 degrees C. The ability to exchange and recombine chromosomal markers appears to be an intrinsic property of S. acidocaldarius strains. It occurs between two cell lines derived from the same parent or from different parents and also between a recombinant and its parent. This is the first observation of chromosomal marker exchange in archaea from geothermal environments and provides the first functional evidence of generalized, homologous recombination at such high temperatures.

A multicopy plasmid of the extremely thermophilic archaeon Sulfolobus effects its transfer to recipients by mating

A plasmid of 45 kb, designated pNOB8, was found in high copy number in a new heterotrophic Sulfolobus isolate, NOB8H2, from Japan. Dissemination of the plasmid occurred in six cultures of nine different Sulfolobus strains when small amounts of the donor were added. These mixed cultures exhibited a high average copy number of the plasmid, between 20 and 40 per chromosome, and showed a marked growth retardation. Horizontal transfer of pNOB8 was proved by isolating transcipients from mating mixtures via single colonies. In these isolates, the copy number of the plasmid appeared to be subject to a control mechanism. Cell-free filtrates of donor cultures did not transmit the plasmid, and plating of the donor on lawns of recipients did not result in plaque formation, suggesting that the transfer was not mediated by a virus. Rapid formation of cell-to-cell contacts between differently stained donor and recipient partners was demonstrated after the two strains were mixed. Electron microscopic analysis of mating mixtures revealed many cell aggregates made up of 2 to 30 cells and intercellular cytoplasmic bridges connecting two or more cells. Cells that had been transformed with purified plasmid DNA as well as transcipients isolated from mating mixtures were shown to serve as donors for further transmission of pNOB8. The plasmid undergoes extensive genetic variations, since deletions and insertions were frequently observed in plasmid preparations from the donor strain and from mating mixtures.

Archaebacterial genomes: eubacterial form and eukaryotic content

Since the recognition of the uniqueness and coherence of the archaebacteria (sometimes called Archaea), our perception of their role in early evolution has been modified repeatedly. The deluge of sequence data and rapidly improving molecular systematic methods have combined with a better understanding of archaebacterial molecular biology to describe a group that in some ways appears to be very similar to the eubacteria, though in others is more like the eukaryotes. The structure and contents of archaebacterial genomes are examined here, with an eye to their meaning in terms of the evolution of cell structure and function.