Detection of Hyperthermophilic Archaea of the Genus Desulfurococcus by Hybridization with Oligonucleotide Probes

Based on the analysis of nucleotide sequences of 16S rRNA, oligonucleotide probes were designed for the detection and identification of representatives of the genus Desulfurococcus (kingdom Crenarchaeota of the domain Archaea). The detection procedure included obtaining PCR products on DNA isolated from pure cultures, enrichments, or natural samples with a designed Crenarchaeota-specific primer pair: Cren 7F (5"-TTCCGGTTGATCCYGCCGGACC-3") and Cren 518R (5"-GCTGGTWTTACCGCGGCGGCTGA-3"). The PCR products were hybridized with Dig-11-dUTP–labeled oligonucleotide probes targeting the genus Desulfurococcus (Dco 198, 5"-CGTTAACYCCYGCCACACC-3") and its species D. mobilis (Dco_mob 198, 5"-CGTTAACCCCTGCCACACC-3") and D. amylolyticus (Dco_amy 198, 5"-CGTTAACCCCCGCCACACC-3"). With the use of these primers and probes, four new strains isolated from hydrotherms of Kamchatka and Kunashir Island were identified as members of the speciesDesulfurococcus amylolyticus. Desulfurococcus representatives were detected in several natural samples, including a sample taken from a marine hydrotherm at Kunashir Island; this demonstrates that representatives of this genus occur not only in terrestrial but also in marine environments.     

Phylogenetic systematics of microorganisms inhabiting thermal environments

Thermal habitats harbor specialized communities of thermophilic microorganisms, primarily prokaryotes. This review considers modern systematics of prokaryotes and the place of thermophilic archaea and bacteria in it. Among the existing hierarchical classifications of prokaryotes, the bulk of attention is given to the one accepted in the current second edition of "Bergey's Manual of Systematic Bacteriology", which is primarily based on 16S rRNA phylogeny and phenotypic properties of the organisms. Analysis of the genomics data shows that they on the whole agree with the 16S rRNA-based system, although revealing the significance of the evolutionary role of lateral transfer, duplication, and loss of genes. According to the classification elaborated in the current edition of "Bergey's Manual", the prokaryotes currently culturable under laboratory conditions are distributed among 26 phyla, two of which belong to the domain Archaea and 24 to the domain Bacteria. Six phyla contain exclusively thermophiles, and eleven phyla contain thermophiles along with mesophiles, thermophiles being usually separated phylogenetically and representing high-level taxa (classes, orders). In light of the data on the topology of the 16S rRNA-based phylogenetic tree and some other data, this review discusses the probable hyperthermophilic nature of the universal common ancestor.     

The first evidence of anaerobic CO oxidation coupled with H<Subscript>2</Subscript> production by a hyperthermophilic archaeon isolated from a deep-sea hydrothermal vent

From 24 samples of hydrothermal venting structures collected at the East Pacific Rise (13°N), 13 enrichments of coccoid cells were obtained which grew on CO, producing H₂ and CO₂ at 80°C. A hyperthermophilic archaeon capable of lithotrophic growth on CO coupled with equimolar production of H₂ was isolated. Based on its 16S rRNA sequence analysis, this organism was affiliated with the genus Thermococcus. Other strains of Thermococcales species (Pyrococcus furiosus, Thermococcus peptonophilus, T. profundus, T. chitonophagus, T. stetteri, T. gorgonarius, T. litoralis, and T. pacificus) were shown to be unable to grow on CO. Searches in sequence databases failed to reveal deposited sequences of genes related to CO metabolism in Thermococcales. Our work provides the first evidence of anaerobic CO oxidation coupled with H₂ production performed by an archaeon as well as the first documented case of lithotrophic growth of a Thermococcales representative.     

PCR-Based Identification of Hyperthermophilic Archaea of the Family Thermococcaceae

A method for rapid detection and identification of hyperthermophilic archaea of the family Thermococcaceae based on PCR amplification of 16S rRNA gene fragments with primers TcPc 173F (5′-TCCCCCATAGGYCTGRGGTACTGGAAGGTC-3′) and TcPc 589R (5′-GCCGTGRGATTTCGCCAGGGACTTACGGGC-3′) was developed and used for identification of new isolates.     

Investigation of structure and antigenic capacities of Thermococcales cell envelopes and reclassification of "Caldococcus litoralis" Z-1301 as Thermococcus litoralis Z-1301

Fourteen strains of hyperthermophilic organotrophic anaerobic marine Archaea were isolated from shallow water and deep-sea hot vents, and four of them were characterized. These isolates, eight previously published strains, and six type strains of species of the order Thermococcales were selected for the study of cell wall components by means of thin sectioning or freeze-etching electron microscopy. The cell envelopes of most isolates were shown to consist of regularly arrayed surface protein layers, either single or double, with hexagonal lattice (p6) symmetry, as the exclusive constituents outside the cytoplasmic membrane. The S-layers studied differed in center-to-center spacing and molecular mass of the constituent protein subunits. Polyclonal antisera raised against the cells of 10 species were found to be species-specific and allowed 12 new isolates from shallow water hot vents to be identified as representatives of the species Thermococcus litoralis, Thermococcus stetteri, Thermococcus chitonophagus, and Thermococcus pacificus. Of the 7 deep-sea isolates, only 1 was identified as a T. litoralis strain. Thus, hyperthermophilic marine organotrophic isolates obtained from deep-sea hot vents showed greater diversity with regard to their S-layer proteins than shallow water isolates.     

Aerobic carbon monoxide oxidation in the course of growth of a hyperthermophilic archaeon, <Emphasis Type="Italic">Sulfolobus</Emphasis> sp. ETSY

An aerobic hyperthermophilic CO-oxidizing archaeon, Sulfolobus sp. strain ETSY, was isolated and characterized. Presently, it is the only known representative of both hyperthermophiles and Archaea that is capable of aerobic oxidation of CO, a gas of global importance for atmospheric chemistry and of local importance as one of the substrates for the microbial communities of hydrothermal vents. In the genome of Sulfolobus sp. ETSY we found genetic determinants of aerobic CO oxidation: a coxFMSLDE gene cluster and two separately located coxG genes. We also found such gene clusters in the genomes of certain strains of Sulfolobus islandicus and Sulfolobus solfataricus. On the phylogenetic tree of large subunits of aerobic CO-dehydrogenases (CoxLs), these proteins of Sulfolobus representatives formed a compact cluster within one of the branches formed by bacterial form I CoxLs. Thus we argue that the ability to oxidize CO aerobically was acquired by Sulfolobus ancestor from Bacteria relatively late in the evolution, presumably after the formation of the atmosphere with a high oxygen content.     

Investigation of structure and antigenic capacities of Thermococcales cell envelopes and reclassification of "Caldococcus litoralis" Z-1301 as Thermococcus litoralis Z-1301

Fourteen strains of hyperthermophilic organotrophic anaerobic marine Archaea were isolated from shallow water and deep-sea hot vents, and four of them were characterized. These isolates, eight previously published strains, and six type strains of species of the order Thermococcales were selected for the study of cell wall components by means of thin sectioning or freeze-etching electron microscopy. The cell envelopes of most isolates were shown to consist of regularly arrayed surface protein layers, either single or double, with hexagonal lattice (p6) symmetry, as the exclusive constituents outside the cytoplasmic membrane. The S-layers studied differed in center-to-center spacing and molecular mass of the constituent protein subunits. Polyclonal antisera raised against the cells of 10 species were found to be species-specific and allowed 12 new isolates from shallow water hot vents to be identified as representatives of the species Thermococcus litoralis, Thermococcus stetteri, Thermococcus chitonophagus, and Thermococcus pacificus. Of the 7 deep-sea isolates, only 1 was identified as a T. litoralis strain. Thus, hyperthermophilic marine organotrophic isolates obtained from deep-sea hot vents showed greater diversity with regard to their S-layer proteins than shallow water isolates. Received: February 5, 1999 / Accepted: May 11, 1999