Dennis W. Grogan

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°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.

HYPERTHERMOPHILES AND THE PROBLEM OF DNA INSTABILITY

Rates of chemical decomposition of DNA at the optimal growth temperatures of hyperthermophiles seem incongruent with the requirements of accurate genome replication. The peculiar physiology, ecology and phylogeny of hyperthermophiles combine to suggest that these prokaryotes have solved a molecular problem (spontaneous loss of native DNA structure) of a magnitude that well‐studied microorganisms do not face. The failure of DNA base composition to correlate with optimal growth temperature among hyperthermophiles provides indirect evidence that other mechanisms maintain their chromosomal DNA in the duplex form. Studies in vitro indicate that DNA primary structure is more difficult to maintain at extremely high temperature than is secondary structure, yet hyperthermophiles exhibit only modest levels of spontaneous mutation. Radiation sensitivity studies also indicate that hyperthermophiles repair their DNA efficiently in vivo, and underlying mechanisms are beginning to be examined. Several enzymes of DNA metabolism from hyperthermophilic archaea exhibit unusual biochemical features that may ultimately prove relevant to DNA repair. However, genomic sequencing results suggest that many DNA repair genes of hyperthermophilic archaea may not be recognized because they are not sufficiently related to those of well‐studied organisms.

Small multicopy, non-integrative shuttle vectors based on the plasmid pRN1 for Sulfolobus acidocaldarius and Sulfolobus solfataricus, model organisms of the (cren-)archaea

The extreme thermoacidophiles of the genus Sulfolobus are among the best-studied archaea but have lacked small, reliable plasmid vectors, which have proven extremely useful for manipulating and analyzing genes in other microorganisms. Here we report the successful construction of a series of Sulfolobus–Escherichia coli shuttle vectors based on the small multicopy plasmid pRN1 from Sulfolobus islandicus. Selection in suitable uracil auxotrophs is provided through inclusion of pyrEF genes in the plasmid. The shuttle vectors do not integrate into the genome and do not rearrange. The plasmids allow functional overexpression of genes, as could be demonstrated for the β-glycosidase (lacS) gene of S. solfataricus. In addition, we demonstrate that this β-glycosidase gene could function as selectable marker in S. solfataricus. The shuttle plasmids differ in their interruption sites within pRN1 and allowed us to delineate functionally important regions of pRN1. The orf56/orf904 operon appears to be essential for pRN1 replication, in contrast interruption of the highly conserved orf80/plrA gene is tolerated. The new vector system promises to facilitate genetic studies of Sulfolobus and to have biotechnological uses, such as the overexpression or optimization of thermophilic enzymes that are not readily performed in mesophilic hosts.

The question of DNA repair in hyperthermophilic archaea

Hyperthermophilic archaea grow at temperatures that destabilize the primary structure of DNA and in evolutionary terms they are highly divergent from other well studied microorganisms. These prokaryotes should therefore require DNA damage repair to be unusually effective, and could employ novel mechanisms for this repair. Recent genome sequence analyses and biochemical and genetic assays suggest a distribution of DNA repair strategies that raises intriguing questions for future study.

UV-inducible DNA exchange in hyperthermophilic archaea mediated by type IV pili

Archaea, like bacteria and eukaryotes, contain proteins involved in various mechanisms of DNA repair, highlighting the importance of these processes for all forms of life. Species of the order Sulfolobales of hyperthermophilic crenarchaeota are equipped with a strongly UV‐inducible type IV pilus system that promotes cellular aggregation. Here we demonstrate by fluorescence in situ hybridization that cellular aggregates are formed based on a species‐specific recognition process and that UV‐induced cellular aggregation mediates chromosomal marker exchange with high frequency. Recombination rates exceeded those of uninduced cultures by up to three orders of magnitude. Knockout strains of Sulfolobus acidocaldarius incapable of pilus production could not self‐aggregate, but were partners in mating experiments with wild‐type strains indicating that one cellular partner can mediate the DNA transfer. Since pilus knockout strains showed decreased survival upon UV treatment, we conclude that the UV‐inducible DNA transfer process and subsequent homologous recombination represents an important mechanism to maintain chromosome integrity in Sulfolobus. It might also contribute substantially to the frequent chromosomal DNA exchange and horizontal gene transfer in these archaea in their natural habitat.

Recombination of synthetic oligonucleotides with prokaryotic chromosomes: substrate requirements of the Escherichia coli/λRed and Sulfolobus acidocaldarius recombination systems

In order to reveal functional properties of recombination involving short ssDNAs in hyperthermophilic archaea, we evaluated oligonucleotide‐mediated transformation (OMT) in Sulfolobus acidocaldarius and Escherichia coli as a function of the molecular properties of the ssDNA substrates. Unmodified ssDNAs as short as 20–22 nt yielded recombinants in both organisms, as did longer DNAs forming as few as 2–5 base pairs on one side of the genomic mutation. The two OMT systems showed similar responses to certain end modifications of the oligonucleotides, but E. coli was found to require a 5′ phosphate on 5′‐limited ssDNA whereas this requirement was not evident in S. acidocaldarius. The ability of both E. coli and S. acidocaldarius to incorporate short, mismatched ssDNAs into their genomes raises questions about the biological significance of this capability, including its phylogenetic distribution among microorganisms and its impact on genome stability. These questions seem particularly relevant for S. acidocaldarius, as this archaeon has natural competence for OMT, encodes no MutSL homologues and thrives under environmental conditions that accelerate DNA decomposition.

New insertion sequences of Sulfolobus: functional properties and implications for genome evolution in hyperthermophilic Archaea

Analyses of complete genomes indicate that insertion sequences (ISs) are abundant and widespread in hyperthermophilic archaea, but few experimental studies have measured their activities in these hosts. As a way to investigate the impact of ISs on Sulfolobus genomes, we identified seven transpositionally active ISs in a widely distributed Sulfolobus species, and measured their functional properties. Six of the seven were found to be distinct from previously described ISs of Sulfolobus, and one of the six could not be assigned to any known IS family. A type II ‘Miniature Inverted‐repeat Transposable Element’ (MITE) related to one of the ISs was also recovered. Rates of transposition of the different ISs into the pyrEF region of their host strains varied over a 250‐fold range. The Sulfolobus ISs also differed with respect to target‐site selectivity, although several shared an apparent preference for the pyrEF promoter region. Despite the number of distinct ISs assayed and their molecular diversity, only one demonstrated precise excision from the chromosomal target region. The fact that this IS is the only one lacking inverted repeats and target‐site duplication suggests that the observed precise excision may be promoted by the IS itself. Sequence searches revealed previously unidentified partial copies of the newly identified ISs in the Sulfolobus tokodaii and Sulfolobus solfataricus genomes. The structures of these fragmentary copies suggest several distinct molecular mechanisms which, in the absence of precise excision, inactivate ISs and gradually eliminate the defective copies from Sulfolobus genomes.

Cytosine Methylation by the SuaI Restriction-Modification System: Implications for Genetic Fidelity in a Hyperthermophilic Archaeon

5-methylcytosine in chromosomal DNA represents a potential source of frequent spontaneous mutation for hyperthermophiles. To determine the relevance of this threat for the archaeon Sulfolobus acidocaldarius, the mode of GGCC methylation by its restriction-modification system, SuaI, was investigated. Distinct isoschizomers of the SuaI endonuclease were used to probe the methylation state of GGCC in native S. acidocaldarius DNA. In addition, the methylation sensitivity of the SuaI endonuclease was determined with synthetic oligonucleotide substrates and modified natural DNAs. The results show that the SuaI system uses N(4) methylation to block cleavage of its recognition site, thereby avoiding the creation of G. T mismatches by spontaneous deamination at extremely high temperature.

An Unusual Pattern of Spontaneous Mutations Recovered in the Halophilic Archaeon Haloferax volcanii

Spontaneous mutations in the orotate:phosphoribosyl transferase (pyrE2) gene of the halophilic archaeon Haloferax volcanii were selected by 5-fluoroorotic acid plus uracil at a rate of ∼2 × 10−8/cell division in fluctuation and null-fraction tests but ∼6 × 10−8/cell division in mutation-accumulation tests. The corresponding genomic mutation rates were substantially lower than those observed for other mesophilic microbial DNA genomes on the basis of similar target genes. The mutational spectrum was dominated by indels adding or deleting multiples of 3 bp. Properties of the organism contributing to this unusual mutational pattern may include phenotypic lag caused by a high chromosomal copy number and efficient promotion of strand misalignments by short direct repeats.

Thermophiles : biology and technology at high temperatures

OVERVIEW: The challenges to life at extremely high temperature Frank Robb, Garo Antranikain, Arnold Driessen, and Dennis Grogan MOLECULAR BASIS OF THERMOSTABILITY Extrinsic protein stabilization H. Santos The relationship between catalytic activity, structural flexibility and conformational stability as deduced from the analysis of mesophilic - thermophilic enzyme pairs and protein engineering studies R. Sterner and E. Bruner Membranes and membrane proteins A. J. M. Driessen and S-V. Albers Protein chaperones F. T. Robb and P. Laksanalamai Physical Properties of Membranes Composed of Tetraether Archaeal Lipids P. L-G Chong HEAT-STABLE ENZYMES AND METABOLISM Glycolysis in hyperthermophiles P. Schoenheit The industrial relevance of thermophiles and their enzymes G. Antranikian, Denitrification pathway enzymes of extremophiles S. DeVries and I. Schroder GENETICS OF THERMOPHILES DNA repair and mutagenesis M. F. White, D. T. Grogan Plasmids and cloning vectors for thermophilic archaea K. M. Stedman Genetic analysis in extremely thermophilic bacteria: An overview D. W. Grogan Establishing gene function in archaea by targeted mutagenesis H. Atomi and T. Imanaka Nanobiotechnological potential of viruses of hyperthermophilic archaea. T. Basta and D. Prangishvili MINIMAL COMPLEXITY MODEL SYSTEMS Master keys to DNA replication, repair, and recombination from the structural biology of enzymes from thermophiles L. Fan, R. S. Williams, D. S. Shin, B. Chapados, and J. A. Tainer DNA replication in thermophiles J-H Shin, L. M. Kelman and Z. Kelman DNA binding proteins and DNA topology K. Sandman Structure and function of the Thermus ribosome S. T. Gregory and A. E. Dalberg Protein Phosphorylation at 80 C and Beyond P. J. Kennelly The 20S Proteasome from (Hyper)thermophilic Archaea: Model System for Protein Degradation J. K. Michel and R. M. Kelly