The phylogenetic relations of DNA-dependent RNA polymerases of archaebacteria, eukaryotes, and eubacteria

Agl24 is an ancient archaeal homolog of the eukaryotic N-glycan chitobiose synthesis enzymes

Protein N-glycosylation is a post-translational modification found in organisms of all domains of life. The crenarchaeal N-glycosylation begins with the synthesis of a lipid-linked chitobiose core structure, identical to that in Eukaryotes, although the enzyme catalyzing this reaction remains unknown. Here, we report the identification of a thermostable archaeal β-1,4-N-acetylglucosaminyltransferase, named archaeal glycosylation enzyme 24 (Agl24), responsible for the synthesis of the N-glycan chitobiose core. Biochemical characterization confirmed its function as an inverting β-D-GlcNAc-(1→4)-α-D-GlcNAc-diphosphodolichol glycosyltransferase. Substitution of a conserved histidine residue, found also in the eukaryotic and bacterial homologs, demonstrated its functional importance for Agl24. Furthermore, bioinformatics and structural modeling revealed similarities of Agl24 to the eukaryotic Alg14/13 and a distant relation to the bacterial MurG, which are catalyzing the same or a similar reaction, respectively. Phylogenetic analysis of Alg14/13 homologs indicates that they are ancient in Eukaryotes, either as a lateral transfer or inherited through eukaryogenesis.

RNA is taking its Toll: Impact of RNA-specific Toll-like receptors on health and disease

RNA-sensing Toll-like receptors (TLRs) are often described as antiviral receptors of the innate immune system. However, the past decade has shown that the function and relevance of these receptors are far more complex. They were found to be essential for the detection of various bacterial, archaeal, and eukaryotic microorganisms and facilitate the discrimination between dead and living microbes. The cytokine and interferon response profile that is triggered has the potential to improve the efficacy of next-generation vaccines and may prevent the development of asthma and allergy. Nevertheless, the ability to recognize foreign RNA comes with a cost as also damaged host cells can release nucleic acids that might induce an inappropriate immune response. Thus, it is not surprising that RNA-sensing TLRs play a key role in various autoimmune diseases. However, promising new inhibitors and antagonists are on the horizon to improve their treatment.

The archaeal legacy of eukaryotes: a phylogenomic perspective

The origin of the eukaryotic cell can be regarded as one of the hallmarks in the history of life on our planet. The apparent genomic chimerism in eukaryotic genomes is currently best explained by invoking a cellular fusion at the root of the eukaryotes that involves one archaeal and one or more bacterial components. Here, we use a phylogenomics approach to reevaluate the evolutionary affiliation between Archaea and eukaryotes, and provide further support for scenarios in which the nuclear lineage in eukaryotes emerged from within the archaeal radiation, displaying a strong phylogenetic affiliation with, or even within, the archaeal TACK superphylum. Further taxonomic sampling of archaeal genomes in this superphylum will certainly provide a better resolution in the events that have been instrumental for the emergence of the eukaryotic lineage.

Identification and characterization of small RNAs in the hyperthermophilic archaeon Sulfolobus solfataricus

The term RNA silencing (RNA interference, RNAi) describes a set of mechanisms that regulate gene expression in eukaryotes. Small interfering RNAs (siRNA) and microRNAs (miRNAs) are two major types of RNAi-associated small RNAs (smRNAs) found in most eukaryotic organisms. Despite the presence of a plethora of non-coding RNAs longer than 50-nucleotide (nt) in length in various species of Archaea, little is known about smRNAs in archaea that resemble the 20-24-nt long smRNAs found in eukaryotes, which have been implicated in the post-transcriptional control of gene expression. Here, we report the finding of a large number of smRNAs approximatelly 20-nt in length, including phased smRNAs and potential miRNAs, from the hyperthermophilic archaeon Sulfolobus solfataricus p2 (Ssp2) based on deep sequencing. The expression of some of the miRNA candidates in Ssp2 was confirmed. Consistent with the Ssp2 hyperthermophilic properties, we found that higher temperatures more efficiently induced the production of the miRNA candidates in an in vitro system using the putative foldback precursor transcripts incubated with Ssp2 extract. Although we initially predicted putative target genes of some miRNA candidates, further analysis mapped the cleavage sites downstream of the miRNA candidate complementary regions, similar to those involved in plant miRNA-mediated TAS transcript cleavage. We also identified smRNAs from clustered, regularly interspaced, short palindromic repeat (CRISPR) loci, which play important roles in prokaryotic microbial defense systems. Archaea represent a unique life form next to Bacteria and Eukarya, and our results may provide a useful resource for further in-depth study on the regulation and evolution of smRNAs in this special organism.

Active-site remodelling in the bifunctional fructose-1,6-bisphosphate aldolase/phosphatase

Fructose-1,6-bisphosphate (FBP) aldolase/phosphatase is a bifunctional, thermostable enzyme that catalyses two subsequent steps in gluconeogenesis in most archaea and in deeply branching bacterial lineages. It mediates the aldol condensation of heat-labile dihydroxyacetone phosphate (DHAP) and glyceraldehyde-3-phosphate (GAP) to FBP, as well as the subsequent, irreversible hydrolysis of the product to yield the stable fructose-6-phosphate (F6P) and inorganic phosphate; no reaction intermediates are released. Here we present a series of structural snapshots of the reaction that reveal a substantial remodelling of the active site through the movement of loop regions that create different catalytic functionalities at the same location. We have solved the three-dimensional structures of FBP aldolase/phosphatase from thermophilic Thermoproteus neutrophilus in a ligand-free state as well as in complex with the substrates DHAP and FBP and the product F6P to resolutions up to 1.3 Å. In conjunction with mutagenesis data, this pinpoints the residues required for the two reaction steps and shows that the sequential binding of additional Mg(2+) cations reversibly facilitates the reaction. FBP aldolase/phosphatase is an ancestral gluconeogenic enzyme optimized for high ambient temperatures, and our work resolves how consecutive structural rearrangements reorganize the catalytic centre of the protein to carry out two canonical reactions in a very non-canonical type of bifunctionality.

Potential coexistence of both bacterial and eukaryotic small RNA biogenesis and functional related protein homologs in Archaea

RNA silencing plays crucial roles in both bacteria and eukaryotes, yet its machinery appears to differ in these two kingdoms. A couple of Argonaute protein homologs have been reported in some archaeal species in recent years. As Argonaute protein is the key component of eukaryotic RNA silencing pathways, such findings suggested the possibility of existence of eukaryotic RNA silencing like pathways in Archaea, which present the life forms between prokaryotes and eukaryotes. To further explore such hypothesis, we systematically screened 71 fully sequenced archaeal genomes, and identified some proteins containing homologous regions to the functional domains of eukaryotic RNA silencing pathway key proteins. The phylogenetic relationships of these proteins were analyzed. The conserved functional amino acids between archaeal and eukaryotic Piwi domains suggested their functional similarity. Our results provide new clues to the evolution of RNA silencing pathways.

Examining Ancient Inter-domain Horizontal Gene Transfer

Details of the genomic changes that occurred in the ancestors of Eukarya, Archaea and Bacteria are elusive. Ancient interdomain horizontal gene transfer (IDHGT) amongst the ancestors of these three domains has been difficult to detect and analyze because of the extreme degree of divergence of genes in these three domains and because most evidence for such events are poorly supported. In addition, many researchers have suggested that the prevalence of IDHGT events early in the evolution of life would most likely obscure the patterns of divergence of major groups of organisms let alone allow the tracking of horizontal transfer at this level. In order to approach this problem, we mined the E. coli genome for genes with distinct paralogs. Using the 1,268 E. coli K-12 genes with 40% or higher similarity level to a paralog elsewhere in the E. coli genome we detected 95 genes found exclusively in Bacteria and Archaea and 86 genes found in Bacteria and Eukarya. These genes form the basis for our analysis of IDHGT. We also applied a newly developed statistical test (the node height test), to examine the robustness of these inferences and to corroborate the phylogenetically identified cases of ancient IDHGT. Our results suggest that ancient inter domain HGT is restricted to special cases, mostly involving symbiosis in eukaryotes and specific adaptations in prokaryotes. Only three genes in the Bacteria + Eukarya class (Deoxyxylulose-5-phosphate synthase (DXPS), fructose 1,6-phosphate aldolase class II protein and glucosamine-6-phosphate deaminase) and three genes–in the Bacteria + Archaea class (ABC-type FE3+ -siderophore transport system, ferrous iron transport protein B, and dipeptide transport protein) showed evidence of ancient IDHGT. However, we conclude that robust estimates of IDHGT will be very difficult to obtain due to the methodological limitations and the extreme sequence saturation of the genes suspected of being involved in IDHGT.

A multistep process gave rise to RNA polymerase IV of land plants

Since their discovery in Metazoa, the three nuclear RNA polymerases (RNAPs) have been found in fungi, plants, and diverse protists. In all eukaryotes studied to date, RNAPs I, II, and III collectively transcribe all major RNAs made in the nucleus. We have found genes for the largest subunit (RPD1/RPE1) of a new DNA-dependent RNAP, RNAP IV, in all major land plant taxa and in closely related green algae. Genes for the second-largest subunit (RPD2) of this enzyme were found in all land plants. Phylogenetic study indicates that RNAP IV genes are sister to the corresponding RNAP II genes. Our results show the genesis of RNAP IV to be a multistep process in which the largest and second-largest subunit genes evolved by independent duplication events in the ancestors of Charales and land plants. These findings provide insights into evolutionary mechanisms that can explain the origin of multiple RNAPs in the eukaryotic nucleus.

Predicted highly expressed genes in archaeal genomes

Based primarily on 16S rRNA sequence comparisons, life has been broadly divided into the three domains of Bacteria, Archaea, and Eukarya. Archaea is further classified into Crenarchaea and Euryarchaea. Archaea generally thrive in extreme environments as assessed by temperature, pH, and salinity. For many prokaryotic organisms, ribosomal proteins (RP), transcription/translation factors, and chaperone genes tend to be highly expressed. A gene is predicted highly expressed (PHX) if its codon usage is rather similar to the average codon usage of at least one of the RP, transcription/translation factors, and chaperone gene classes and deviates strongly from the average gene of the genome. The thermosome (Ths) chaperonin family represents the most salient PHX genes among Archaea. The chaperones Trigger factor and HSP70 have overlapping functions in the folding process, but both of these proteins are lacking in most archaea where they may be substituted by the chaperone prefoldin. Other distinctive PHX proteins of Archaea, absent from Bacteria, include the proliferating cell nuclear antigen PCNA, a replication auxiliary factor responsible for tethering the catalytic unit of DNA polymerase to DNA during high-speed replication, and the acidic RP P0, which helps to initiate mRNA translation at the ribosome. Other PHX genes feature Cell division control protein 48 (Cdc48), whereas the bacterial septation proteins FtsZ and minD are lacking in Crenarchaea. RadA is a major DNA repair and recombination protein of Archaea. Archaeal genomes feature a strong Shine-Dalgarno ribosome-binding motif more pronounced in Euryarchaea compared with Crenarchaea.

Evolution of eukaryotic transcription: insights from the genome of Giardia lamblia

The Giardia lamblia genome sequencing project affords us a unique opportunity to conduct comparative analyses of core cellular systems between early and late-diverging eukaryotes on a genome-wide scale. We report a survey to identify canonical transcription components in Giardia, focusing on RNA polymerase (RNAP) subunits and transcription-initiation factors. Our survey revealed that Giardia contains homologs to 21 of the 28 polypeptides comprising eukaryal RNAPI, RNAPII, and RNAPIII; six of the seven RNAP subunits without giardial homologs are polymerase specific. Components of only four of the 12 general transcription initiation factors have giardial homologs. Surprisingly, giardial TATA-binding protein (TBP) is highly divergent with respect to archaeal and higher eukaryotic TBPs, and a giardial homolog of transcription factor IIB was not identified. We conclude that Giardia represents a transition during the evolution of eukaryal transcription systems, exhibiting a relatively complete set of RNAP subunits and a rudimentary basal initiation apparatus for each transcription system. Most class-specific RNAP subunits and basal initiation factors appear to have evolved after the divergence of Giardia from the main eukaryotic line of descent. Consequently, Giardia is predicted to be unique in many aspects of transcription initiation with respect to paradigms derived from studies in crown eukaryotes.

The sequence of the largest subunit of RNA polymerase II is a useful marker for inferring seed plant phylogeny

We used RT-PCR to sequence approximately 3 kb of the gene coding for the largest subunit of RNA polymerase II (rpb1) from nine land plants. Our results show that plant rpb1 genes all have a similar GC-content and that their amino acid sequences evolve at a similar rate in most species we examined, except for the Arabidopsis thaliana and rice sequences which evolve faster. This gene also exists as a single copy in most species and contains enough phylogenetically informative sites to resolve the evolutionary relationships among seed plants. Protein maximum parsimony, as well as neighbor-joining and maximum likelihood analyses of DNA and protein sequences, all generated identical tree topologies with similar strong support values at each node. The angiosperms are a clade comprising Amborella as a sister group to all other angiosperms, followed by Nymphaea, Magnolia, Arabidopsis, and a monocot clade containing maize and rice. The gymnosperms also form a monophyletic clade with Welwitschia and pine grouped together and sister to a Cycas and Zamia clade. These findings concur with recent studies that refute the Anthophyte Hypothesis and place Amborella at the base of the angiosperm tree. These rpb1 sequences also give a more consistent picture of seed plant relationships than similar analyses performed on data sets made of 18S rDNA, atpB, and rbcL sequences from the same species. These sequences therefore show great promise to help further resolve the phylogenetic relationships of seed plants.

Heterogeneity of genome and proteome content in bacteria, archaea, and eukaryotes

Our analysis compares bacteria, archaea, and eukaryota with respect to a wide assortment of genome and proteome properties. These properties include ribosomal protein gene distributions, chaperone protein contrasts, major variation of transcription/translation factors, gene encoding pathways of energy metabolism, and predicted protein expression levels. Significant differences within and between the three domains of life include protein lengths, information processing procedures, many metabolic and lipid biosynthesis pathways, cellular controls, and regulatory proteins. Differences among genomes are influenced by lifestyle, habitat, physiology, energy sources, and other factors.

Transcriptional regulation of genes encoding the selenium-free [NiFe]-hydrogenases in the archaeon Methanococcus voltae involves positive and negative control elements

Methanococcus voltae harbors genetic information for two pairs of homologous [NiFe]-hydrogenases. Two of the enzymes contain selenocysteine, while the other two gene groups encode apparent isoenzymes that carry cysteinyl residues in the homologous positions. The genes coding for the selenium-free enzymes, frc and vhc, are expressed only under selenium limitation. They are transcribed out of a common intergenic region. A series of deletions made in the intergenic region localized a common negative regulatory element for the vhc and frc promoters as well as two activator elements that are specific for each of the two transcription units. Repeated sequences, partially overlapping the frc promoter, were also detected. Mutations in these repeated heptanucleotide sequences led to a weak induction of a reporter gene under the control of the frc promoters in the presence of selenium. This result suggests that the heptamer repeats contribute to the negative regulation of the frc transcription unit.

Comparative Genomics of the Archaea (Euryarchaeota): Evolution of Conserved Protein Families, the Stable Core, and the Variable Shell

Comparative analysis of the protein sequences encoded in the four euryarchaeal species whose genomes have been sequenced completely (Methanococcus jannaschii, Methanobacterium thermoautotrophicum, Archaeoglobus fulgidus, andPyrococcus horikoshii) revealed 1326 orthologous sets, of which 543 are represented in all four species. The proteins that belong to these conserved euryarchaeal families comprise 31%–35% of the gene complement and may be considered the evolutionarily stable core of the archaeal genomes. The core gene set includes the great majority of genes coding for proteins involved in genome replication and expression, but only a relatively small subset of metabolic functions. For many gene families that are conserved in all euryarchaea, previously undetected orthologs in bacteria and eukaryotes were identified. A number of euryarchaeal synapomorphies (unique shared characters) were identified; these are protein families that possess sequence signatures or domain architectures that are conserved in all euryarchaea but are not found in bacteria or eukaryotes. In addition, euryarchaea-specific expansions of several protein and domain families were detected. In terms of their apparent phylogenetic affinities, the archaeal protein families split into bacterial and eukaryotic families. The majority of the proteins that have only eukaryotic orthologs or show the greatest similarity to their eukaryotic counterparts belong to the core set. The families of euryarchaeal genes that are conserved in only two or three species constitute a relatively mobile component of the genomes whose evolution should have involved multiple events of lineage-specific gene loss and horizontal gene transfer. Frequently these proteins have detectable orthologs only in bacteria or show the greatest similarity to the bacterial homologs, which might suggest a significant role of horizontal gene transfer from bacteria in the evolution of the euryarchaeota.

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.

Polyphasic taxonomy, a consensus approach to bacterial systematics

Over the last 25 years, a much broader range of taxonomic studies of bacteria has gradually replaced the former reliance upon morphological, physiological, and biochemical characterization. This polyphasic taxonomy takes into account all available phenotypic and genotypic data and integrates them in a consensus type of classification, framed in a general phylogeny derived from 16S rRNA sequence analysis. In some cases, the consensus classification is a compromise containing a minimum of contradictions. It is thought that the more parameters that will become available in the future, the more polyphasic classification will gain stability. In this review, the practice of polyphasic taxonomy is discussed for four groups of bacteria chosen for their relevance, complexity, or both: the genera Xanthomonas and Campylobacter, the lactic acid bacteria, and the family Comamonadaceae. An evaluation of our present insights, the conclusions derived from it, and the perspectives of polyphasic taxonomy are discussed, emphasizing the keystone role of the species. Taxonomists did not succeed in standardizing species delimitation by using percent DNA hybridization values. Together with the absence of another "gold standard" for species definition, this has an enormous repercussion on bacterial taxonomy. This problem is faced in polyphasic taxonomy, which does not depend on a theory, a hypothesis, or a set of rules, presenting a pragmatic approach to a consensus type of taxonomy, integrating all available data maximally. In the future, polyphasic taxonomy will have to cope with (i) enormous amounts of data, (ii) large numbers of strains, and (iii) data fusion (data aggregation), which will demand efficient and centralized data storage. In the future, taxonomic studies will require collaborative efforts by specialized laboratories even more than now is the case. Whether these future developments will guarantee a more stable consensus classification remains an open question.

Characterization of the distal promoter element of halobacteria in vivo using saturation mutagenesis and selection

The sequence and spacing requirements of the archaeal "distal promoter element' (DPE) were examined by randomizing positions -19 to -32 upstream of the transcriptional start site of the ferredoxin (fdx) promoter of Halobacterium salinarium. This randomized promoter library containing 4(14) entries was cloned in front of the dihydrofolate reductase (DHFR) reporter gene and transformed into Haloferax volcanii. Two approaches were used to characterize these synthetic promoters. First, 1040 independent clones were randomly chosen and their degrees of trimethoprim resistance were determined. The sequences of 20 clones that were either sensitive, partially resistant or very resistant, respectively, were determined. Secondly, the transformed library was screened by direct selection for high-activity promoters by growing transformants in the presence of trimethoprim. Both approaches produced the following consensus sequence for a halobacterial promoter: (Formula: see text) (where R = A or G; Y = C or T; W = A or T; S = G or C; N = A, C, G or T). Further characterization of two sensitive, two partially resistant, and two very resistant clones verified that DHFR activity and cell phenotype are directly correlated. Sensitive clones did not contain detectable dhfr mRNA, whereas partially resistant clones contained a 700 nucleotide (nt)-long transcript, and very resistant clones contained both the 700nt-long transcript and a second, more abundant, 500nt-long truncated transcript. Quantification of the dhfr mRNA and DHFR enzyme activity suggests that the 3'-untranslated region of the dhfr transcript, missing from the shorter transcript, functions as a negative regulator of translation.

Exobiology, the study of the origin, evolution and distribution of life within the context of cosmic evolution: a review

The primary goal of exobiological research is to reach a better understanding of the processes leading to the origin, evolution and distribution of life on Earth or elsewhere in the universe. In this endeavour, scientists from a wide variety of disciplines are involved, such as astronomy, planetary research, organic chemistry, palaeontology and the various subdisciplines of biology including microbial ecology and molecular biology. Space technology plays an important part by offering the opportunity for exploring our solar system, for collecting extraterrestrial samples, and for utilizing the peculiar environment of space as a tool. Exobiological activities include comparison of the overall pattern of chemical evolution of potential precursors of life, in the interstellar medium, and on the planets and small bodies of our solar system; tracing the history of life on Earth back to its roots; deciphering the environments of the planets in our solar system and of their satellites, throughout their history, with regard to their habitability; searching for other planetary systems in our Galaxy and for signals of extraterrestrial civilizations; testing the impact of space environment on survivability of resistant life forms. This evolutionary approach towards understanding the phenomenon of life in the context of cosmic evolution may eventually contribute to a better understanding of the processes regulating the interactions of life with its environment on Earth.

Apparent functional independence of the mitochondrial and nuclear transcription systems in cultured human cells

We have constructed a series of reporter constructs which test the effects of sequence elements from the control region of human mitochondrial DNA on expression in the nucleus, as assayed by transient expression in cultured human cells. The mitochondrial heavy-strand promoter (HSP) was unable to function as a promoter in nuclear DNA. Neither the HSP, nor the binding region for the mitochondrial transcription factor mtTF1 from the light-strand promoter, had any significant or systematic modulatory effects upon transcription from strong or weak RNA polymerase II (pol II) promoters, in three different human cell lines. The same finding held true regardless of orientation with respect to the start site of transcription. Similar results were obtained with a rho 0 derivative of one of these lines, indicating that mitochondrial promoter sequences in the nucleus cannot modulate transcription in response to altered mtDNA copy number. These results support the view that the nuclear and mitochondrial transcription systems in human cells are functionally independent, and do not communicate through factors recognizing shared sequence elements, as suggested by studies in yeast.

DNA-dependent RNA polymerase subunit B as a tool for phylogenetic reconstructions: branching topology of the archaeal domain

The branching topology of the archaeal (archaebacterial) domain was inferred from sequence comparisons of the largest subunit (B) of DNA-dependent RNA polymerases (RNAP). Both the nucleic acid sequences of the genes coding for RNAP subunit B and the amino acid sequences of the derived gene products were used for phylogenetic reconstructions. Individual analysis of the three nucleotide positions of codons revealed significant inequalities with respect to guanosine and cytosine (GC) content and evolutionary rates. Only the nucleotides at the second codon positions were found to be unbiased by varied GC contents and sufficiently conserved for reliable phylogenetic reconstructions. A decision matrix was used for the combination of the results of distance matrix, maximum parsimony, and maximum likelihood methods. For this purpose the original results (sums of squares, steps, and logarithms of likelihoods) were transformed into comparable effective values and analyzed with methods known from the theory of statistical decisions. Phylogenetic invariants and statistical analysis with resampling techniques (bootstrap and jackknife) confirmed the preferred branching topology, which is significantly different from the topology known from phylogenetic trees based on 16S rRNA sequences. The preferred topology reconstructed by this analysis shows a common stem for the Methanococcales and Methanobacteriales and a separation of the thermophilic sulfur archaea from the methanogens and halophiles. The latter coincides with a unique phylogenetic location of a characteristic splitting event replacing the largest RNAP subunit of thermophilic sulfur archaea by two fragments in methanogens and halophiles. This topology is in good agreement with physiological and structural differences between the various archaea and demonstrates RNAP to be a suitable phylogenetic marker molecule.

Phylogenetic relationships of Bacteria based on comparative sequence analysis of elongation factor Tu and ATP-synthase beta-subunit genes

Comparative sequence analyses were performed on 14 genes encoding bacterial elongation factors EF-Tu and 7 genes encoding the beta-subunit of bacterial F1F0 type ATP-synthases. The corresponding predicted amino acid sequences were compared with published primary structures of homologous molecules. Phylogenetic trees were reconstructed from both data sets of aligned protein sequences and from an equivalent selection of 16S rRNA sequences by applying distance matrix and maximum parsimony methods. The EF-Tu data were in very good agreement with the rRNA data, although the resolution within the EF-Tu tree was reduced at certain phylogenetic levels. The resolution power of the ATPase beta-subunit sequence data were more reduced than those of the EF-Tu data. In comparison with the 16S rRNA tree there are minor differences in the order of adjacent branchings within the ATPase beta-subunit tree.

Transcription of the ileS operon in the archaeon Methanobacterium thermoautotrophicum Marburg

In the thermophilic archaeon Methanobacterium thermoautotrophicum Marburg, the structural gene for isoleucyl-tRNA synthetase (ileS) is flanked upstream by orf401 and downstream by purL. orf401 encodes a 43.5-kDa protein with an unknown function. Northern (RNA) hybridization and S1 nuclease protection experiments showed that the orf401, ileS, and purL genes are cotranscribed from an archael consensus promoter in front of orf401. The corresponding transcript was about eightfold increased in cells that had been exposed to pseudomonic acid A, a specific inhibitor of isoleucyl-tRNA synthetase. Growth inhibition by puromycin, tryptophan starvation, or starvation for hydrogen did not affect the level of this transcript. The level of a trpE transcript, however, was drastically elevated upon tryptophan starvation, while inhibition by pseudomonic acid A had no effect on the level of this transcript. Expression of ileS thus appears to be controlled by a regulatory mechanism which specifically responds to the availability of isoleucyl-tRNA. Extensive decay of the orf401-ileS-purL message was observed. Degradation occurred, presumably by endonucleolytic cleavage, within the orf401 region.

Ether polar lipids of methanogenic bacteria: structures, comparative aspects, and biosyntheses

Complete structures of nearly 40 ether polar lipids from seven species of methanogens have been elucidated during the past 10 years. Three kinds of variations of core lipids, macrocyclic archaeol and two hydroxyarchaeols, were identified, in addition to the usual archaeol and caldarchaeol (for the nomenclature of archaeal [archaebacterial] ether lipids, see the text). Polar head groups of methanogen phospholipids include ethanolamine, serine, inositol, N-acetylglucosamine, dimethyl- and trimethylaminopentanetetrol, and glucosaminylinositol. Glucose is the sole hexose moiety of glycolipids in most methanogens, and galactose and mannose have been found in a few species. Methanogen lipids are characterized by their diversity in phosphate-containing polar head groups and core lipids, which in turn can be used for chemotaxonomy of methanogens. This was shown by preliminary simplified analyses of lipid component residues. Core lipid analysis by high-pressure liquid chromatography provides a method of determining the methanogenic biomass in natural samples. There has been significant progress in the biosynthetic studies of methanogen lipids in recent years. In vivo incorporation experiments have led to delineation of the outline of the synthetic route of the diphytanylglycerol ether core. The mechanisms of biosynthesis of tetraether lipids and various polar lipids, and cell-free systems of either lipid synthesis, however, remain to be elucidated. The significance and the origin of archaeal ether lipids is discussed in terms of the lipid composition of bacteria living in a wide variety of environments, the oxygen requirement for biosynthesis of hydrocarbon chains, and the physicochemical properties and functions of lipids as membrane constituents.

TGA cysteine codons and intron sequences in conserved and nonconserved positions are found in macronuclear RNA polymerase genes of Euplotes octocarinatus

The gene sequences of the second largest subunits of RNA polymerases I and II of Euplotes octocarinatus, RPA2 and RPB2, were determined and compared to the respective known sequences of Saccharomyces cerevisiae. The similarity of the derived polypeptide sequences permitted their assignment to the respective polymerases and allowed the comparison of the zinc binding regions. In frame TGA codons were detected, which are likely to encode conserved cysteinyl residues in the putative zinc-finger region of the RPA2 gene. They were also found in other positions in both the RPA2 and RPB2 genes. The RPB2 gene contains a 30 bp intron close to the 5'-end of its coding region. The 5'-ends of the coding regions of all three genes encoding the largest subunits of the three different polymerases were also analyzed. The zinc finger structures again show the use of TGA codons for conserved cysteinyl residues in two of the genes. An N-terminal intron is located in the RPB1 gene at a conserved position as compared to the respective genes of several other eucarya.

The immunity-conferring plasmid p phi HL from the Halobacterium salinarium phage phi H: nucleotide sequence and transcription

The complete nucleotide sequence of the plasmid p phi HL, composing the central 12,041-bp L-region from the temperate phage phi H of Halobacterium salinarium is presented. Transcripts mapped to the p phi HL and the L-region produced under immune conditions, under lytic growth or constitutively, are described. The sequences upstream of the transcription start points show homology to the consensus sequence for archaeal (formerly archaebacterial) promoters. Lytic transcription is shown to be strictly time-dependent, with an early gene product required for the expression of late genes.

Methanococcus voltae harbors four gene clusters potentially encoding two [NiFe] and two [NiFeSe] hydrogenases, each of the cofactor F420-reducing or F420-non-reducing types

Four gene clusters were identified in Methanococcus voltae which probably all encode hydrogenases of the [NiFe] type. One of these contains four genes, including those for the three subunits of the known [NiFeSe] hydrogenase capable of reducing the natural deazaflavin cofactor F420. In a second homologous cluster, the gene encoding the subunit corresponding to that which contains selenium in the known enzyme has a cysteine codon in the relevant position. In addition, two more gene clusters were detected which are very similar both in gene order and sequence to one which encodes a hydrogenase that reduces viologens in Methanobacterium thermoautotrophicum, but whose natural electron acceptor is as yet unknown. Again, in one of these clusters, one of the structural genes, which codes for a hydrogenase subunit containing the putative Ni-binding site, contains a selenocysteine codon. The homologous gene in the other clusters again shows a cysteine codon in the corresponding location. The four gene clusters are closely linked. Those encoding the two selenium-free enzymes are arranged in opposite polarities with a relatively short intergenic region. This arrangement is discussed in terms of a possible joint transcriptional regulation.

Component H of the DNA-dependent RNA polymerases of Archaea is homologous to a subunit shared by the three eucaryal nuclear RNA polymerases

The gene encoding component H of the DNA-dependent RNA polymerase (RNAP, EC 2.7.7.6) of Sulfolobus acidocaldarius has been identified by comparison of the amino acid sequence with the derived amino acid sequence of an open reading frame (ORF88) in the RNAP operon. Corresponding genes were identified in Halobacterium halobium and were cloned and sequenced from Thermococcus celer and Methanococcus vannielii. All these rpoH genes are situated between the promoters of the RNAP operons and the corresponding rpoB and rpoB2 genes. The archaeal H subunits show high sequence similarity to each other and to the C-terminal portions of the largest of four subunits shared by all three specialized nuclear RNAPs. These correlations are further evidence for the striking similarity between archaeal and eucaryal RNAP structures and transcription systems.

Evolutionary relationships among eubacteria, cyanobacteria, and chloroplasts: evidence from the rpoC1 gene of Anabaena sp. strain PCC 7120

RNA polymerases of cyanobacteria contain a novel core subunit, gamma, which is absent from the RNA polymerases of other eubacteria. The genes encoding the three largest subunits of RNA polymerase, including gamma, have been isolated from the cyanobacterium Anabaena sp. strain PCC 7120. The genes are linked in the order rpoB, rpoC1, rpoC2 and encode the beta, gamma, and beta' subunits, respectively. These genes are analogous to the rpoBC operon of Escherichia coli, but the functions of rpoC have been split in Anabaena between two genes, rpoC1 and rpoC2. The DNA sequence of the rpoC1 gene was determined and shows that the gamma subunit corresponds to the amino-terminal half of the E. coli beta' subunit. The gamma protein contains several conserved domains found in the largest subunits of all bacterial and eukaryotic RNA polymerases, including a potential zinc finger motif. The spliced rpoC1 gene from spinach chloroplast DNA was expressed in E. coli and shown to encode a protein immunologically related to Anabaena gamma. The similarities in the RNA polymerase gene products and gene organizations between cyanobacteria and chloroplasts support the cyanobacterial origin of chloroplasts and a divergent evolutionary pathway among eubacteria.

Gene cluster rpoBC1C2 in cyanobacteria does not constitute an operon

The core enzyme of the cyanobacterial DNA-dependent RNA polymerase contains a unique component, gamma, which is absent from the corresponding enzymes of other eubacteria. In the heterocystous cyanobacterium Nostoc commune the gene encoding gamma, rpoC1, is immediately adjacent to, and downstream of, rpoB. The rpoC1 gene, and a 3' adjacent gene, rpoC2, correspond to the single rpoC gene found in Escherichia coli with respect to those domains conserved within their translational products. Northern analysis and primer extension assay show that in N. commune, rpoC1 and rpoC2 are transcribed separately from rpoB. The promoter of rpoC1C2 can direct the expression of a promotorless lacZ gene in E. coli. As a consequence, cyanobacterial rpo gene expression is distinct from the mode of cotranscription described for the equivalent sequences found in other eubacteria, archaebacteria, and plant chloroplasts. Also in this paper, a simple protocol for RNA isolation, which should be applicable for RNA isolation from plant cells, is presented.

Phylogenetic analysis of the RNA polymerases of Trypanosoma brucei, with special reference to class-specific transcription

We have sequenced the genes encoding to largest subunits of the three classes of DNA-dependent RNA polymerases of Trypanosoma brucei. The nucleotide and deduced amino acid sequences were compared and aligned with the corresponding sequences of other eukaryotes. Phylogenetic relationships were subsequently calculated with a distant matrix, a bootstrapped parsimony and a maximum-likelihood method. These independent calculations resulted in trees with very similar topologies. The analyses show that all the largest subunits of T. brucei are evolutionarily distant members within each of the three RNA polymerase classes. An early separation of the trypanosomal subunits from the eukaryotic lineage might form the fundamental basis for the unusual transcription process of this species. Finally, all dendrograms show a separate ramification for the largest subunit of RNA polymerase I, II and III. RNA polymerase II and/or III form a bifurcation with the archaebacterial lineage, RNA polymerase I, however, arises separately from the eubacterial beta' lineage. This suggests that the three eukaryotic RNA polymerase classes are not simply derived by two gene duplications of an ancestral gene with subsequent differentiation.

Organization and expression of the 16S, 23S and 5S ribosomal RNA genes from the archaebacterium Thermoplasma acidophilum

To elucidate the organization of the transcription units encoding the 16S, 23S and 5S rRNAs in the archaebacterium Thermoplasma acidophilum, the nucleotide sequences flanking the three rRNA genes were determined, and the 5' and 3' termini of the rRNA transcripts were mapped by primer extension and nuclease S1 protection. The results show that each of the rRNAs is transcribed separately, consistent with the lack of physical proximity among them in the T. acidophilum genome. The transcription initiation sites are preceded at an interval of approximately 25 base pairs by conserved A + T-rich sequences of the form CTTATATA, which strongly resemble the archaebacterial promoter consensus, TTTAT/AATA. In all three cases, transcription termination occurs within T-rich tracts just downstream from inverted repeats which can be folded into relatively stable stem-loop structures. While no partially processed intermediates of the 16S or 5S rRNA transcripts were detected, the 23S rRNA transcript appears to be processed by a RNase III-like activity prior to final maturation. This is the only organism known in the prokaryotic world in which the 16S, 23S and 5S rRNAs are all expressed from separate transcription units.

Hyperthermus butylicus, a hyperthermophilic sulfur-reducing archaebacterium that ferments peptides

The hyperthermophilic peptide-fermenting sulfur archaebacterium Hyperthermus butylicus was isolated from the sea floor of a solfataric habitat with temperatures of up to 112 degrees C on the coast of the island of São Miguel, Azores. The organism grows at up to 108 degrees C, grows optimally between 95 and 106 degrees C at 17 g of NaCl per liter and pH 7.0, utilizes peptide mixtures as carbon and energy sources, and forms H2S from elemental sulfur and molecular hydrogen as a growth-stimulating accessory energy source but not by sulfur respiration. The same fermentation products, CO2, 1-butanol, acetic acid, phenylacetic acid, and a trace of hydroxyphenylacetic acid, are formed both with and without of S0 and H2. Its ether lipids, the absence of a mureine sacculus, the nature of the DNA-dependent RNA polymerase, and phylogenetic classification by DNA-rRNA cross-hybridization characterize H. butylicus as part of a novel genus of the major branch of archaebacteria comprising the orders Thermoproteales and Sulfolobales, representing a particularly long lineage bifurcating with the order Sulfolobales above the branching off of the genus Thermoproteus and distinct from the genera Desulfurococcus and Pyrodictium.

Specific transcription of cloned Methanobacterium thermoautotrophicum transcription units by homologous RNA polymerase in vitro

Specific in vitro transcription by partially purified RNA polymerase from Methanobacterium thermoautotrophicum of DNA sequences cloned in between the promoter and terminator regions of the methyl CoM reductase transcription unit of the same organism is described. The 5'-terminus of the product has been mapped. Deletion analyses of the promoter region show the limits of the sequences essential for the promoter function.