Control regions of an archaeal gene. A TATA box and an initiator element promote cell-free transcription of the tRNA(Val) gene of Methanococcus vannielii

Tuning Gene Expression by Phosphate in the Methanogenic Archaeon Methanococcus maripaludis

Methanococcus maripaludis is a rapidly growing, hydrogenotrophic, and genetically tractable methanogen with unique capabilities to convert formate and CO₂ to CH₄. The existence of genome-scale metabolic models and an established, robust system for both large-scale and continuous cultivation make it amenable for industrial applications. However, the lack of molecular tools for differential gene expression has hindered its application as a microbial cell factory to produce biocatalysts and biochemicals. In this study, a library of differentially regulated promoters was designed and characterized based on the pst promoter, which responds to the inorganic phosphate concentration in the growth medium. Gene expression increases by 4- to 6-fold when the medium phosphate drops to growth-limiting concentrations. Hence, this regulated system decouples growth from heterologous gene expression without the need for adding an inducer. The minimal pst promoter is identified and contains a conserved AT-rich region, a factor B recognition element, and a TATA box for phosphate-dependent regulation. Rational changes to the factor B recognition element and start codon had no significant impact on expression; however, changes to the transcription start site and the 5' untranslated region resulted in the differential protein production with regulation remaining intact. Compared to a previous expression system based upon the histone promoter, this regulated expression system resulted in significant improvements in the expression of a key methanogenic enzyme complex, methyl-coenzyme M reductase, and the potentially toxic arginine methyltransferase MmpX.

Characterization of promoters in archaeal genomes based on DNA structural parameters

The transcription machinery of archaea can be roughly classified as a simplified version of eukaryotic organisms. The basal transcription factor machinery binds to the TATA box found around 28 nucleotides upstream of the transcription start site; however, some transcription units lack a clear TATA box and still have TBP/TFB binding over them. This apparent absence of conserved sequences could be a consequence of sequence divergence associated with the upstream region, operon, and gene organization. Furthermore, earlier studies have found that a structural analysis gains more information compared with a simple sequence inspection. In this work, we evaluated and coded 3630 archaeal promoter sequences of three organisms, Haloferax volcanii, Thermococcus kodakarensis, and Sulfolobus solfataricus into DNA duplex stability, enthalpy, curvature, and bendability parameters. We also split our dataset into conserved TATA and degenerated TATA promoters to identify differences among these two classes of promoters. The structural analysis reveals variations in archaeal promoter architecture, that is, a distinctive signal is observed in the TFB, TBP, and TFE binding sites independently of these being TATA-conserved or TATA-degenerated. In addition, the promoter encountering method was validated with upstream regions of 13 other archaea, suggesting that there might be promoter sequences among them. Therefore, we suggest a novel method for locating promoters within the genome of archaea based on DNA energetic/structural features.

Next Generation DNA-Seq and Differential RNA-Seq Allow Re-annotation of the Pyrococcus furiosus DSM 3638 Genome and Provide Insights Into Archaeal Antisense Transcription

Pyrococcus furiosus DSM 3638 is a model organism for hyperthermophilic archaea with an optimal growth temperature near 100°C. The genome was sequenced about 18 years ago. However, some publications suggest that in contrast to other Pyrococcus species, the genome of P. furiosus DSM 3638 is prone to genomic rearrangements. Therefore, we re-sequenced the genome using third generation sequencing techniques. The new de novo assembled genome is 1,889,914 bp in size and exhibits high sequence identity to the published sequence. However, two major deviations were detected: (1) The genome is 18,342 bp smaller than the NCBI reference genome due to a recently described deletion. (2) The region between PF0349 and PF0388 is inverted most likely due an assembly problem for the original sequence. In addition, numerous minor variations, ranging from single nucleotide exchanges, deletions or insertions were identified. The total number of insertion sequence (IS) elements is also reduced from 30 to 24 in the new sequence. Re-sequencing of a 2-year-old “lab culture” using Nanopore sequencing confirmed the overall stability of the P. furiosus DSM 3638 genome even under normal lab conditions without taking any special care. To improve genome annotation, the updated DNA sequence was combined with an RNA sequencing approach. Here, RNAs from eight different growth conditions were pooled to increase the number of detected transcripts. Furthermore, a differential RNA-Seq approach was employed for the identification of transcription start sites (TSSs). In total, 2515 TSSs were detected and classified into 834 primary (pTSS), 797 antisense (aTSS), 739 internal and 145 secondary TSSs. Our analysis of the upstream regions revealed a well conserved archaeal promoter structure. Interrogation of the distances between pTSSs and aTSSs revealed a significant number of antisense transcripts, which are a result of bidirectional transcription from the same TATA box. This mechanism of antisense transcript production could be further confirmed by in vitro transcription experiments. We assume that bidirectional transcription gives rise to non-functional antisense RNAs and that this is a widespread phenomenon in archaea due to the architecture of the TATA element and the symmetric structure of the TATA-binding protein.

Transcription initiation factor TBP: old friend new questions

In all domains of life, the regulation of transcription by DNA-dependent RNA polymerases (RNAPs) is achieved at the level of initiation to a large extent. Whereas bacterial promoters are recognized by a σ-factor bound to the RNAP, a complex set of transcription factors that recognize specific promoter elements is employed by archaeal and eukaryotic RNAPs. These initiation factors are of particular interest since the regulation of transcription critically relies on initiation rates and thus formation of pre-initiation complexes. The most conserved initiation factor is the TATA-binding protein (TBP), which is of crucial importance for all archaeal-eukaryotic transcription initiation complexes and the only factor required to achieve full rates of initiation in all three eukaryotic and the archaeal transcription systems. Recent structural, biochemical and genome-wide mapping data that focused on the archaeal and specialized RNAP I and III transcription system showed that the involvement and functional importance of TBP is divergent from the canonical role TBP plays in RNAP II transcription. Here, we review the role of TBP in the different transcription systems including a TBP-centric discussion of archaeal and eukaryotic initiation complexes. We furthermore highlight questions concerning the function of TBP that arise from these findings.

Displacement of the transcription factor B reader domain during transcription initiation

Transcription initiation by archaeal RNA polymerase (RNAP) and eukaryotic RNAP II requires the general transcription factor (TF) B/ IIB. Structural analyses of eukaryotic transcription initiation complexes locate the B-reader domain of TFIIB in close proximity to the active site of RNAP II. Here, we present the first crosslinking mapping data that describe the dynamic transitions of an archaeal TFB to provide evidence for structural rearrangements within the transcription complex during transition from initiation to early elongation phase of transcription. Using a highly specific UV-inducible crosslinking system based on the unnatural amino acid para-benzoyl-phenylalanine allowed us to analyze contacts of the Pyrococcus furiosus TFB B-reader domain with site-specific radiolabeled DNA templates in preinitiation and initially transcribing complexes. Crosslink reactions at different initiation steps demonstrate interactions of TFB with DNA at registers +6 to +14, and reduced contacts at +15, with structural transitions of the B-reader domain detected at register +10. Our data suggest that the B-reader domain of TFB interacts with nascent RNA at register +6 and +8 and it is displaced from the transcribed-strand during the transition from +9 to +10, followed by the collapse of the transcription bubble and release of TFB from register +15 onwards.

Fine-Tuned Protein Production in Methanosarcina acetivorans C2A

Methanogenic archaea can be integrated into a sustainable, carbon-neutral cycle for producing organic chemicals from C₁ compounds if the rate, yield, and titer of product synthesis can be improved using metabolic engineering. However, metabolic engineering techniques are limited in methanogens by insufficient methods for controlling cellular protein levels. We conducted a systematic approach to tune protein levels in Methanosarcina acetivorans C2A, a model methanogen, by regulating transcription and translation initiation. Rationally designed core promoter and ribosome binding site mutations in M. acetivorans C2A resulted in a predicable change in protein levels over a 60 fold range. The overall range of protein levels was increased an additional 3 fold by introducing the 5' untranslated region of the mcrB transcript. This work demonstrates a wide range of precisely controlled protein levels in M. acetivorans C2A, which will help facilitate systematic metabolic engineering efforts in methanogens.

Comparative genomic analysis of translation initiation mechanisms for genes lacking the Shine-Dalgarno sequence in prokaryotes

In prokaryotes, translation initiation is believed to occur through an interaction between the 3΄ tail of a 16S rRNA and a corresponding Shine–Dalgarno (SD) sequence in the 5΄ untranslated region (UTR) of an mRNA. However, some genes lack SD sequences (non-SD genes), and the fraction of non-SD genes in a genome varies depending on the prokaryotic species. To elucidate non-SD translation initiation mechanisms in prokaryotes from an evolutionary perspective, we statistically examined the nucleotide frequencies around the initiation codons in non-SD genes from 260 prokaryotes (235 bacteria and 25 archaea). We identified distinct nucleotide frequency biases upstream of the initiation codon in bacteria and archaea, likely because of the presence of leaderless mRNAs lacking a 5΄ UTR. Moreover, we observed overall similarities in the nucleotide patterns between upstream and downstream regions of the initiation codon in all examined phyla. Symmetric nucleotide frequency biases might facilitate translation initiation by preventing the formation of secondary structures around the initiation codon. These features are more prominent in species’ genomes that harbor large fractions of non-SD sequences, suggesting that a reduced stability around the initiation codon is important for efficient translation initiation in prokaryotes.

Global transcriptional regulator TrmB family members in prokaryotes

Members of the TrmB family act as global transcriptional regulators for the activation or repression of sugar ABC transporters and central sugar metabolic pathways, including glycolytic, gluconeogenic, and other metabolic pathways, and also as chromosomal stabilizers in archaea. As a relatively newly classified transcriptional regulator family, there is limited experimental evidence for their role in Thermococcales, halophilic archaeon Halobacterium salinarum NRC1, and crenarchaea Sulfolobus strains, despite being one of the extending protein families in archaea. Recently, the protein structures of Pyrococcus furiosus TrmB and TrmBL2 were solved, and the transcriptomic data uncovered by microarray and ChIP-Seq were published. In the present review, recent evidence of the functional roles of TrmB family members in archaea is explained and extended to bacteria.

The TrmB family: a versatile group of transcriptional regulators in Archaea

Microbes are organisms which are well adapted to their habitat. Their survival depends on the regulation of gene expression levels in response to environmental signals. The most important step in regulation of gene expression takes place at the transcriptional level. This regulation is intriguing in Archaea because the eu-karyotic-like transcription apparatus is modulated by bacterial-like transcription regulators. The transcriptional regulator of mal operon (TrmB) family is well known as a very large group of regulators in Archaea with more than 250 members to date. One special feature of these regulators is that some of them can act as repressor, some as activator and others as both repressor and activator. This review gives a short updated overview of the TrmB family and their regulatory patterns in different Archaea as a lot of new data have been published on this topic since the last review from 2008.

The Sulfolobus initiator element is an important contributor to promoter strength

Basal elements in archaeal promoters, except for putative initiator elements encompassing transcription start sites, are well characterized. Here, we employed the Sulfolobus araS promoter as a model to study the function of the initiator element (Inr) in archaea. We have provided evidence for the presence of a third core promoter element, the Sulfolobus Inr, whose action depends on a TATA box and the TFB recognition element (BRE). Substitution mutations in the araS Inr did not alter the location of the transcription start site. Using systematic mutagenesis, the most functional araS Inr was defined as +1 GAGAMK +6 (where M is A/C and K is G/T). Furthermore, WebLogo analysis of a subset of promoters with coding sequences for 5' untranslated regions (UTRs) larger than 4 nucleotides (nt) in Sulfolobus solfataricus P2 identified an Inr consensus that exactly matches the functional araS Inr sequence. Moreover, mutagenesis of 3 randomly selected promoters confirmed the Inr sequences to be important for basal promoter strength in the subgroup. Importantly, the result of the araS Inr being added to the Inr-less promoters indicates that the araS Inr, the core promoter element, is able to enhance the strength of Inr-less promoters. We infer that transcription factor B (TFB) and subunits of RNA polymerase bind the Inr to enhance promoter strength. Taken together, our data suggest that the presence or absence of an Inr on basal promoters is important for global gene regulation in Sulfolobus.

Genetic manipulation of Methanosarcina spp

The discovery of the third domain of life, the Archaea, is one of the most exciting findings of the last century. These remarkable prokaryotes are well known for their adaptations to extreme environments; however, Archaea have also conquered moderate environments. Many of the archaeal biochemical processes, such as methane production, are unique in nature and therefore of great scientific interest. Although formerly restricted to biochemical and physiological studies, sophisticated systems for genetic manipulation have been developed during the last two decades for methanogenic archaea, halophilic archaea and thermophilic, sulfur-metabolizing archaea. The availability of these tools has allowed for more complete studies of archaeal physiology and metabolism and most importantly provides the basis for the investigation of gene expression, regulation and function. In this review we provide an overview of methods for genetic manipulation of Methanosarcina spp., a group of methanogenic archaea that are key players in the global carbon cycle and which can be found in a variety of anaerobic environments.

Activation of archaeal transcription mediated by recruitment of transcription factor B

Archaeal promoters consist of a TATA box and a purine-rich adjacent upstream sequence (transcription factor B (TFB)-responsive element (BRE)), which are bound by the transcription factors TATA box-binding protein (TBP) and TFB. Currently, only a few activators of archaeal transcription have been experimentally characterized. The best studied activator, Ptr2, mediates activation by recruitment of TBP. Here, we present a detailed biochemical analysis of an archaeal transcriptional activator, PF1088, which was identified in Pyrococcus furiosus by a bioinformatic approach. Operon predictions suggested that an upstream gene, pf1089, is polycistronically transcribed with pf1088. We demonstrate that PF1088 stimulates in vitro transcription by up to 7-fold when the pf1089 promoter is used as a template. By DNase I and hydroxyl radical footprinting experiments, we show that the binding site of PF1088 is located directly upstream of the BRE of pf1089. Mutational analysis indicated that activation requires the presence of the binding site for PF1088. Furthermore, we show that activation of transcription by PF1088 is dependent upon the presence of an imperfect BRE and is abolished when the pf1089 BRE is replaced with a BRE from a strong archaeal promoter. Gel shift experiments showed that TFB recruitment to the pf1089 operon is stimulated by PF1088, and TFB seems to stabilize PF1088 operator binding even in the absence of TBP. Taken together, these results represent the first biochemical evidence for a transcriptional activator working as a TFB recruitment factor in Archaea, for which the designation TFB-RF1 is suggested.

The Bridge Helix of RNA polymerase acts as a central nanomechanical switchboard for coordinating catalysis and substrate movement

The availability of in vitro assembly systems to produce recombinant archaeal RNA polymerases (RNAPs) offers one of the most powerful experimental tools for investigating the still relatively poorly understood molecular mechanisms underlying RNAP function. Over the last few years, we pioneered new robot-based high-throughput mutagenesis approaches to study structure/function relationships within various domains surrounding the catalytic center. The Bridge Helix domain, which appears in numerous X-ray structures as a 35-amino-acid-long alpha helix, coordinates the concerted movement of several other domains during catalysis through kinking of two discrete molecular hinges. Mutations affecting these kinking mechanisms have a direct effect on the specific catalytic activity of RNAP and can in some instances more than double it. Molecular dynamics simulations have established themselves as exceptionally useful for providing additional insights and detailed models to explain the underlying structural motions.

Protein-coding gene promoters in Methanocaldococcus (Methanococcus) jannaschii

Although Methanocaldococcus (Methanococcus) jannaschii was the first archaeon to have its genome sequenced, little is known about the promoters of its protein-coding genes. To expand our knowledge, we have experimentally identified 131 promoters for 107 protein-coding genes in this genome by mapping their transcription start sites. Compared to previously identified promoters, more than half of which are from genes for stable RNAs, the protein-coding gene promoters are qualitatively similar in overall sequence pattern, but statistically different at several positions due to greater variation among their sequences. Relative binding affinity for general transcription factors was measured for 12 of these promoters by competition electrophoretic mobility shift assays. These promoters bind the factors less tightly than do most tRNA gene promoters. When a position weight matrix (PWM) was constructed from the protein gene promoters, factor binding affinities correlated with corresponding promoter PWM scores. We show that the PWM based on our data more accurately predicts promoters in the genome and transcription start sites than could be done with the previously available data. We also introduce a PWM logo, which visually displays the implications of observing a given base at a position in a sequence.

TBP domain symmetry in basal and activated archaeal transcription

The TATA box binding protein (TBP) is the platform for assembly of archaeal and eukaryotic transcription preinitiation complexes. Ancestral gene duplication and fusion events have produced the saddle-shaped TBP molecule, with its two direct-repeat subdomains and pseudo-two-fold symmetry. Collectively, eukaryotic TBPs have diverged from their present-day archaeal counterparts, which remain highly symmetrical. The similarity of the N- and C-halves of archaeal TBPs is especially pronounced in the Methanococcales and Thermoplasmatales, including complete conservation of their N- and C-terminal stirrups; along with helix H'1, the C-terminal stirrup of TBP forms the main interface with TFB/TFIIB. Here, we show that, in stark contrast to its eukaryotic counterparts, multiple substitutions in the C-terminal stirrup of Methanocaldococcus jannaschii (Mja) TBP do not completely abrogate basal transcription. Using DNA affinity cleavage, we show that, by assembling TFB through its conserved N-terminal stirrup, Mja TBP is in effect ambidextrous with regard to basal transcription. In contrast, substitutions in either its N- or the C-terminal stirrup abrogate activated transcription in response to the Lrp-family transcriptional activator Ptr2.

A whole-genome approach to identifying protein binding sites: promoters in Methanocaldococcus (Methanococcus) jannaschii

We have adapted an electrophoretic mobility shift assay (EMSA) to isolate genomic DNA fragments that bind the archaeal transcription initiation factors TATA-binding protein (TBP) and transcription factor B (TFB) to perform a genome-wide search for promoters. Mobility-shifted fragments were cloned, tested for their ability to compete with known promoter-containing fragments for a limited concentration of transcription factors, and sequenced. We applied the method to search for promoters in the genome of Methanocaldococcus jannaschii. Selection was most efficient for promoters of tRNA genes and genes for several presumed small non-coding RNAs (ncRNA). Protein-coding gene promoters were dramatically underrepresented relative to their frequency in the genome. The repeated isolation of these genomic regions was partially rectified by including a hybridization-based screening. Sequence alignment of the affinity-selected promoters revealed previously identified TATA box, BRE, and the putative initiator element. In addition, the conserved bases immediately upstream and downstream of the BRE and TATA box suggest that the composition and structure of archaeal natural promoters are more complicated.

Role of the Sulfolobus shibatae viral T6 initiator in conferring promoter strength and in influencing transcription start site selection

Archaeal promoters contain a TATA-box, an adjacent upstream TFB-recognition element (BRE), and a downstream initiator (INR) region from which transcription originates. While the contribution of A-box and BRE to promoter strength is well established, the role of DNA sequences within the INR region and its vicinity on transcription efficiency and start site selection remains unclear. Here, I demonstrate using the strong Sulfolobus shibatae viral T6 promoter that either substitution of its natural sequence from -17 and beyond with plasmid DNA or introduction of point transversion mutations at +3, -2, -4, and -5 positions reduce promoter strength dramatically, whereas +1, -1, and -2 mutations influence the transcription start site. These data therefore reveal that the INR region plays a role as important as the BRE and the A-box in T6 gene transcription.

A novel archaeal regulatory protein, Sta1, activates transcription from viral promoters

While studying gene expression of the rudivirus SIRV1 in cells of its host, the hyperthermophilic crenarchaeon Sulfolobus, a novel archaeal transcriptional regulator was isolated. The 14 kDa protein, termed Sulfolobus transcription activator 1, Sta1, is encoded on the host chromosome. Its activating effect on transcription initiation from viral promoters was demonstrated in in vitro transcription experiments using a reconstituted host system containing the RNA polymerase, TATA-binding protein (TBP) and transcription factor B (TFB). Most pronounced activation was observed at low concentrations of either of the two transcription factors, TBP or TFB. Sta1 was able to bind viral promoters independently of any component of the host pre-initiation complex. Two binding sites were revealed by footprinting, one located in the core promoter region and the second ∼30 bp upstream of it. Comparative modeling, NMR and circular dichroism of Sta1 indicated that the protein contained a winged helix–turn–helix motif, most probably involved in DNA binding. This strategy of the archaeal virus to co-opt a host cell regulator to promote transcription of its genes resembles eukaryal virus–host relationships.

Global transcriptional analysis of Methanosarcina mazei strain Gö1 under different nitrogen availabilities

Certain archaeal species can fix molecular nitrogen under nitrogen limiting conditions although little is known about this process at either the genetic or molecular level. To address this on a genome-wide scale, transcriptional analysis was performed on the model methanogen Methanosarcina mazei strain Gö1 using DNA-microarrays. The genomic expression patterns for cells grown under nitrogen fixing conditions versus nitrogen sufficiency (10 mM ammonium) revealed that approximately 5% of all genes are differentially expressed. Besides a small set of genes previously known to be up-regulated under nitrogen limitation, 14 additional genes involved in nitrogen metabolism were identified plus 10 genes encoding potential transcriptional regulators, 13 genes involved in carbon metabolism, 3 genes in general stress response, 8 putative transporter genes, and an additional 21 genes with unknown function. Quantitative reverse transcriptase PCR experiments confirmed the differential expression of a subset of these genes. Promoter analysis revealed a palindromic DNA motif centered nearby the transcriptional start point for several genes up-regulated under nitrogen limitation. A bioinformatics study demonstrated the presence of this motif in the up-stream region of 52 genes genome-wide, the majority of which showed nitrogen dependent differential transcription. We therefore hypothesize that this DNA element is involved in nitrogen control in M. mazei where it may act as a binding site for a regulatory protein.

Determinants of transcription initiation by archaeal RNA polymerase

Transcription in Archaea is catalyzed by an RNA polymerase that is most similar to eukaryotic RNA polymerases both in subunit composition and in transcription initiation factor requirements. Recent studies on archaeal transcription in diverse members of this domain have contributed new details concerning the functions of promoters and transcription factors in guiding initiation by RNA polymerase, and phylogenetic arguments have allowed modeling of archaeal transcription initiation complexes by comparison with recently described models of eukaryotic and bacterial transcription initiation complexes. Important new advances in reconstitution of archaeal transcription complexes from fully recombinant components is permitting testing of hypotheses derived from and informed by these structural models, and will help bring the study of archaeal transcription to the levels of understanding currently enjoyed by bacterial and eukaryotic RNA polymerase II transcription.

Promoter architecture and response to a positive regulator of archaeal transcription

The archaeal transcription apparatus is chimeric: its core components (RNA polymerase and basal factors) closely resemble those of eukaryotic RNA polymerase II, but the putative archaeal transcriptional regulators are overwhelmingly of bacterial type. Particular interest attaches to how these bacterial-type effectors, especially activators, regulate a eukaryote-like transcription system. The hyperthermophilic archaeon Methanocaldococcus jannaschii encodes a potent transcriptional activator, Ptr2, related to the Lrp/AsnC family of bacterial regulators. Ptr2 activates rubredoxin 2 (rb2) transcription through a bipartite upstream activating site (UAS), and conveys its stimulatory effects on its cognate transcription machinery through direct recruitment of the TATA binding protein (TBP). A functional dissection of the highly constrained architecture of the rb2 promoter shows that a 'one-site' minimal UAS suffices for activation by Ptr2, and specifies the required placement of this site. The presence of such a simplified UAS upstream of the natural rubrerythrin (rbr) promoter also suffices for positive regulation by Ptr2 in vitro, and TBP recruitment remains the primary means of transcriptional activation at this promoter.

Transcriptional fidelity and proofreading in Archaea and implications for the mechanism of TFS-induced RNA cleavage

We have addressed the question whether TFS, a protein that stimulates the intrinsic cleavage activity of the archaeal RNA polymerase, is able to improve the fidelity of transcription in Methanococcus. Using non-specific transcription experiments, we could demonstrate that misincorporation of non-templated nucleotides is reduced in the presence of TFS. A more detailed analysis revealed that elongation complexes containing a misincorporated nucleotide were arrested, but could be reactivated by TFS. RNase as well as exonuclease III footprinting experiments demonstrated that this arrest was not combined with extended backtracking. Analysis of paused elongation complexes demonstrated that TFS is able to induce a cleavage resynthesis cycle in such complexes, which resulted in the accumulation of dinucleotides corresponding to the last two nucleotides of the transcript. Further analysis of cleavage products revealed that, even under conditions that strongly promote misincorporation, still 50% of the released dinucleotides were correctly incorporated. Therefore, we assume that pausing of elongation complexes is an important determinant of TFS-induced RNA cleavage from the 3' end. As the incorporation rate of wrong nucleotides is about 700-fold reduced, it is possible that this delay also provides an appropriate time window for cleavage induction in order to maintain transcriptional fidelity by preventing misincorporation.

The RNA polymerase II core promoter

The events leading to transcription of eukaryotic protein-coding genes culminate in the positioning of RNA polymerase II at the correct initiation site. The core promoter, which can extend ~35 bp upstream and/or downstream of this site, plays a central role in regulating initiation. Specific DNA elements within the core promoter bind the factors that nucleate the assembly of a functional preinitiation complex and integrate stimulatory and repressive signals from factors bound at distal sites. Although core promoter structure was originally thought to be invariant, a remarkable degree of diversity has become apparent. This article reviews the structural and functional diversity of the RNA polymerase II core promoter.

Topography of the euryarchaeal transcription initiation complex

Transcription in the Archaea is carried out by RNA polymerases and transcription factors that are highly homologous to their eukaryotic counterparts, but little is known about the structural organization of the archaeal transcription complex. To address this, transcription initiation complexes have been formed with Pyrococcus furiosus transcription factors (TBP and TFB1), RNA polymerase, and a linear DNA fragment containing a strong promoter. The arrangement of proteins from base pair -35 to +20 (relative to the transcriptional start site) has been analyzed by photochemical protein-DNA cross-linking. TBP cross-links to the TATA box and TFB1 cross-links both upstream and downstream of the TATA box, as expected, but the sites of most prominent TFB1 cross-linking are located well downstream of the TATA box, reaching as far as the start site of transcription, suggesting a role for TFB1 in initiation of transcription that extends beyond polymerase recruitment. These cross-links indicate the transcription factor orientation in the initiation complex. The pattern of cross-linking of four RNA polymerase subunits (B, A', A", and H) to the promoter suggests a path for promoter DNA relative to the RNA polymerase surface in this archaeal transcription initiation complex. In addition, an unidentified protein approximately the size of TBP cross-links to the non-transcribed DNA strand near the upstream edge of the transcription bubble. Cross-linking is specific to the polymerase-containing initiation complex and requires the gdh promoter TATA box. The location of this protein suggests that it, like TFB1, could also have a role in transcription initiation following RNA polymerase recruitment.

Function of Corynebacterium glutamicum promoters in Escherichia coli, Streptomyces lividans, and Bacillus subtilis

The function of seven promoters from Corynebacterium glutamicum, P-hom, P-leuA, P-per, P-aes1, P-aes2, P-45, and P-104, was analyzed in a heterologous background. DNA fragments carrying the promoters were cloned into shuttle promoter-probe vectors replicating in Escherichia coli and C. glutamicum (pET2), Streptomyces lividans (pGL7011) and Bacillus subtilis (pRB394). With the exception of P-hom, P-leuA and P-104 in B. subtilis, all promoters were found to be active in all species. Non-radioactive methods of primer-extension analysis and of S1-nuclease protection assay using automatic sequencer were developed to determine the respective transcriptional start points (TSPs). All TSPs were determined by primer extension and in two promoters (P-45 and P-hom) the main TSPs were confirmed by S1-mapping. While the main TSPs were identical in all four species, utilization of multiple TSPs varied among the species and additional TSPs were detected in S. lividans. Knowledge of the efficiency of promoters and of exact respective TSPs may be of practical value for the construction of expression systems in a heterologous background.

Activation of archaeal transcription by recruitment of the TATA-binding protein

The hyperthermophilic archaeon Methanococcus jannaschii encodes two putative transcription regulators, Ptr1 and Ptr2, that are members of the Lrp/AsnC family of bacterial transcription regulators. In contrast, this archaeon's RNA polymerase and core transcription factors are of eukaryotic type. Using the M. jannaschii high-temperature in vitro transcription system, we show that Ptr2 is a potent transcriptional activator, and that it conveys its stimulatory effects on its cognate eukaryal-type transcription machinery from an upstream activating region composed of two Ptr2-binding sites. Transcriptional activation is generated, at least in part, by Ptr2-mediated recruitment of the TATA-binding protein to the promoter.

The fission yeast TFIIB-related factor limits RNA polymerase III to a TATA-dependent pathway of TBP recruitment

The RNA polymerase (pol) III-transcribed (e.g. tRNA and 5S rRNA) genes of traditionally studied organisms rely on gene-internal promoters that precisely position the initiation factor, TFIIIB, on the upstream promoter-less DNA. This is accomplished by the ability of the TFIIIB subunit, TFIIB-related factor (Brf1), to make stable protein-protein interactions with TATA-binding protein (TBP) and place it on the promoter-less upstream DNA. Unlike traditional model organisms, Schizosaccharomyces pombe tRNA and 5S rRNA genes contain upstream TATA promoters that are required to program functional pol III initiation complexes. In this study we demonstrate that S.pombe (Sp)Brf does not form stable interactions with TBP in the absence of DNA using approaches that do reveal stable association of TBP and S.cerevisiae (Sc)Brf1. Gel mobility analyses demonstrate that a TBP-TATA DNA complex can recruit SpBrf to a Pol III promoter. Consistent with this, overproduction of SpBrf in S.pombe increases the expression of a TATA-dependent, but not a TATA-less, suppressor tRNA gene. Since previous whole genome analysis also revealed TATA elements upstream of tRNA genes in Arabidopsis, this pathway may be more widespread than appreciated previously.

TrmB, a sugar-specific transcriptional regulator of the trehalose/maltose ABC transporter from the hyperthermophilic archaeon Thermococcus litoralis

We report the characterization of TrmB, a protein of 38,800 apparent molecular weight, that is involved in the maltose-specific regulation of a gene cluster in Thermococcus litoralis, malE malF malG orf trmB malK, encoding a binding protein-dependent ABC transporter for trehalose and maltose. TrmB binds maltose and trehalose half-maximally at 20 microm and 0.5 mm sugar concentration, respectively. Binding of maltose but not of trehalose showed indications of sigmoidality and quenched the intrinsic tryptophan fluorescence by 15%, indicating a conformational change on maltose binding. TrmB causes a shift in electrophoretic mobility of DNA fragments harboring the promoter and upstream regulatory motif identified by footprinting. Band shifting by TrmB can be prevented by maltose. In vitro transcription assays with purified components from Pyrococcus furiosus have been established to show pmalE promoter-dependent transcription at 80 degrees C. TrmB specifically inhibits transcription, and this inhibition is counteracted by maltose and trehalose. These data characterize TrmB as a maltose-specific repressor for the trehalose/maltose transport operon of Thermococcus litoralis.

The basal transcription factors TBP and TFB from the mesophilic archaeon Methanosarcina mazeii: structure and conformational changes upon interaction with stress-gene promoters

Transcription of archaeal non-stress genes involves the basal factors TBP and TFB, homologs of the eucaryal TATA-binding protein and transcription factor IIB, respectively. No comparable information exists for the archaeal molecular-chaperone, stress genes hsp70(dnaK), hsp40(dnaJ), and grpE. These do not occur in some archaeal species, but are present in others possibly due to lateral transfer from bacteria, which provides a unique opportunity to study regulation of stress-inducible bacterial genes in organisms with eukaryotic-like transcription machinery. Among the Archaea with the genes, those from the mesophilic methanogen Methanosarcina mazeii are the only ones whose basal (constitutive) and stress-induced transcription patterns have been determined. To continue this work, tbp and tfb were cloned from M. mazeii, sequenced, and the encoded recombinant proteins characterized in solution, separately and in complex with each other and with DNA. M. mazeii TBP ranks among the shortest within Archaea and, contrary to other archaeal TBPs, it lacks tryptophan or an acidic tail at the C terminus and has a basic N-terminal third. M. mazeii TFB is similar in length to archaeal and eucaryal homologs and all have a zinc finger and HTH motifs. Phylogenetically, the archaeal and eucaryal proteins form separate clusters and the M. mazeii molecules are closer to the homologs from Archaeoglobus fulgidus than to any other. Antigenically, M. mazeii TBP and TFB are close to archaeal homologs within each factor family, but the two families are unrelated. The purified recombinant factors were functionally active in a cell-free in vitro transcription system, and were interchangeable with the homologs from Methanococcus thermolithotrophicus. The M. mazeii factors have a similar secondary structure by circular dichroism (CD). The CD spectra changed upon binding to the promoters of the stress genes grpE, dnaK, and dnaJ, with the changes being distinctive for each promoter; in contrast, no effect was produced by the promoter of a non-stress-gene. Factor(s)-DNA modeling predicted that modifications of H bonds are caused by TBP binding, and that these modifications are distinctive for each promoter. It also showed which amino acid residues would contact an extended TATA box with a B recognition element, and evolutionary conservation of the TBP-TFB-DNA complex orientation between two archaeal organisms with widely different optimal temperature for growth (37 and 100 degrees C).

Events during initiation of archaeal transcription: open complex formation and DNA-protein interactions

Transcription in Archaea is initiated by association of a TATA box binding protein (TBP) with a TATA box. This interaction is stabilized by the binding of the transcription factor IIB (TFIIB) orthologue TFB. We show here that the RNA polymerase of the archaeon Methanococcus, in contrast to polymerase II, does not require hydrolysis of the beta-gamma bond of ATP for initiation of transcription and open complex formation on linearized DNA. Permanganate probing revealed that the archaeal open complex spanned at least the DNA region from -11 to -1 at a tRNA(Val) promoter. The Methanococcus TBP-TFB promoter complex protected the DNA region from -40 to -14 on the noncoding DNA strand and the DNA segment from -36 to -17 on the coding DNA strand from DNase I digestion. This DNase I footprint was extended only to the downstream end by the addition of the RNA polymerase to position +17 on the noncoding strand and to position +13 on the coding DNA strand.

Mechanism and regulation of transcription in archaea

The archaeal basal transcription machinery resembles the core components of the eucaryal RNA polymerase II apparatus. Thus, studies of the archaeal basal machinery over the last few years have shed light on fundamentally conserved aspects of the mechanisms of transcription pre-initiation complex assembly in both eucarya and archaea. Intriguingly, it has become increasingly apparent that regulators of archaeal transcription resemble regulators initially identified in bacteria. The presence of these shared bacterial-archaeal regulators has given insight into the evolution of gene regulatory processes in all three domains of life.

Initiator and upstream elements in the alpha2-tubulin promoter of Giardia lamblia

Giardia lamblia, one of the earliest diverging eukaryotes and a major cause of diarrhea world-wide, has unusually short intergenic regions, raising questions concerning its regulation of gene expression. We have approached this issue through examination of the alpha2-tubulin promoter and in particular investigated the function of an AT-rich element surrounding the transcription start site. Its placement and the ability of this sequence to direct transcription initiation in the absence of any other promoter elements is similar to the initiator element in higher eukaryotes. However, the sequence diversity of extremely short (8-10 bp) initiator elements is surprising, as is their ability to independently direct substantial levels of transcription. We also identified a large AT-rich element located between -64 and -29 bp upstream of the transcriptional start site and show using both deletions and site-specific mutations of this region that sequences between -60 and the start of transcription are important for promoter strength; interestingly this AT-rich sequence is not highly conserved among different Giardia promoters. These data suggest that while the overall structure of the core promoter has been conserved throughout eukaryotic evolution, significant variation and flexibility is allowed in element consensus sequences and roles in transcription. In particular, the short and diverse sequences that function in transcription initiation in Giardia suggest the potential for relaxed transcriptional regulation.

An Lrp-like transcriptional regulator from the archaeon Pyrococcus furiosus is negatively autoregulated

The archaeal transcriptional initiation machinery closely resembles core elements of the eukaryal polymerase II system. However, apart from the established basal archaeal transcription system, little is known about the modulation of gene expression in archaea. At present, no obvious eukaryal-like transcriptional regulators have been identified in archaea. Instead, we have previously isolated an archaeal gene, the Pyrococcus furiosus lrpA, that potentially encodes a bacterial-like transcriptional regulator. In the present study, we have for the first time addressed the actual involvement of an archaeal Lrp homologue in transcription modulation. For that purpose, we have produced LrpA in Escherichia coli. In a cell-free P. furiosus transcription system we used wild-type and mutated lrpA promoter fragments to demonstrate that the purified LrpA negatively regulates its own transcription. In addition, gel retardation analyses revealed a single protein-DNA complex, in which LrpA appeared to be present in (at least) a tetrameric conformation. The location of the LrpA binding site was further identified by DNaseI and hydroxyl radical footprinting, indicating that LrpA binds to a 46-base pair sequence that overlaps the transcriptional start site of its own promoter. The molecular basis of the transcription inhibition by LrpA is discussed.

Transcription factor S, a cleavage induction factor of the archaeal RNA polymerase

We have analyzed the function of an archaeal protein (now called transcription factor S (TFS)) that shows sequence similarity to eukaryotic transcription factor IIS (TFIIS) as well as to small subunits of eukaryotic RNA polymerases I (A12.6), II (B12.2), and III (C11). Western blot analysis with antibodies against recombinant TFS demonstrated that this protein is not a subunit of the RNA polymerase. In vitro transcription experiments with paused elongation complexes at position +25 showed that TFS is able to induce cleavage activity in the archaeal RNA polymerase in a similar manner to TFIIS. In the presence of TFS, the cleavage activity of the RNA polymerase truncates the RNA back to position +15 by releasing mainly dinucleotides from the 3'-end of the nascent RNA. Furthermore, TFS reduces the amount of non-chaseable elongation complexes at position +25 as well as position +45. These findings clearly demonstrate that this protein has a similar function to eukaryotic TFIIS.

Expression and heat-responsive regulation of a TFIIB homologue from the archaeon Haloferax volcanii

Multiple divergent genes encoding the eukaryal-like TFIIB (TFB) transcription initiation factor have been identified in the archaeon Haloferax volcanii. Expression of one of these TFB-encoding genes, referred to here as tfb2, was induced specifically in response to heat shock at the transcription level. A time course for tfb2 induction demonstrated that mRNA levels increased as much as eightfold after 15 min at 60 degrees C. A transcription fusion of the tfb2 promoter region with a stable RNA reporter gene confirmed the heat responsiveness of the tfb2 core promoter, and immunoblot analysis using antibodies generated against a recombinant His-tagged TFB2 showed that the protein levels of one TFB increased slightly in response to elevated temperatures. An archaeal consensus TATA element (5'-TTTATA-3') was located 110 bp upstream of the translation start site and appeared to be used for both basal and heat shock-induced expression. The long DNA leader region (79 bp) preceding the predicted AUG translation start codon for TFB2 contained a T-rich sequence element located 22 bp downstream of the transcription start site. Using an in vivo transcription termination assay, we demonstrated that this T-rich element can function as a sequence-dependent transcription terminator, which may serve to downregulate expression of the tfb2 gene under both non-heat shock and heat shock conditions.

Transcriptional regulation in the hyperthermophilic archaeon Pyrococcus furiosus: coordinated expression of divergently oriented genes in response to beta-linked glucose polymers

The genetic organization, expression, and regulation of the celB locus of the hyperthermophilic archaeon Pyrococcus furiosus were analyzed. This locus includes the celB gene, which codes for an intracellular beta-glucosidase, and a divergently orientated gene cluster, adhA-adhB-lamA, which codes for two alcohol dehydrogenases and an extracellular beta-1,3-endoglucanase that is transcribed as a polycistronic messenger (the lamA operon). During growth of P. furiosus on either the beta-1,4-linked glucose dimer cellobiose or the beta-1,3-linked glucose polymer laminarin, the activities of both beta-glucosidase and endoglucanase were increased at least fivefold compared with levels during growth on maltose or pyruvate. Northern blot analysis revealed an enhanced transcription of both the celB gene and the lamA operon in the presence of these glucose-containing substrates. The in vivo and in vitro transcription initiation sites of both the celB gene and the lamA operon were identified 25 nucleotides downstream of conserved TATA box motifs. A number of repeating sequences have been recognized in the celB-adhA intergenic region, some of which might be part of a transcriptional regulator-binding site.

Analysis of DNA compaction profile and intracellular contents of archaeal histones from Pyrococcus kodakaraensis KOD1

Two histone genes, hpkA and hpkB, from hyperthermophilic archaeon Pyrococcus kodakaraensis KOD1 strain were cloned, sequenced, and expressed in Escherichia coli cells. Both hpkA and hpkB genes encoded a protein of 67 amino acids, however they possessed the different molecular weight (HpkA, 7,378:HpkB, 7,167). Deduced amino acid sequences of HpkA and HpkB were homologous to other archaeal histones and eucaryal core histones (H2A, H4). Gel mobility shift assays by purified proteins demonstrated that HpkB possessed higher affinity to DNA and more extensive ability to compact DNA than HpkA. HpkB prevented double stranded DNA from thermal denaturation in less amount than HpkA in vitro. In order to investigate intracellular contents of HpkA and HpkB in KOD1 cells, immunoblot analysis was performed by using anti-HpkA antisera obtained from immunized BALB/c mice, showing that HpkA was less abundantly expressed than HpkB in KOD1 cells. These results suggest that HpkB plays a major role to protect double stranded DNA from thermal denaturation in vivo.

Transcription and translation in Archaea: a mosaic of eukaryal and bacterial features

The principal components involved in the processes of transcription and translation in Archaea have been identified by a combination of biochemistry and genome sequencing. In many cases, these factors are closely related to previously characterized proteins from Eukarya and Bacteria. Elucidating the function of these proteins will shed considerable light on the evolution of gene regulatory processes.

Purification, regulation, and molecular and biochemical characterization of pyruvate carboxylase from Methanobacterium thermoautotrophicum strain deltaH

We discovered that Methanobacterium thermoautotrophicum strain DeltaH possessed pyruvate carboxylase (PYC), and this biotin prototroph required exogenously supplied biotin to exhibit detectable amounts of PYC activity. The enzyme was highly labile and was stabilized by 10% inositol in buffers to an extent that allowed purification to homogeneity and characterization. The purified enzyme was absolutely dependent on ATP, Mg2+ (or Mn2+ or Co2+), pyruvate, and bicarbonate for activity; phosphoenolpyruvate could not replace pyruvate, and acetyl-CoA was not required. The enzyme was inhibited by ADP and alpha-ketoglutarate but not by aspartate or glutamate. ATP was inhibitory at high concentrations. The enzyme, unlike other PYCs, exhibited nonlinear kinetics with respect to bicarbonate and was inhibited by excess Mg2+, Mn2+, or Co2+. The 540-kDa enzyme of A4B4 composition contained a non-biotinylated 52-kDa subunit (PYCA) and a 75-kDa biotinylated subunit (PYCB). The pycB gene was probably monocistronic and followed by a putative gene of a DNA-binding protein on the opposite strand. The pycA was about 727 kilobase pairs away from pycB on the chromosome and was probably co-transcribed with the biotin ligase gene (birA). PYCA and PYCB showed substantial sequence identities (33-62%) to, respectively, the biotin carboxylase and biotin carboxyl carrier + carboxyltransferase domains or subunits of known biotin-dependent carboxylases/decarboxylases. We discovered that PYCB and probably the equivalent domains or subunits of all biotin-dependent carboxylases harbored the serine/threonine dehydratase types of pyridoxal-phosphate attachment site. Our results and the existence of an alternative oxaloacetate synthesizing enzyme phosphoenolpyruvate carboxylase in M. thermoautotrophicum strain DeltaH (Kenealy, W. R., and Zeikus, J. G. (1982) FEMS Microbiol. Lett. 14, 7-10) raise several questions for future investigations.

Heat shock inducibility of an archaeal TATA-like promoter is controlled by adjacent sequence elements

The expression of a heat-inducible cct1 (chaperonin-containing Tcp-1) family member gene is regulated at the transcription level in the archaeon Haloferax volcanii. Transcriptional fusions of the cct1 promoter region with a yeast proline tRNA reporter gene were constructed to analyse the functional domains of this archaeal heat shock promoter. Both basal and heat-induced transcription of the reporter gene was directed by an archaeal consensus TATA element (5'-TTTATA-3') centred 25bp upstream of the transcription start site. Deletion mutagenesis indicated that the 5' boundary of the cct1 regulatory region mapped to position -37. Nucleotide alignment with the 5' flanking regions of two additional cct-related genes identified in H. volcanii showed a high degree of sequence conservation between positions +1 and -37, especially in and immediately surrounding the TATA element of the putative core promoter. Mutational analysis of conserved sequences demonstrated that basal and heat-induced transcription required sequence elements located upstream and downstream of the TATA-box. These findings indicate that the regulatory sequences involved in heat-induced transcription lie within the core promoter region and suggest that the mechanism controlling heat shock gene expression in H. volcanii differs from the bacterial and eukaryal strategies.

Isolation of the gene encoding Pyrococcus furiosus ornithine carbamoyltransferase and study of its expression profile in vivo and in vitro

The gene coding for ornithine carbamoyltransferase (OTCase, argF) in the hyperthermophilic archaea Pyrococcus furiosus was cloned by complementation of an OTCase mutant of Escherichia coli. The cloned P. furiosus argF gene also complemented a similar mutant of Saccharomyces cerevisiae. Sequencing revealed an open reading frame of 314 amino acids homologous to known OTCases and preceded by a TATA box showing only limited similarity with the Euryarchaeota consensus sequence. This is in accordance with the comparatively low in vitro promoter activity observed in a cell-free purified transcription system. Transcription initiates in vivo as well as in vitro at a guanine, 22 nucleotides downstream of the TATA box. Upstream from argF is a putative gene for diphthine synthetase, a eukaryotic enzyme assumed to occur also in archaea but not in bacteria.

Factor requirements for transcription in the Archaeon Sulfolobus shibatae

Archaea (archaebacteria) constitute a domain of life that is distinct from Bacteria (eubacteria) and Eucarya (eukaryotes). Although archaeal cells share many morphological features with eubacteria, their transcriptional apparatus is more akin to eukaryotic RNA polymerases I, II and III than it is to eubacterial transcription systems. Thus, in addition to possessing a 10 subunit RNA polymerase and a homologue of the TATA-binding protein (TBP), Archaea possess a polypeptide termed TFB that is homologous to eukaryotic TFIIB. Here, we investigate the factor requirements for transcription of several promoters of the archaeon Sulfolobus shibatae and its associated virus SSV. Through in vitro transcription and immunodepletion, we demonstrate that S. shibatae TBP, TFB and RNA polymerase are not complexed tightly with one another and that each is required for efficient transcription of all promoters tested. Furthermore, full transcription is restored by supplementing respective depleted extracts with recombinant TBP or TFB, indicating that TBP-associated factors or TFB-associated factors are not required. Indeed, gel-filtration suggests that Sulfolobus TBP and TFB are not associated stably with other proteins. Finally, all promoters analysed are transcribed accurately and efficiently in an in vitro system comprising recombinant TBP and TFB, together with essentially homogeneous preparation of RNA polymerase. Transcription in Archaea is therefore fundamentally homologous to that in eukaryotes, although factor requirements appear to be much less complex.

Cloning and phylogenetic analysis of the genes encoding acetohydroxyacid synthase from the archaeon Methanococcus aeolicus

The gene for acetohydroxyacid synthase (AHAS) was cloned from the archaeon Methanococcus aeolicus. Contrary to biochemical studies [Xing, R. and Whitman, W.B. (1994) J. Bacteriol. 176, 1207-1213] the enzyme was encoded by two open reading frames (ORFs). Based on sequence homology, these ORFs were designated ilvB and ilvN for the large and small subunits of AHAS, respectively. A putative methanogen promoter preceded ilvB-ilvN, and a potential internal promoter was found upstream of ilvN. ilvB encoded a 65-kDa protein, which agreed well with the measured value for the purified enzyme. ilvN encoded a 19-kDa protein, which fell within the range of M(r) of small subunits from other sources. Phylogenetic analysis of the deduced amino acid sequence of ilvB showed a close relationship between the AHAS of Bacteria and Archaea, to the exclusion of other enzymes in this family, including pyruvate oxidase, glyoxylate carboligase, pyruvate decarboxylase, and the acetolactate synthase found in fermentative Bacteria. Thus, this family of enzymes probably arose prior to the divergence of the Bacteria and Archaea. Moreover, the higher plant AHAS and the red algal AHAS were related to the AHAS II of Escherichia coli and the cyanobacterial AHAS, respectively. For this reason, these genes appear to have been acquired by the Eucarya during the endosymbiosis that gave rise to the mitochondrion and chloroplast, respectively. One of the ORFs in the Methanococcus jannaschii genome possesses high similarity to the M. aeolicus ilvB, indicating that it is an authentic AHAS.

Identification of a gene in the euryarchaeal Thermococcus species AN1 encoding a protein homologous to the alpha subunit of the eukaryal signal recognition particle (SRP) receptor

We describe here the sequence and transcriptional analysis of a gene from the euryarchaeal Thermococcus species AN1 (DSM 2770) encoding a protein homologous to the alpha subunit of the eukaryal SRP receptor (SR alpha). The AN1 protein is found to share the highest degree of homology with the only other described archaeal SR alpha homolog characterized from the hyperthermophilic crenarchaeal Sulfolobus solfataricus. Sequence analysis of the translation of the AN1 gene reveals the presence of the following previously described domains: an N-terminal alpha domain rich in acidic and basic residues; an X domain and four GTP binding motifs (G1-G4). A putative guanine nucleotide dissociation stimulator binding element is also present. The AN1 SR alpha protein would now represent the shortest variant of this expanding family with 329 residues and a predicted molecular weight of 36.4 kDa. A Northern analysis indicates that the AN1 SR alpha protein gene transcript is present at low levels suggesting that SR alpha is likely to be only a minor cell constituent. The presence of an SR alpha homolog in another kingdom within the archaeal domain possessing the full suite of conserved motifs is significant in several respects. It not only supports the monophyletic character of the domain Archaea but suggests that these homologs have similar functions in these organisms and emphasises the ancient origins of the protein export machinery.

Purification and analysis of an extremely halophilic beta-galactosidase from Haloferax alicantei

As a first step in the development of a reporter system for gene expression in halophilic archaea, a beta-galactosidase was purified 140-fold from Haloferax alicantei (previously phenon K, strain Aa2.2). An overproducing mutant was first isolated by UV mutagenesis and screening on agar plates containing X-Gal substrate. Cytoplasmic extracts of the mutant contained 25-fold higher enzyme levels than the parent. Purification of the active enzyme was greatly facilitated by the ability of sorbitol to stabilise enzyme activity in the absence of salt, which allowed conventional purification methods (e.g., ion-exchange chromatography) to be utilised. The enzyme was optimally active at 4 M NaCl and was estimated to be 180 +/- 20 kDa in size, consisting of two monomers (each 78 +/- 3 kDa). It cleaves several different beta-galactoside substrates such as ONP-Gal, X-Gal and lactulose, but not lactose, and also has beta-D-fucosidase activity. No beta-glucosidase, beta-arabinosidase or beta-xylosidase activity could be detected. The amino-acid sequence at the N-terminus and of four proteolytic products has been determined.

Hydrogen regulation of growth, growth yields, and methane gene transcription in Methanobacterium thermoautotrophicum deltaH

Changes in growth rate, methanogenesis, growth yield (Y(CH4)), and methane gene transcription have been correlated with changes in the supply of H2 to Methanobacterium thermoautotrophicum deltaH cells growing on H2 plus CO2 in fed-batch cultures. Under conditions of excess H2, biomass and methanogenesis increased exponentially and in parallel, resulting in cultures with a constant Y(CH4) and transcription of the mth and mrt genes that encode the H2-dependent N5,N10-methenyltetrahydromethanopterin (methenyl-H4MPT) reductase (MTH) and methyl coenzyme M reductase II (MRII), respectively. Reducing the H2 supply, by decreasing the percentage of H2 in the input gas mixture or by reducing the mixing speed of the fermentor impeller, decreased the growth rate and resulted in lower and constant rates of methanogenesis. Under such H2-limited growth conditions, cultures grew with a continuously increasing Y(CH4) and the mtd and mcr genes that encode the reduced coenzyme F420-dependent N5,N10-methenyl-H4MPT reductase (MTD) and methyl coenzyme M reductase I (MRI), respectively, were transcribed. Changes in the kinetics of growth, methanogenesis, and methane gene transcription directed by reducing the H2 supply could be reversed by restoring a high H2 supply. Methane production continued, but at a low and constant rate, and only mcr transcripts could be detected when the H2 supply was reduced to a level insufficient for growth. ftsA transcripts, which encode coenzyme F390 synthetase, were most abundant in cells growing with high H2 availability, consistent with coenzyme F390 synthesis signaling a high exogenous supply of reductant.