Evolution in the laboratory: the genome of Halobacterium salinarum strain R1 compared to that of strain NRC-1.

We report the sequence of the Halobacterium salinarum strain R1 chromosome and its four megaplasmids. Our set of protein-coding genes is supported by extensive proteomic and sequence homology data. The structures of the plasmids, which show three large-scale duplications (adding up to 100 kb), were unequivocally confirmed by cosmid analysis. The chromosome of strain R1 is completely colinear and virtually identical to that of strain NRC-1. Correlation of the plasmid sequences revealed 210 kb of sequence that occurs only in strain R1. The remaining 350 kb shows virtual sequence identity in the two strains. Nevertheless, the number and overall structure of the plasmids are largely incompatible. Also, 20% of the protein sequences differ despite the near identity at the DNA sequence level. Finally, we report genome-wide mobility data for insertion sequences from which we conclude that strains R1 and NRC-1 originate from the same natural isolate. This exemplifies evolution in the laboratory.

Genomics and functional genomics with haloarchaea.

The first haloarchaeal genome was published in 2000 and today five genome sequences are available. Transcriptome and proteome analyses have been established for two and three haloarchaeal species, respectively, and more than 20 studies using these functional genomic approaches have been published in the last two years. These studies gave global overviews of metabolic regulation (aerobic and anaerobic respiration, phototrophy, carbon source usage), stress response (UV, X-rays, transition metals, osmotic and temperature stress), cell cycle-dependent transcript level regulation, and transcript half-lives. The only translatome analysis available for any prokaryotic species revealed that 10 and 20% of all transcripts are translationally regulated in Haloferax volcanii and Halobacterium salinarum, respectively. Very effective methods for the construction of in frame deletion mutants have been established recently for haloarchaea and are intensively used to unravel the biological roles of genes in this group. Bioinformatic analyses include both cross-genome comparisons as well as integration of genomic data with experimental results. The first systems biology approaches have been performed that used experimental data to construct predictive models of gene expression and metabolism, respectively. In this contribution the current status of genomics, functional genomics, and molecular genetics of haloarchaea is summarized and selected examples are discussed.

Genetic identification of three ABC transporters as essential elements for nitrate respiration in Haloferax volcanii.

More than 40 nitrate respiration-deficient mutants of Haloferax volcanii belonging to three different phenotypic classes were isolated. All 15 mutants of the null phenotype were complemented with a genomic library of the wild type. Wild-type copies of mutated genes were recovered from complemented mutants using two different approaches. The DNA sequences of 13 isolated fragments were determined. Five fragments were found to overlap; therefore nine different genomic regions containing genes essential for nitrate respiration could be identified. Three genomic regions containing genes coding for subunits of ABC transporters were further characterized. In two cases, genes coding for an ATP-binding subunit and a permease subunit were clustered and overlapped by four nucleotides. The third gene for a permease subunit had no additional ABC transporter gene in proximity. One ABC transporter was found to be glucose specific. The mutant reveals that the ABC transporter solely mediates anaerobic glucose transport. Based on sequence similarity, the second ABC transporter is proposed to be molybdate specific, explaining its essential role in nitrate respiration. The third ABC transporter is proposed to be anion specific. Genome sequencing has shown that ABC transporters are widespread in Archaea. Nevertheless, this study represents only the second example of a functional characterization.

Prokaryotic structural maintenance of chromosomes (SMC) proteins: distribution, phylogeny, and comparison with MukBs and additional prokaryotic and eukaryotic coiled-coil proteins.

Structural maintenance of chromosomes (SMC) proteins are known to be essential for chromosome segregation in some prokaryotes and in eukaryotes. A systematic search for the distribution of SMC proteins in prokaryotes with fully or partially sequenced genomes showed that they form a larger family than previously anticipated and raised the number of known prokaryotic homologs to 54. Secondary structure predictions revealed that the length of the globular N-terminal and C-terminal domains is extremely well conserved in contrast to the hinge domain and coiled-coil domains which are considerably shorter in several bacterial species. SMC proteins are present in all gram-positive bacteria and in nearly all archaea while they were found in less than half of the gram-negative bacteria. Phylogenetic analyses indicate that the SMC tree roughly resembles the 16S rRNA tree, but that cyanobacteria and Aquifex aeolicus obtained smc genes by lateral transfer from archaea. Fourteen out of 22 smc genes located in fully sequenced genomes seem to be co-transcribed with a second gene out of six different gene families, indicating that the deduced gene products might be involved in similar functions. The SMC proteins were compared with other prokaryotic proteins with long coiled-coil domains. The lengths of different protein domains and signature sequences allowed to differentiate SMCs, MukBs, which were found to be confined to gamma proteobacteria, and two subfamilies of COG 0419 including the SbcC nuclease from E. coli. A phylogenetic analysis was performed including the prokaryotic coiled-coil proteins as well as SMCs and Rad18 proteins from selected eukaryotes.

Two hypotheses--one answer. Sequence comparison does not support an evolutionary link between halobacterial retinal proteins including bacteriorhodopsin and eukaryotic G-protein-coupled receptors.

The structure of bacteriorhodopsin (BR) of Halobacterium halobium is known. Despite the lack of sequence similarities it is often taken as a model for eukaryotic G-protein-coupled receptors (GPCRs). Recently two hypotheses were used to support the homology of BR and GPCRs, namely evolution by exon shuffling and evolution by gene duplication. BR is a member of a family of halobacterial retinal proteins. The sequences of eight members of this family were used to test the two hypotheses. Based on sequence comparison, no indication for an evolutionary linkage between the two protein families could be found.

Properties of a mutant lactose carrier of Escherichia coli with a Cys148----Ser148 substitution.

The cysteine residue at position 148 in the lactose carrier protein of Escherichia coli has been replaced by serine using oligonucleotide-directed, site-specific mutagenesis of the lac Y gene. The mutant carrier is incorporated into the cytoplasmic membrane to the same extent as the wild-type carrier, confers a lactose-positive phenotype on cells, and actively transports lactose and other galactosides. However, the maximum rate of transport for several substrates is reduced by a factor of 6-10 while the apparent affinity is reduced by a factor of 2-4. Carrier activity in the mutant is much less sensitive to sulfhydryl reagents (HgCl2, p-(chloromercuri)benzenesulfonate and N-ethylmaleimide) than in the wild type, and beta-D-galactosyl 1-thio-beta-D-galactoside does not protect the mutant carrier against slow inactivation by N-ethylmaleimide. It is concluded that the Cys148 residue is not essential for carrier-catalyzed galactoside: proton symport and that its alkylation presumbly prohibits access of the substrate to the binding site by steric hindrance. A serine residue at position 148 in the amino acid sequence appears to alter the protein structure in such a way that one or more sulfhydryl groups elsewhere in the protein become accessible to alkylating agents thereby inhibiting transport. Recently, Trumble et al. [(1984) Biochem. Biophys. Res. Commun. 119, 860-867] arrived at similar conclusions by investigating a mutant carrier with a Cys148----Gly148 replacement.

Extensive proteolysis inhibits high-level production of eukaryal G protein-coupled receptors in the archaeon Haloferax volcanii.

In this study the usage of the halophilic archaeon Haloferax volcanii as a production system for eukaryal G protein-coupled receptors (GPCRs) was characterized. The genes of four GPCRs were fused to the dihydrofolate reductase gene of H. volcanii. In Northern blots both 5' fragments and full-length fusion transcripts were found. In contrast, only C-terminal fusion protein fragments could be detected in Western blot analyses. Ligand binding experiments revealed that a minor amount of correctly folded human beta 2 adrenergic receptor was inserted into the membrane. The introduction of different modifications at the 5' and the 3' end of the receptor genes did not significantly increase the production level. Determination of the subcellular localization showed that fusion protein fragments containing one or more receptor helices were located in the membrane. The results indicate that neither transcription, translation nor membrane translocation but the activity of one or more proteases limits the level of GPCR production in H. volcanii.

Expression of beta 2-adrenoceptors in halobacteria.

Halobacteria are halophilic representatives of the recently defined domain, the Archaea. Halobacterium salinarium belongs to this group of microorganisms and contains large amounts of bacteriorhodopsin in its membrane. Bacteriorhodopsin is a seven-transmembrane protein that consists of bacterio-opsin (BO), and the chromophore retinal, which is covalently attached to BO. We have investigated whether the expression machinery for BO can be utilized for synthesis of the human beta 2-adrenoceptor (beta 2-AR), a protein with a similar seven-transmembrane-helix topology. An expression vector for BO synthesis was modified to express beta 2-ARs under the control of BO regulatory clements in H. salinarium. Homologous recombination into the genome was verified by polymerase chain reactions. Northern blots revealed transcripts of the calculated size and significant amounts of epitope-tagged beta 2-ARs were detected in Western blots. However, binding of the beta-AR antagonist 125I-cyanopindolol revealed low levels of functional receptors, and the ligand binding properties of these receptors were altered when compared to native receptors. Expression of chimeras containing larger amino terminal portions of BO did not result in higher receptor levels. Expression of beta 2-AR in Haloferax volcanii, another member of halobacteria, was achieved with a vector carrying the ferredoxin promoter. The levels of functional receptor as determined by 125I-cyanopindolol binding were 180 fmol/mg protein. The beta-AR ligands isoprenaline and propranolol showed affinities expected for functional beta 2-ARs. Thus, functional human beta 2-ARs were expressed in halobacteria, constituting a first approach for expression of a eukaryotic protein in the domain of Archaea.

Transcription initiation in Archaea: facts, factors and future aspects.

The basal apparatus for transcription initiation in Archaea is more closely related to the eukaryal than to the bacterial counterpart. The understanding of archaeal transcription initiation has been deepened by recent advances, which include genome sequencing, biochemical approaches and the structure determination of a protein DNA complex. Archaeal promoter elements, transcription factors, RNA polymerase and their interactions are discussed and compared with the eukaryal situation. It is emerging that transcription initiation is not uniform in Archaea. A minimal set of promoter elements and transcription factors is conserved, but the relative importance for transcription initiation can vary. Furthermore, additional basal transcription factors and promoter elements seem to be crucial in subgroups of Archaea. Finally, some aspects of global as well as gene-specific transcriptional regulation are discussed.

Fermentative arginine degradation in Halobacterium salinarium (formerly Halobacterium halobium): genes, gene products, and transcripts of the arcRACB gene cluster.

Fermentative growth via the arginine deiminase pathway is mediated by the enzymes arginine deiminase, carbamate kinase, and catabolic ornithine transcarbamylase and by a membrane-bound arginine-ornithine antiporter. Recently we reported the characterization of catabolic ornithine transcarbamylase and the corresponding gene, arcB, from Halobacterium salinarium (formerly Halobacterium halobium). Upstream of the arcB gene, three additional open reading frames with halobacterial codon usage were found. They were identified as the arcC gene coding for carbamate kinase, the arcA gene coding for arginine deiminase, and a gene, tentatively termed arcR, coding for a putative regulatory protein. The identification of the arcC and arcA genes was verified, respectively, by heterologous expression of the enzyme in Haloferax volcanii and by protein isolation and N-terminal sequence determination of three peptides. The gene order arcRACB differs from the gene order arcDABC in Pseudomonas aeruginosa, the only other organism for which sequence information is available. Transcripts from H. salinarium cultures grown fermentatively or aerobically were characterized by Northern (RNA) blot and primer extension analyses. It was determined (i) that monocistronic transcripts corresponding to the four open reading frames exist and that there are three polycistronic transcripts, (ii) that the level of induction during fermentative growth differs for the various transcripts, and (iii) that upstream of the putative transcriptional start sites for the three structural genes there are sequences with similarities to the halobacterial consensus promoter. The data indicate that expression of the arc gene cluster and its regulation differ in H. salinarium and P. aeruginosa.

Halobacterium sp. GRB: a species to work with!?

The properties of the halobacterial isolate Halobacterium sp. GRB are discussed, especially in relation to its use as a laboratory strain. Experimental results on this species are described, including the isolation of point mutants in the bacterioopsin gene leading to single amino acid replacements in bacteriorhodopsin, the application of a selection procedure for the isolation of different types of mutants, the genetic stability of Halobacterium sp. GRB and the possibility of isolating a set of isogenic mutants, the conditions for transformation experiments with this species, and specific features of Halobacterium sp. GRB, such as halocin production and the absence of a restriction system, as well as DNA adenosine methylation.

Bacteriorhodopsin mutants of Halobacterium sp. GRB. I. The 5-bromo-2'-deoxyuridine selection as a method to isolate point mutants in halobacteria.

Halobacterium sp. GRB (Ebert, K., Goebel, W., and Pfeifer, F. (1984) Mol. & Gen. Genet. 194, 91-97) was used to isolate bacteriorhodopsin (BR) mutants. A procedure is described which allows the enrichment of any type of mutant unable to grow under the selection conditions applied. Its use for the isolation of phototrophically negative, retinal-positive mutants of Halobacterium sp. GRB is demonstrated. Single-cell clones of this phenotype were further characterized. The expression of bacterioopsin was tested with a monoclonal antibody directed against the C terminus of the protein. The expressed bacteriorhodopsins were characterized by their specific activity for proton pumping, their spectral properties, and photocycle kinetics. About 15 independent mutants carrying bacteriorhodopsins of three distinct phenotypic classes could be isolated, including BR with a different absorption maximum, BR of lower specific activity, and BR characterized by a slower photocycle and a lack of proton pumping activity.

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.

The TATA-box-binding protein (TBP) of Halobacterium salinarum. Cloning of the tbp gene, heterologous production of TBP and folding of TBP into a native conformation.

The TATA-box binding protein (TBP) is a basal transcription factor involved in transcription initiation in Eucarya and Archaea. Using a tbp-specific probe, a 4.5-kbp genomic fragment from Halobacterium salinarum was cloned and sequenced. It contained the tbp gene and the 5'-ends of two additional open reading frames, but surprisingly, 70% of the cloned fragment (3.2 kbp) was devoid of coding capacity or similarity to database sequences. The deduced halobacterial TBP exhibits sequence similarities to other archaeal (41-43%) as well as to eucaryal (27-38%) TBP. A comparative analysis showed that the archaeal and eucaryal TBP form two related monophylic protein families, and the archaeal TBP possess features which separate them from eucaryal TBP. Compared with the other TBP, the halobacterial TBP is unique in having a high excess of negatively charged residues. A histidine-tagged version of the halobacterial TBP was produced in Escherichia coli in a denatured conformation and purified by means of Ni-chelating chromatography. CD spectroscopy was used to monitor TBP secondary structure and the conditions necessary for folding it into a native conformation. In the absence of denaturating agents, the folded as well as the unfolded state were found to be stable over a wide range of salt concentrations. Properly folded TBP was shown to bind to a halobacterial TATA-box-containing DNA fragment, indicating that the fusion protein can be used to characterize DNA recognition by the halobacterial TBP.

A 71-kDa protein from Halobacterium salinarium belongs to a ubiquitous P-loop ATPase superfamily with head-rod-tail structure.

The nucleotide sequence of a genomic fragment from Halobacterium salinarium containing an open reading frame encoding a protein with a calculated molecular mass of 71 kDa was determined. Database searches revealed that this protein, Hp71, has similarities to eukaryotic cytoskeletal proteins. Heterologous production of Hp71 in Escherichia coli allowed the isolation of anti-Hp71 antibodies. The antibodies were used (1) to verify the production of Hp71 in H. salinarium and (2) to determine its cytoplasmic localization by immune electron microscopy. Homologous overproduction of Hp71 in H. salinarium and heterologous production in Haloferax volcanii resulted in modifications of cell morphology from rods to extended rods, and from pleiomorphic cells to rods, respectively. Structure prediction methods indicated that Hp71 has a head-rod-tail configuration, including an N-terminal domain with a nucleotide binding motif (P-loop), and an extended discontinuous coiled-coil domain of 330 amino acids. To identify related proteins, the complete genomes of Haemophilus influenzae, Mycoplasma genitalium, and Methanococcus jannaschii were searched for deduced proteins with extended coiled-coil domains. Only one or two proteins were found for each organism, showing that Hp71 is one of only a few prokaryotic intracellular proteins with extended coiled-coil domains. The phenotype upon overproduction and the similarity of Hp71 to the SMC superfamily of P-loop head-rod-tail proteins (named after SMC1, which is involved in the "stability of minichromosomes" in yeast) indicate that Hp71 might be involved in cytoskeleton formation and/or chromosome partitioning in H. salinarium.

Bacterioopsin, haloopsin, and sensory opsin I of the halobacterial isolate Halobacterium sp. strain SG1: three new members of a growing family.

The genes coding for bacterioopsin, haloopsin, and sensory opsin I of a halobacterial isolate from the Red Sea called Halobacterium sp. strain SG1 have been cloned and sequenced. The deduced protein sequences were aligned to the previously known halobacterial retinal proteins. The addition of these new sequences lowered the number of conserved residues to only 23 amino acids, or 8% of the alignment. Data base searches with two highly conserved peptides as well as with an alignment profile yielded no significant similarity to any other protein, so the halobacterial retinal proteins should be regarded as a distinct protein family. The protein alignment was used to make predictions about the structure of the retinal proteins as well as about the amino acids in contact with retinal proteins. These results were in excellent agreement with the structural model of bacteriorhodopsin of Halobacterium halobium as well as with mutant studies, indicating that (i) structure predictions based on the sequences of a membrane protein family can be quite accurate; (ii) halorhodopsin and sensory rhodopsin I have tertiary structures similar to that of bacteriorhodopsin; (iii) conserved amino acids do not take part in reactions specific for one group of proteins, e.g., proton translocation for bacteriorhodopsins, but have a crucial role in determining the conformation and reactions of the chromophore; and (iv) the general mode of action (light-induced chromophore and protein movements) is the same for all halobacterial retinal proteins, ion pumps as well as sensors.

Role of aspartate-96 in proton translocation by bacteriorhodopsin.

Proton transfer reactions in bacteriorhodopsin were investigated by Fourier transform infrared spectroscopy, using a mutant protein in which Asp-96 was replaced by Asn-96. By comparison of the BR - K, BR - L, and BR - M difference spectra (BR indicating bacteriorhodopsin ground state and K, L, and M indicating photo-intermediates) of the wild-type protein with the corresponding difference spectra of the mutant protein, detailed insight into the functional role of this residue in the proton pump mechanism is obtained. Asp-96 is protonated in BR, as well as another aspartic residue, which is tentatively assigned to be Asp-115. Asp-96 is not affected in the primary photoreaction. During formation of the L intermediate it is subjected to a change in the H-bonding character of its carboxylic group, but no deprotonation occurs at this reaction step. Also, in the mutant protein a light-induced structural change of the protein interior near the Asn-96 residue is probed. The BR - M difference spectrum of the mutant protein lacks the negative carbonyl band at 1742 cm-1 of Asp-96 and in addition a positive band at about 1378 cm-1, which is most likely to be caused by the carboxylate vibration of Asp-96. This argues for a deprotonation of Asp-96 in the time range of the M intermediate during its photostationary accumulation. On the basis of these results, it is suggested that the point mutation does not induce a gross change of the protein structure, but a proton-binding site in the proton pathway from the cytoplasmic side to the Schiff base is lost.

Catabolic ornithine transcarbamylase of Halobacterium halobium (salinarium): purification, characterization, sequence determination, and evolution.

Halobacterium halobium (salinarium) is able to grow fermentatively via the arginine deiminase pathway, which is mediated by three enzymes and one membrane-bound arginine-ornithine antiporter. One of the enzymes, catabolic ornithine transcarbamylase (cOTCase), was purified from fermentatively grown cultures by gel filtration and ammonium sulfate-mediated hydrophobic chromatography. It consists of a single type of subunit with an apparent molecular mass of 41 kDa. As is common for proteins of halophilic Archaea, the cOTCase is unstable below 1 M salt. In contrast to the cOTCase from Pseudomonas aeruginosa, the halophilic enzyme exhibits Michaelis-Menten kinetics with both carbamylphosphate and ornithine as substrates with Km values of 0.4 and 8 mM, respectively. The N-terminal sequences of the protein and four peptides were determined, comprising about 30% of the polypeptide. The sequence information was used to clone and sequence the corresponding gene, argB. It codes for a polypeptide of 295 amino acids with a calculated molecular mass of 32 kDa and an amino acid composition which is typical of halophilic proteins. The native molecular mass was determined to be 200 kDa, and therefore the cOTCase is a hexamer of identical subunits. The deduced protein sequence was compared to the cOTCase of P. aeruginosa and 14 anabolic OTCases, and a phylogenetic tree was constructed. The halobacterial cOTCase is more distantly related to the cOTCase than to the anabolic OTCase of P. aeruginosa. It is found in a group with the anabolic OTCases of Bacillus subtilis, P. aeruginosa, and Mycobacterium bovis.

Bacteriorhodopsin mutants of Halobacterium sp. GRB. II. Characterization of mutants.

The bacterioopsin genes of Halobacterium sp. GRB (Ebert, K., Goebel, W., and Pfeifer, F. (1984) Mol. & Gen. Genet. 194, 91-97) wild type and 10 independent mutants of different phenotypes have been cloned and sequenced. The wild type gene has two conservative changes compared to the gene of Halobacterium halobium, so that the proteins of the two species are identical. Six different mutations at five different codons have been found, leading to the following amino acid changes compared to the wild type: Trp10----Cys (three cases), Tyr57----Asn, Asp85----Glu, Asp06----Asn (three cases), Asp96----Gly, Trp138----Arg. A first characterization of the mutant proteins is given, and their implications for models of bacteriorhodopsin structure and function are discussed.