Structure of the gas vesicle plasmid in Halobacterium halobium: inversion isomers, inverted repeats, and insertion sequences

Genome comparison reveals that Halobacterium salinarum 63-R2 is the origin of the twin laboratory strains NRC-1 and R1

The genome of Halobacterium strain 63-R2 was recently reported and provides the opportunity to resolve long-standing issues regarding the source of two widely used model strains of Halobacterium salinarum, NRC-1 and R1. Strain 63-R2 was isolated in 1934 from a salted buffalo hide (epithet "cutirubra"), along with another strain from a salted cow hide (91-R6^T , epithet "salinaria," the type strain of Hbt. salinarum). Both strains belong to the same species according to genome-based taxonomy analysis (TYGS), with chromosome sequences showing 99.64% identity over 1.85 Mb. The chromosome of strain 63-R2 is 99.99% identical to the two laboratory strains NRC-1 and R1, with only five indels, excluding the mobilome. The two reported plasmids of strain 63-R2 share their architecture with plasmids of strain R1 (pHcu43/pHS4, 99.89% identity; pHcu235/pHS3, 100.0% identity). We detected and assembled additional plasmids using PacBio reads deposited at the SRA database, further corroborating that strain differences are minimal. One plasmid, pHcu190 (190,816 bp) corresponds to pHS1 (strain R1) but is even more similar in architecture to pNRC100 (strain NRC-1). Another plasmid, pHcu229, assembled partially and completed in silico (229,124 bp), shares most of its architecture with pHS2 (strain R1). In deviating regions, it corresponds to pNRC200 (strain NRC-1). Further architectural differences between the laboratory strain plasmids are not unique, but are present in strain 63-R2, which contains characteristics from both of them. Based on these observations, it is proposed that the early twentieth-century isolate 63-R2 is the immediate ancestor of the twin laboratory strains NRC-1 and R1.

Acid Experimental Evolution of the Haloarchaeon Halobacterium sp. NRC-1 Selects Mutations Affecting Arginine Transport and Catabolism

Halobacterium sp. NRC-1 (NRC-1) is an extremely halophilic archaeon that is adapted to multiple stressors such as UV, ionizing radiation and arsenic exposure; it is considered a model organism for the feasibility of microbial life in iron-rich brine on Mars. We conducted experimental evolution of NRC-1 under acid and iron stress. NRC-1 was serially cultured in CM+ medium modified by four conditions: optimal pH (pH 7.5), acid stress (pH 6.3), iron amendment (600 μM ferrous sulfate, pH 7.5), and acid plus iron (pH 6.3, with 600 μM ferrous sulfate). For each condition, four independent lineages of evolving populations were propagated. After 500 generations, 16 clones were isolated for phenotypic characterization and genomic sequencing. Genome sequences of all 16 clones revealed 378 mutations, of which 90% were haloarchaeal insertion sequences (ISH) and ISH-mediated large deletions. This proportion of ISH events in NRC-1 was five-fold greater than that reported for comparable evolution of Escherichia coli. One acid-evolved clone had increased fitness compared to the ancestral strain when cultured at low pH. Seven of eight acid-evolved clones had a mutation within or upstream of arcD, which encodes an arginine-ornithine antiporter; no non-acid adapted strains had arcD mutations. Mutations also affected the arcR regulator of arginine catabolism, which protects bacteria from acid stress by release of ammonia. Two acid-adapted strains shared a common mutation in bop, which encodes bacterio-opsin, apoprotein for the bacteriorhodopsin light-driven proton pump. Thus, in the haloarchaeon NRC-1, as in bacteria, pH adaptation was associated with genes involved in arginine catabolism and proton transport. Our study is among the first to report experimental evolution with multiple resequenced genomes of an archaeon. Haloarchaea are polyextremophiles capable of growth under environmental conditions such as concentrated NaCl and desiccation, but little is known about pH stress. Interesting parallels appear between the molecular basis of pH adaptation in NRC-1 and in bacteria, particularly the acid-responsive arginine-ornithine system found in oral streptococci.

Whole-genome comparison between the type strain of Halobacterium salinarum (DSM 3754T ) and the laboratory strains R1 and NRC-1

Halobacterium salinarum is an extremely halophilic archaeon that is widely distributed in hypersaline environments and was originally isolated as a spoilage organism of salted fish and hides. The type strain 91-R6 (DSM 3754T ) has seldom been studied and its genome sequence has only recently been determined by our group. The exact relationship between the type strain and two widely used model strains, NRC-1 and R1, has not been described before. The genome of Hbt. salinarum strain 91-R6 consists of a chromosome (2.17 Mb) and two large plasmids (148 and 102 kb, with 39,230 bp being duplicated). Cytosine residues are methylated (m4 C) within CTAG motifs. The genomes of type and laboratory strains are closely related, their chromosomes sharing average nucleotide identity (ANIb) values of 98% and in silico DNA-DNA hybridization (DDH) values of 95%. The chromosomes are completely colinear, do not show genome rearrangement, and matching segments show <1% sequence difference. Among the strain-specific sequences are three large chromosomal replacement regions (>10 kb). The well-studied AT-rich island (61 kb) of the laboratory strains is replaced by a distinct AT-rich sequence (47 kb) in 91-R6. Another large replacement (91-R6: 78 kb, R1: 44 kb) codes for distinct homologs of proteins involved in motility and N-glycosylation. Most (107 kb) of plasmid pHSAL1 (91-R6) is very closely related to part of plasmid pHS3 (R1) and codes for essential genes (e.g. arginine-tRNA ligase and the pyrimidine biosynthesis enzyme aspartate carbamoyltransferase). Part of pHS3 (42.5 kb total) is closely related to the largest strain-specific sequence (164 kb) in the type strain chromosome. Genome sequencing unraveled the close relationship between the Hbt. salinarum type strain and two well-studied laboratory strains at the DNA and protein levels. Although an independent isolate, the type strain shows a remarkably low evolutionary difference to the laboratory strains.

Plasmids from Euryarchaeota

Many plasmids have been described in Euryarchaeota, one of the three major archaeal phyla, most of them in salt-loving haloarchaea and hyperthermophilic Thermococcales. These plasmids resemble bacterial plasmids in terms of size (from small plasmids encoding only one gene up to large megaplasmids) and replication mechanisms (rolling circle or theta). Some of them are related to viral genomes and form a more or less continuous sequence space including many integrated elements. Plasmids from Euryarchaeota have been useful for designing efficient genetic tools for these microorganisms. In addition, they have also been used to probe the topological state of plasmids in species with or without DNA gyrase and/or reverse gyrase. Plasmids from Euryarchaeota encode both DNA replication proteins recruited from their hosts and novel families of DNA replication proteins. Euryarchaeota form an interesting playground to test evolutionary hypotheses on the origin and evolution of viruses and plasmids, since a robust phylogeny is available for this phylum. Preliminary studies have shown that for different plasmid families, plasmids share a common gene pool and coevolve with their hosts. They are involved in gene transfer, mostly between plasmids and viruses present in closely related species, but rarely between cells from distantly related archaeal lineages. With few exceptions (e.g., plasmids carrying gas vesicle genes), most archaeal plasmids seem to be cryptic. Interestingly, plasmids and viral genomes have been detected in extracellular membrane vesicles produced by Thermococcales, suggesting that these vesicles could be involved in the transfer of viruses and plasmids between cells.

Haloarchaea and the formation of gas vesicles

Halophilic Archaea (Haloarchaea) thrive in salterns containing sodium chloride concentrations up to saturation. Many Haloarchaea possess genes encoding gas vesicles, but only a few species, such as Halobacterium salinarum and Haloferax mediterranei, produce these gas-filled, proteinaceous nanocompartments. Gas vesicles increase the buoyancy of cells and enable them to migrate vertically in the water body to regions with optimal conditions. Their synthesis depends on environmental factors, such as light, oxygen supply, temperature and salt concentration. Fourteen gas vesicle protein (gvp) genes are involved in their formation, and regulation of gvp gene expression occurs at the level of transcription, including the two regulatory proteins, GvpD and GvpE, but also at the level of translation. The gas vesicle wall is solely formed of proteins with the two major components, GvpA and GvpC, and seven additional accessory proteins are also involved. Except for GvpI and GvpH, all of these are required to form the gas permeable wall. The applications of gas vesicles include their use as an antigen presenter for viral or pathogen proteins, but also as a stable ultrasonic reporter for biomedical purposes.

Assessment of whole genome amplification-induced bias through high-throughput, massively parallel whole genome sequencing

BACKGROUND

Whole genome amplification is an increasingly common technique through which minute amounts of DNA can be multiplied to generate quantities suitable for genetic testing and analysis. Questions of amplification-induced error and template bias generated by these methods have previously been addressed through either small scale (SNPs) or large scale (CGH array, FISH) methodologies. Here we utilized whole genome sequencing to assess amplification-induced bias in both coding and non-coding regions of two bacterial genomes. Halobacterium species NRC-1 DNA and Campylobacter jejuni were amplified by several common, commercially available protocols: multiple displacement amplification, primer extension pre-amplification and degenerate oligonucleotide primed PCR. The amplification-induced bias of each method was assessed by sequencing both genomes in their entirety using the 454 Sequencing System technology and comparing the results with those obtained from unamplified controls.

RESULTS

All amplification methodologies induced statistically significant bias relative to the unamplified control. For the Halobacterium species NRC-1 genome, assessed at 100 base resolution, the D-statistics from GenomiPhi-amplified material were 119 times greater than those from unamplified material, 164.0 times greater for Repli-G, 165.0 times greater for PEP-PCR and 252.0 times greater than the unamplified controls for DOP-PCR. For Campylobacter jejuni, also analyzed at 100 base resolution, the D-statistics from GenomiPhi-amplified material were 15 times greater than those from unamplified material, 19.8 times greater for Repli-G, 61.8 times greater for PEP-PCR and 220.5 times greater than the unamplified controls for DOP-PCR.

CONCLUSION

Of the amplification methodologies examined in this paper, the multiple displacement amplification products generated the least bias, and produced significantly higher yields of amplified DNA.

Post-genomics of the model haloarchaeon Halobacterium sp. NRC-1

Halobacteriumsp. NRC-1 is an extremely halophilic archaeon that is easily cultured and genetically tractable. Since its genome sequence was completed in 2000, a combination of genetic, transcriptomic, proteomic, and bioinformatic approaches have provided insights into both its extremophilic lifestyle as well as fundamental cellular processes common to all life forms. Here, we review post-genomic research on this archaeon, including investigations of DNA replication and repair systems, phototrophic, anaerobic, and other physiological capabilities, acidity of the proteome for function at high salinity, and role of lateral gene transfer in its evolution.

Arsenic resistance in Halobacterium sp. strain NRC-1 examined by using an improved gene knockout system

The genome sequence of Halobacterium sp. strain NRC-1 encodes genes homologous to those responsible for conferring resistance to arsenic. These genes occur on both the large extrachromosomal replicon pNRC100 (arsADRC and arsR2M) and on the chromosome (arsB). We studied the role of these ars genes in arsenic resistance genetically by construction of gene knockouts. Deletion of the arsADRC gene cluster in a Halobacterium NRC-1 Deltaura3 strain resulted in increased sensitivity to arsenite and antimonite but not arsenate. In contrast, knockout of the chromosomal arsB gene did not show significantly increased sensitivity to arsenite or arsenate. We also found that knockout of the arsM gene produced sensitivity to arsenite, suggesting a second novel mechanism of arsenic resistance involving a putative arsenite(III)-methyltransferase. These results indicate that Halobacterium sp. strain NRC-1 contains an arsenite and antimonite extrusion system with significant differences from bacterial counterparts. Deletion analysis was facilitated by an improved method for gene knockouts/replacements in Halobacterium that relies on both selection and counterselection of ura3 using a uracil dropout medium and 5-fluoroorotic acid. The arsenite and antimonite resistance elements were shown to be regulated, with resistance to arsenic in the wild type inducible by exposure to a sublethal concentration of the metal. Northern hybridization and reverse transcription-PCR analyses showed that arsA, arsD, arsR, arsM, arsC, and arsB, but not arsR2, are inducible by arsenite and antimonite. We discuss novel aspects of arsenic resistance in this halophilic archaeon and technical improvements in our capability for gene knockouts in the genome.

Understanding the adaptation of Halobacterium species NRC-1 to its extreme environment through computational analysis of its genome sequence

The genome of the halophilic archaeon Halobacterium sp. NRC-1 and predicted proteome have been analyzed by computational methods and reveal characteristics relevant to life in an extreme environment distinguished by hypersalinity and high solar radiation: (1) The proteome is highly acidic, with a median pI of 4.9 and mostly lacking basic proteins. This characteristic correlates with high surface negative charge, determined through homology modeling, as the major adaptive mechanism of halophilic proteins to function in nearly saturating salinity. (2) Codon usage displays the expected GC bias in the wobble position and is consistent with a highly acidic proteome. (3) Distinct genomic domains of NRC-1 with bacterial character are apparent by whole proteome BLAST analysis, including two gene clusters coding for a bacterial-type aerobic respiratory chain. This result indicates that the capacity of halophiles for aerobic respiration may have been acquired through lateral gene transfer. (4) Two regions of the large chromosome were found with relatively lower GC composition and overrepresentation of IS elements, similar to the minichromosomes. These IS-element-rich regions of the genome may serve to exchange DNA between the three replicons and promote genome evolution. (5) GC-skew analysis showed evidence for the existence of two replication origins in the large chromosome. This finding and the occurrence of multiple chromosomes indicate a dynamic genome organization with eukaryotic character.

Genomic perspective on the photobiology of Halobacterium species NRC-1, a phototrophic, phototactic, and UV-tolerant haloarchaeon

Halobacterium species display a variety of responses to light, including phototrophic growth, phototactic behavior, and photoprotective mechanisms. The complete genome sequence of Halobacterium species NRC-1 (Proc Natl Acad Sci USA 97: 12176-12181, 2000), coupled with the availability of a battery of methods for its analysis makes this an ideal model system for studying photobiology among the archaea. Here, we review: (1) the structure of the 2.57 Mbp Halobacterium NRC-1 genome, including a large chromosome, two minichromosomes, and 91 transposable IS elements; (2) the purple membrane regulon, which programs the accumulation of large quantities of the light-driven proton pump, bacteriorhodopsin, and allows for a period of phototrophic growth; (3) components of the sophisticated pathways for color-sensitive phototaxis; (4) the gas vesicle gene cluster, which codes for cell buoyancy organelles; (5) pathways for the production of carotenoid pigments and retinal, (6) processes for the repair of DNA damage; and (7) putative homologs of circadian rhythm regulators. We conclude with a discussion of the power of systems biology for comprehensive understanding of Halobacterium NRC-1 photobiology.

Genome sequence of Halobacterium species NRC-1

We report the complete sequence of an extreme halophile, Halobacterium sp. NRC-1, harboring a dynamic 2,571,010-bp genome containing 91 insertion sequences representing 12 families and organized into a large chromosome and 2 related minichromosomes. The Halobacterium NRC-1 genome codes for 2,630 predicted proteins, 36% of which are unrelated to any previously reported. Analysis of the genome sequence shows the presence of pathways for uptake and utilization of amino acids, active sodium-proton antiporter and potassium uptake systems, sophisticated photosensory and signal transduction pathways, and DNA replication, transcription, and translation systems resembling more complex eukaryotic organisms. Whole proteome comparisons show the definite archaeal nature of this halophile with additional similarities to the Gram-positive Bacillus subtilis and other bacteria. The ease of culturing Halobacterium and the availability of methods for its genetic manipulation in the laboratory, including construction of gene knockouts and replacements, indicate this halophile can serve as an excellent model system among the archaea.

IS1675, a novel lactococcal insertion element, forms a transposon-like structure including the lacticin 481 lantibiotic operon

Two copies of IS1675, a novel lactococcal insertion element from the IS4 family, are present on a 70-kb plasmid, where they frame the lantibiotic lacticin 481 operon. The whole structure could be a composite transposon designated Tn5721. This study shows that the lacticin 481 operon does not include any regulatory gene and provides a new example of a transposon-associated bacteriocin determinant. We identified five other IS1675 copies not associated with the lacticin 481 operon. The conservation of IS1675 flanking sequences suggested a 24-bp target site.

ISBst12, a novel type of insertion-sequence element causing loss of S-layer-gene expression in Bacillus stearothermophilus ATCC 12980

The cell surface of the surface layer (S-layer)-carrying strain of Bacillus stearothermophilus ATCC 12980 is completely covered with an oblique lattice composed of the S-layer protein SbsC. In the S-layer-deficient strain, theS-layer gene sbsC was still present but was interrupted by a novel type of insertion sequence (IS) element designated ISBst12. The insertion site was found to be located within the coding region of the sbsC gene, 199 bp downstream from the translation start of SbsC. ISBst12 is 1612 bp long, bounded by 16 bp imperfect inverted repeats and flanked by a directly repeated 8 bp target sequence. ISBst12 contains an ORF of 1446 bp and is predicted to encode a putative transposase of 482 aa with a calculated theoretical molecular mass of 55562 Da and an isoelectric point of 9.13. The putative transposase does not exhibit a typical DDE motif but displays aHis-Arg-Tyr triad characteristic of the active site of integrases from the bacteriophage lambda Int family. Furthermore, two overlapping leucine-zipper motifs were identified at the N-terminal part of the putative transposase. As revealed by Southern blotting, ISBst12 was present in multiple copies in the S-layer-deficient strain as well as in the S-layer-carrying strain. Northern blotting indicated that S-layer gene expression is already inhibited at the transcriptional level, since no sbsC-specific transcript could be identified in the S-layer-deficient strain. By using PCR, ISBst12 was also detected in B. stearothermophilus PV72/p6, in its oxygen-induced strain variant PV72/p2 and in the S-layer-deficient strain PV72/T5.

Stationary-phase variation due to transposition of novel insertion elements in Xanthomonas oryzae pv. oryzae

Xanthomonas oryzae pv. oryzae causes bacterial leaf blight, a serious disease of rice. Spontaneous mutants which are deficient for virulence and extracellular polysaccharide (Eps) production accumulate in large numbers in stationary-phase cultures of this bacterium, a phenomenon which we have called stationary-phase variation. A clone (pSD1) carrying the Eps biosynthetic gene (gum) cluster of X. oryzae pv. oryzae restored Eps production and virulence to several spv (for stationary-phase variation) mutants. Data from localized recombination analysis, Southern hybridization, PCR amplification, and sequence analysis showed that the mutations are due to insertion of either one of two novel endogenous insertion sequence (IS) elements, namely, ISXo1 and ISXo2, into gumM, the last gene of the gum gene cluster. The results of Southern analysis indicate the presence of multiple copies of both IS elements in the genome of X. oryzae pv. oryzae. These results demonstrate the role of IS elements in stationary-phase variation in X. oryzae pv. oryzae.

Divergence of the hyperthermophilic archaea Pyrococcus furiosus and P. horikoshii inferred from complete genomic sequences

Divergence of the hyperthermophilic Archaea, Pyrococcus furiosus and Pyrococcus horikoshii, was assessed by analysis of complete genomic sequences of both species. The average nucleotide identity between the genomic sequences is 70-75% within ORFs. The P. furiosus genome (1.908 mbp) is 170 kbp larger than the P. horikoshii genome (1.738 mbp) and the latter displays significant deletions in coding regions, including the trp, his, aro, leu-ile-val, arg, pro, cys, thr, and mal operons. P. horikoshii is auxotrophic for tryptophan and histidine and is unable to utilize maltose, unlike P. furiosus. In addition, the genomes differ considerably in gene order, displaying displacements and inversions. Six allelic intein sites are common to both Pyrococcus genomes, and two intein insertions occur in each species and not the other. The bacteria-like methylated chemotaxis proteins form a functional group in P. horikoshii, but are absent in P. furiosus. Two paralogous families of ferredoxin oxidoreductases provide evidence of gene duplication preceding the divergence of the Pyrococcus species.

Sequence analysis of cytochrome bd oxidase suggests a revised topology for subunit I

Numerous sequences of the cytochrome bd quinol oxidase (cytochrome bd) have recently become available for analysis. The analysis has revealed a small number of conserved residues, a new topology for subunit I and a phylogenetic tree involving extensive horizontal gene transfer. There are 20 conserved residues in subunit I and two in subunit II. Algorithms utilizing multiple sequence alignments predicted a revised topology for cytochrome bd, adding two transmembrane helices to subunit I to the seven that were previously indicated by the analysis of the sequence of the oxidase from E. coli. This revised topology has the effect of relocating the N-terminus and C-terminus to the periplasmic and cytoplasmic sides of the membrane, respectively. The new topology repositions I-H19, the putative ligand for heme b595, close to the periplasmic edge of the membrane, which suggests that the heme b595/heme d active site of the oxidase is located near the outer (periplasmic) surface of the membrane. The most highly conserved region of the sequence of subunit I contains the sequence GRQPW and is located in a predicted periplasmic loop connecting the eighth and ninth transmembrane helices. The potential importance of this region of the protein was previously unsuspected, and it may participate in the binding of either quinol or heme d. There are two very highly conserved glutamates in subunit I, E99 and E107, within the third transmembrane helix (E. coli cytochrome bd-I numbering). It is speculated that these glutamates may be part of a proton channel leading from the cytoplasmic side of the membrane to the heme d oxygen-reactive site, now placed near the periplasmic surface. The revised topology and newly revealed conserved residues provide a clear basis for further experimental tests of these hypotheses. Phylogenetic analysis of the new sequences of cytochrome bd reveals considerable deviation from the 16sRNA tree, suggesting that a large amount of horizontal gene transfer has occurred in the evolution of cytochrome bd.

Snapshot of a large dynamic replicon in a halophilic archaeon: megaplasmid or minichromosome?

Extremely halophilic archaea, which flourish in hypersaline environments, are known to contain a variety of large dynamic replicons. Previously, the analysis of one such replicon, pNRC100, in Halobacterium sp. strain NRC-1, showed that it undergoes high-frequency insertion sequence (IS) element-mediated insertions and deletions, as well as inversions via recombination between 39-kb-long inverted repeats (IRs). Now, the complete sequencing of pNRC100, a 191,346-bp circle, has shown the presence of 27 IS elements representing eight families. A total of 176 ORFs or likely genes of 850-bp average size were found, 39 of which were repeated within the large IRs. More than one-half of the ORFs are likely to represent novel genes that have no known homologs in the databases. Among ORFs with previously characterized homologs, three different copies of putative plasmid replication and four copies of partitioning genes were found, suggesting that pNRC100 evolved from IS element-mediated fusions of several smaller plasmids. Consistent with this idea, putative genes typically found on plasmids, including those encoding a restriction-modification system and arsenic resistance, as well as buoyant gas-filled vesicles and a two-component regulatory system, were found on pNRC100. However, additional putative genes not expected on an extrachromosomal element, such as those encoding an electron transport chain cytochrome d oxidase, DNA nucleotide synthesis enzymes thioredoxin and thioredoxin reductase, and eukaryotic-like TATA-binding protein transcription factors and a chromosomal replication initiator protein were also found. A multi-step IS element-mediated process is proposed to account for the acquisition of these chromosomal genes. The finding of essential genes on pNRC100 and its property of resistance to curing suggest that this replicon may be evolving into a new chromosome.

Organization, generation and replication of amphimeric genomes: a review

Genomes comprising a pair of separated inverted repeats and called 'amphimers' are reviewed. Amphimeric genomes are observed in a large variety of different organisms, ranging from archaebacteria to mammals. The widespread existence of amphimeric genomes in nature could be due to their particular dynamic structure. Amphimeric genomes containing long inverted segments may provide the only form in which a duplicated segment is stably retained in genomes. Amphimers are often found in amplified subgenomes, indicating that they could promote a special mechanism of DNA replication and amplification. The possible mechanisms of generation, isomerization and replication/amplification of different types of amphimeric genomes are discussed. The study of amphimeric mitochondrial petite genomes of yeast could be a good model system for the study of the role of inverted repeat sequences in genome dynamics.

Sizing chromosomes and megaplasmids in haloarchaea

PFGE was used for the genomic analysis of different species and strains belonging to four out of the six recognized haloarchaeal (halobacterial) genera. All of them were found to carry one chromosome from 1.8-3 Mb, and usually several, but at least one, large plasmids of approximately 90-680 kb, which were detected in supercoiled and linear forms. From the data gathered, chromosomal size appears to be conserved at genus level, whereas plasmid composition and size seems to be subjected to certain variability.

Wild-type gas vesicle formation requires at least ten genes in the gvp gene cluster of Halobacterium halobium plasmid pNRC100

To study the functions of the 13 gvp genes, gvpMLKJIHGFEDACN, on plasmid pNRC100 of Halobacterium halobium in gas vesicle formation, we carried out linker scanning mutagenesis of the gene cluster. We constructed a 24.5-kb Escherichia coli-H. halobium shuttle plasmid, pFL2, containing the gvp gene cluster and introduced a kanamycin resistance (kappa) cassette into each gene (except for gvpA). Transformation of H. halobium SD109, which had the entire gvp gene cluster deleted, with pFL2 and mutated pFL2 derivatives showed that while the unmutated gene cluster successfully programmed gas vesicle formation, derivatives with insertion of the kappa cassette in any of the gvp genes, except gvpM, did not lead to production of normal gas vesicles. Insertions in gvpL, -K, -J, -I, and -F resulted in a complete block in gas vesicle synthesis, while insertions in gvpH, -G, -E, -D, -C, and -N resulted in greatly reduced gas vesicle synthesis. In most cases, the block in gas vesicle synthesis did not result from polar effects, since similar results were obtained for derivatives of the insertion mutants in which most of the internal portion of the kappa cassette was deleted and only small (15 to 54-bp) insertions remained. The only exceptions were for gvpH and gvpD, where deletion of the internal portion of the kappa insertions resulted in phenotypic reversion. Electron microscopic analysis of the kappa mutants revealed that interruptions of gvpC and gvpN result in the formation of smaller gas vesicle than in the wild type, while interruptions of gvpF, -G, -H, -J, -K, and -L produce no discernible vesicle intermediates. These results indicate the gvpA, -C, and -N, which have the rightward transcriptional orientation, encode structural proteins, with gvpC and gvpN necessary for late stages of vesicle formation, and gvpL, -K, -J, -I, -H, -G, and -F, which have the leftward transcriptional orientation encode proteins involved in early steps in the assembly of gas vesicles.

DNA rearrangements and phenotypic switching in prokaryotes

Microorganisms have numerous strategies for coping with environmental changes. In many systems, a single cell has the capacity to generate a seemingly infinite array of phenotypic variants in just a few generations of growth. The resulting heterogeneous population is well equipped for sudden environmental change; even if only a few cells in the population possess a phenotype needed for survival, these cells have the capacity to regenerate a similarly diverse population. Phenotypic switching in these systems usually results from high-frequency DNA rearrangements which are the subject of this review.

Minimal replication origin of the 200-kilobase Halobacterium plasmid pNRC100

We have identified the replication origin of pNRC100, a 200-kb plasmid of Halobacterium halobium, by assaying for replication ability of miniplasmids containing cloned fragments of pNRC100 and the mevinolin resistance selectable marker of Haloferax volcanii. First, we showed the replication ability of plasmid pNGHCMEV1, which contains the 19-kb HindIII-C fragment of pNRC100, by recovery of plasmid DNA from mevinolin-resistant transformants of H. halobium. The minimal replication origin of approximately 3.9 kb was defined by subcloning successively smaller regions of pNGHCMEV1 and assaying for plasmid replication in either H. halobium or H. volcanii. The same replication origin was also recovered after transformation of H. volcanii with a library of partial Sau3AI fragments of pNRC100. The nucleotide sequence of the minimal replication origin was determined and found to contain a long open reading frame, named repH, transcribed away from a highly A+T-rich region. The transcription start site was identified by primer extension analysis to be 17 to 18 nucleotides 5' to a putative repH start codon. The predicted product of the repH gene, an acidic protein with a molecular weight of 113,442, showed 24 to 27% identity with predicted gene products of H. volcanii plasmid pHV2 and H. halobium plasmid p phi HL, suggesting that each is involved in plasmid replication. One pNRC100 minireplicon, pNG11 delta 12, was analyzed by linker scanning mutagenesis, which showed the requirement of repH for replication. Restoration of the repH reading frame of one replication-defective pNG11 delta 12 derivative by introduction of a second small insertion resulted in reversion to replication proficiency. The replication ability of pNG11delta12 was lost when the entire A+T-rich region, about 550 bp long, was deleted but not when small insertions or deletions were introduced into this region. The presence of only 52 bp of the A+T-rich segment was sufficient to permit replication. The pNG11delta12 minireplicon was lost at high frequency from cells grown without mevinolin selection, suggesting that the plasmid partitioning locus of pNRC100 is absent in the minimal replication origin region. We discuss the possible roles of the repH gene and the A+T-rich region in replication of pNRC100.

Identification and analysis of the gas vesicle gene cluster on an unstable plasmid of Halobacterium halobium

In our efforts to elucidate the mechanism of high-frequency mutation of Halobacterium halobium to a gas vesicle deficient state, we discovered insertions, deletions, inversions, and complex DNA rearrangements associated with a large endogenous plasmid, pNRC100. The rearrangements are mostly IS element-mediated, and when they occur in a region of pNCRC100 containing a cluster of thirteen genes, gas vesicle mutants result. We have characterized the structure and expression of this gas vesicle protein (gvp) gene cluster and demonstrated its requirement for gas vesicle synthesis and cell flotation by genetic transformation.

Plasmid pHH1 of Halobacterium salinarium: characterization of the replicon region, the gas vesicle gene cluster and insertion elements

The DNA sequence of the 5.7 kb plasmid pHH9 containing the replicon region of the 150 kb plasmid pHH1 from Halobacterium salinarium was determined. The minimal region necessary for stable plasmid maintenance lies within a 2.9 kb fragment, as defined by transformation experiments. The DNA sequence contained two open reading frames arranged in opposite orientations, separated by an unusually high AT-rich (60-70% A+T) sequence of 350 bp. All H. salinarium strains (H. halobium, H. cutirubrum) investigated harbour endogenous plasmids containing the pHH1 replicon; however, these pHH1-type plasmids differ by insertions and deletions. Adjacent to the replicon, and separated by a copy of each of the insertion elements ISH27 and ISH26, is the 9 kb p-vac region required for gas vesicle synthesis. Analysis of these and other ISH element copies in pHH1 revealed that most of them lack the target DNA duplication usually found with recently transposed ISH elements. These results underline the plasticity of plasmid pHH1.

Gene replacement in Halobacterium halobium and expression of bacteriorhodopsin mutants

A gene replacement method has been developed to express bacteriorhodopsin mutants in the archaeon Halobacterium halobium. Selectable plasmids carrying the bacterioopsin gene (bop) were integrated at the chromosomal bop locus of H. halobium. Under nonselective conditions, recombinants were isolated that had lost the integrated plasmid and retained a single chromosomal copy of the bop gene. This approach was used to construct a bop deletion strain. By using this strain, recombinants were obtained that express wild-type bacteriorhodopsin and mutants known to be defective in proton translocation. The expressed proteins were purified in a membrane fraction similar to purple membrane and were characterized in this form. UV/visible spectra of dark- and light-adapted bacteriorhodopsin from wild-type and Asp-96 mutants were identical to those of purple membrane. Arg-82, Asp-85, and Asp-212 mutants had 10- to 50-nm red shifts in their absorption maxima and showed altered light adaptation. The proton translocation activity of the wild-type samples and purple membrane was comparable, whereas the mutants had 0-60% of wild-type activity. These results support earlier studies of proton translocation mutants expressed in Escherichia coli.

Further characterization of a large inverted repeat in the mitochondrial genomes of Agaricus bisporus (= A. brunnescens) and related species

The mitochondrial (mt) genome of Agaricus bisporus Ag50 (a heterokaryon) is a 136-kilobase (kb) circular molecule which contains a pair of large inverted repeats (IRs). Two large BAMHI fragments (B1 and B2) which contain the IR regions were further mapped. The repeated regions were determined to be approximately 7.7 kb in length. The mt small ribosomal RNA (S rRNA) gene is located adjacent to one of the repeated regions. Orientational isomers, generated by homologous recombination between the repeated regions, were not observed in mtDNA extractions from Ag50 mycelium (liquid culture) or from Ag50 fruit bodies. We also did not observe any orientational isomers in Ag50HA or Ag50HB, two homokaryons somatically isolated from Ag50. DNA homologous to the Ag50 mt repeated regions was observed in ten other isolates of Agaricus including four isolates of A. bisporus, two isolates of A. subperonatus, two isolates of A. subfloccosus, one isolate of A. bitorquis, and one isolate of A. pattersonae. The repeated regions and the small unique regions in two other heterokaryotic strains of A. bisporus, Ag2 and Ag85, were physically mapped. The repeated regions in these two strains are also in the inverted forms. Restriction endonuclease mapping indicated that the two copies of the IR in Ag85 were not identical.

The rightward gas vesicle operon in Halobacterium plasmid pNRC100: identification of the gvpA and gvpC gene products by use of antibody probes and genetic analysis of the region downstream of gvpC

The extreme halophile Halobacterium halobium synthesizes intracellular gas-filled vesicles that confer buoyancy. A cluster of 13 genes on the 200-kb endogenous plasmid pNRC100 has been implicated in the biosynthesis of gas vesicles. Here, we show that two gas vesicle proteins are encoded by genes in the rightward operon, gvpA and gvpC, by Western blotting (immunoblotting) analysis with antibodies directed against LacZ-GvpA and LacZ-GvpC fusion proteins. Our results are consistent with previous data showing that the gvpA gene product is the major gas vesicle protein and demonstrate for the first time that the gvpC gene product is also present in H. halobium gas vesicles. Northern (RNA) blotting analysis showed two RNA species, an abundant 0.35-kb transcript of gvpA and a minor 2.5-kb transcript of gvpAC, and a third gene 3' to gvpAC, named gvpN. The gvpN gene encodes a hypothetical acidic protein with a molecular weight of 39,000 and a nucleotide binding motif. We used a site-directed mutagenesis method involving double recombination in Escherichia coli to insert a kanamycin resistance cassette just beyond the stop codon of gvpN. Introduction of the mutated gene cluster into an H. halobium mutant with a deletion of the entire gas vesicle gene cluster resulted in gas vesicle-positive transformants; this result suggests that gvpN is the last gene of the rightward gas vesicle transcription unit. We discuss the design and utility of the kanamycin resistance cassette for the mutagenesis of other genes in large operons.

Genetic transformation of a halophilic archaebacterium with a gas vesicle gene cluster restores its ability to float

The halophilic archaebacterium, Halobacterium halobium, and many other aquatic bacteria synthesize gas-filled vesicles for flotation. We recently identified a cluster of 13 genes (gvpMLKJIHGFEDACN) on a 200-kb H. halobium plasmid, pNRC100, involved in gas vesicle synthesis. We have cloned and reconstructed the gvp gene cluster on an H. halobium-E. coli shuttle plasmid. Transformation of H. halobium Vac- mutants lacking the entire gas vesicle gene region with the gvp gene cluster results in restoration of their ability to float. These results open the way toward further genetic analysis of gas vesicle gene functions and directed flotation of other microorganisms with potential biotechnological applications.

Genomic organization of the halophilic archaeon Haloferax mediterranei: physical map of the chromosome

Pulsed field gel electrophoresis (PFG) has been used to study the genomic organization of the halophilic archaeon Haloferax mediterranei. Analysis of the different genomic elements as well as the restriction patterns obtained with several endonucleases revealed that this microorganism has a circular chromosome of 2.9 Mb and, at least, three extrachromosomal elements of 490, 320 and 130 kb respectively. The complete physical map of the chromosome for the endonucleases PacI and BamHI has been constructed, and several BcII, BgIII and DraI restriction fragments have been aligned on these maps. The localization of heterologous and homologous genes on the physical map, including those for rRNA, lay the ground work for the construction of a genetic map.

Structure and organization of the gas vesicle gene cluster on the Halobacterium halobium plasmid pNRC100

Halobacterium halobium strain NRC-1 contains intracellular gas-filled vesicles (GVs) that confer buoyancy to the cells. Cloning of the major GV protein (GvpA)-encoding gene, gvpA, and analysis of GV-deficient mutants (Vac-) of H. halobium led to the identification of a region of a 200-kb plasmid, pNRC100, important for GV synthesis. We report here the nucleotide sequence of an 8520-bp region which, including gvpA, contains twelve open reading frames (ORFs) that are organized into two divergent transcription units, gvpAC oriented rightward, and gvpD, E, F, G, H, I, J, K, L, and M located upstream from gvpAC and oriented leftward. Insertions into the gvpA promoter and gvpD and E resulted in the Vac- phenotype. The overall gene organization is highly compact with the end of one ORF overlapping with the beginning of the next in most cases. The gene cluster is bracketed by two ISH8 element copies in inverted orientation, an organization suggestive of a composite transposon. Comparison of predicted amino acid sequences showed homology between GvpA, and the gvpJ and gvpM putative gene products. The putative gvpC gene product contains eight copies of an imperfectly repeated sequence with similarity to repeats in a cyanobacterial GvpC plus a highly acidic C-terminal region not found in the cyanobacterial homologue.