Insertion elements and deletion formation in a halophilic archaebacterium

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.

Copy number variation is associated with gene expression change in archaea

Genomic instability, although frequently deleterious, is also an important mechanism for microbial adaptation to environmental change. Although widely studied in bacteria, in archaea the effect of genomic instability on organism phenotypes and fitness remains unclear. Here we use DNA segmentation methods to detect and quantify genome-wide copy number variation (CNV) in large compendia of high-throughput datasets in a model archaeal species, Halobacterium salinarum. CNV hotspots were identified throughout the genome. Some hotspots were strongly associated with changes in gene expression, suggesting a mechanism for phenotypic innovation. In contrast, CNV hotspots in other genomic loci left expression unchanged, suggesting buffering of certain phenotypes. The correspondence of CNVs with gene expression was validated with strain- and condition-matched transcriptomics and DNA quantification experiments at specific loci. Significant correlation of CNV hotspot locations with the positions of known insertion sequence (IS) elements suggested a mechanism for generating genomic instability. Given the efficient recombination capabilities in H. salinarum despite stability at the single nucleotide level, these results suggest that genomic plasticity mediated by IS element activity can provide a source of phenotypic innovation in extreme environments.

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.

Novel pili-like surface structures of Halobacterium salinarum strain R1 are crucial for surface adhesion

It was recently shown that haloarchaeal strains of different genera are able to adhere to surfaces and form surface-attached biofilms. However, the surface structures mediating the adhesion were still unknown. We have identified a novel surface structure with Halobacterium salinarum strain R1, crucial for surface adhesion. Electron microscopic studies of surface-attached cells frequently showed pili-like surface structures of two different diameters that were irregularly distributed on the surface. The thinner filaments, 7–8 nm in diameter, represented a so far unobserved novel pili-like structure. Examination of the Hbt. salinarum R1 genome identified two putative gene loci (pil-1 and pil-2) encoding type IV pilus biogenesis complexes besides the archaellum encoding fla gene locus. Both pil-1 and pil-2 were expressed as transcriptional units, and the transcriptional start of pil-1 was identified. In silico analyses revealed that the pil-1 locus is present with other euryarchaeal genomes whereas the pil-2 is restricted to haloarchaea. Comparative real time qRT-PCR studies indicated that the general transcriptional activity was reduced in adherent vs. planktonic cells. In contrast, the transcription of pilB1 and pilB2, encoding putative type IV pilus assembly ATPases, was induced in comparison to the archaella assembly/motor ATPase (flaI) and the ferredoxin gene. Mutant strains were constructed that incurred a flaI deletion or flaI/pilB1 gene deletions. The absence of flaI caused the loss of the archaella while the additional absence of pilB1 led to loss of the novel pili-like surface structures. The ΔflaI/ΔpilB1 double mutants showed a 10-fold reduction in surface adhesion compared to the parental strain. Since surface adhesion was not reduced with the non-archaellated ΔflaI mutants, the pil-1 filaments have a distinct function in the adhesion process.

Expression of multiple tfb genes in different Halobacterium salinarum strains and interaction of TFB with transcriptional activator GvpE

Halobacterium salinarum NRC-1 contains multiple TBP and TFB proteins required for the recruitment of RNA polymerase for transcription initiation. The presence and the expression of genes encoding TFB were investigated in the two Hbt. salinarum strains NRC-1 and PHH1 and the mutant strain PHH4. The plasmid-encoded tfbC and tfbE genes of NRC-1 were lacking in PHH1 and PHH4. The 5'-end of the tfbF transcript was determined and contained a 5'-untranslated region of 39 nucleotides able to form a stem-loop structure. The expression of these tfb genes was studied in cultures growing at 15, 37°C and under heat shock conditions. Cold temperatures reduced growth and except for tfbF also the amounts of all tfb transcripts. However, the formation of gas vesicles increased in PHH1 and NRC-1. Heat shock reduced growth of PHH1 and NRC-1, but PHH4 was not affected. A 100-fold increase in tfbA and tfbB mRNA was observed in PHH1 and PHH4, whereas NRC-1 reduced the amounts of these transcripts and increased the expression of tfbG. All TFB proteins tested were able to interact with the transcription activator GvpE involved in gas vesicle formation that thus is able to recruit TFB to the gvp promoter.

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.

Proteome Analysis of Halobacterium sp. NRC-1 Facilitated by the Biomodule Analysis Tool BMSorter

To better understand the extremely halophilic archaeon Halobacterium species NRC-1, we analyzed its soluble proteome by two-dimensional liquid chromatography coupled to electrospray ionization tandem mass spectrometry. A total of 888 unique proteins were identified with a ProteinProphet probability (P) between 0.9 and 1.0. To evaluate the biochemical activities of the organism, the proteomic data were subjected to a biological network analysis using our BMSorter software. This allowed us to examine the proteins expressed in different biomodules and study the interactions between pertinent biomodules. Interestingly an integrated analysis of the enzymes in the amino acid metabolism and citrate cycle networks suggested that up to eight amino acids may be converted to oxaloacetate, fumarate, or oxoglutarate in the citrate cycle for energy production. In addition, glutamate and aspartate may be interconverted from other amino acids or synthesized from citrate cycle intermediates to meet the high demand for the acidic amino acids that are required to build the highly acidic proteome of the organism. Thus this study demonstrated that proteome analysis can provide useful information and help systems analyses of organisms.

Characterization of a novel plasmid from extremely halophilic Archaea: nucleotide sequence and function analysis

We determined the complete nucleotide sequence of the 16341 bp plasmid pHH205 of the extremely halophilic archaeon Halobacterium salinarum J7. The plasmid has a G+C content of 61.1%. A number of direct and inverted repeat sequences were found in pHH205, while no insertion sequences were found. Thirty-eight large open reading frames (ORFs) were identified in both strands, and most of them had no significant similarities to known proteins. A putative protein encoded by ORF31 showed 20-41% homology to some hypothetical proteins, which are annotated in several archaeal genome databases as predicted nucleic acid-binding proteins containing PIN domain. Sequence analysis using the GC skew procedure predicted a possible origin of replication. A 4.8 kb PvuII-SnaBI fragment containing both this region and ORF31 was shown to be able to restore replicate of pWL102, a replicon-deficient plasmid in Haloferax volcanii and in H. salinarum R1. Several methods failed to completely cure H. salinarum J7 of pHH205, suggesting that the plasmid probably played an important role in the growth and metabolism of the host. Our work describes a novel haloarchaeal replicon, which may be useful in the construction of cloning and shuttle vectors.

Spontaneous mutations in gas vesicle genes of Planktothrix spp. affect gas vesicle production and critical pressure

Wild-type strains of the cyanobacterium Planktothrix rubescens have a cluster of gas vesicle (gvp) genes with repeats of alternating gvpA and gvpC. The gvpC occurs in three length variants, all with the same 3'-sequence, OmegaC. Spontaneous non-buoyant mutants had lost some of the alternating gvpAC copies and their gvpC genes had a novel 3'-end sequence, PsiC; additional gvpC genes terminating in this sequence were also found in the wild-type and representatives of other GV genotypes. Alleles of gvpC terminating in PsiC occurred only at the downstream ends of the gvpAC clusters investigated; all other gvpCs terminated in OmegaC. Mutants of strains with the GV3 genotype produced only 30-50% of the gas vesicles present in the wild-type; their gas vesicles had lower mean critical pressures (0.70-0.78 MPa) than those in the wild-type (1.05-1.10 MPa).

Use of a halobacterial bgaH reporter gene to analyse the regulation of gene expression in halophilic archaea

The bgaH reading frame encoding a beta-galactosidase of 'Haloferax alicantei' was used as a reporter gene to investigate three different promoter regions derived from gvpA genes of Haloferax mediterranei (mc-gvpA) and Halobacterium salinarum (c-gvpA and p-gvpA) in Haloferax volcanii transformants. The fusion of bgaH at the start codon of each gvpA reading frame (A1-bgaH fusion genes) caused translational problems in some cases. Transformants containing constructs with fusions further downstream in the gvpA reading frame (A-bgaH) produced beta-galactosidase, and colonies on agar plates turned blue when sprayed with X-Gal. The beta-galactosidase activities quantified by standard ONPG assays correlated well with the mRNA data determined with transformants containing the respective gvpA genes: the cA-bgaH fusion gene was completely inactive, the mcA-bgaH transformants showed low amounts of products, whereas the pA-bgaH fusion gene was constitutively expressed in the respective transformants. The transcription of each A-bgaH gene was activated by the homologous transcriptional activator protein GvpE. The cGvpE, pGvpE and mcGvpE proteins were able to activate the promoter of pA-bgaH and mcA-bgaH, whereas the promoter of cA-bgaH was only activated by cGvpE. Among the three GvpE proteins tested, cGvpE appeared to be the strongest transcriptional activator.

Gene amplification and genomic plasticity in prokaryotes

Gene amplification is a common feature of the genome of prokaryotic organisms. In this review, we analyze different instances of gene amplification in a variety of prokaryotes, including their mechanisms of generation and biological role. Growing evidence supports the concept that gene amplification be considered not as a mutation but rather as a dynamic genomic state related to the adaptation of bacterial populations to changing environmental conditions or biological interactions. In this context, the potentially amplifiable DNA regions impose a defined dynamic structure on the genome. If such structure has indeed been selected during evolution, it is a particularly challenging hypothesis.

Transcript analysis of the c-vac region and differential synthesis of the two regulatory gas vesicle proteins GvpD and GvpE in Halobacterium salinarium PHH4

Halobacterium salinarium PHH4 synthesizes gas vesicles in the stationary growth phase by the expression of 14 gyp genes arranged in two clusters. The chromosomal gvpACNO (c-gvpACNO) gene cluster (encoding the major structural gas vesicle protein GvpA and the minor structural protein GvpC was transcribed as three mRNA species starting at one promoter during the stationary phase of growth. The second gene cluster, c-gvpDEFGHIKLM), was transcribed during all stages of growth as a relatively unstable, single mRNA with a maximal length of 6 kb. In addition, a 1.7-kb c-gvpD transcript was synthesized during stationary growth starting at the same promotor as that of the cgvpDEFGHIJKLM mRNA. The expression of the first two genes located in this unit (c-gvpD and c-gvpE) was also monitored by Western blot (immunoblot) analyses using antisera raised against these proteins synthesized in Escherichia coli. While the cGvpD protein was present only during early exponential growth and disappeared during gas vesicle formation, the cGvpE protein was present during cGvpA and gas vesicle synthesis in the early stationary phase of growth. Previous data indicated that cGvpD is involved in repression of gas vesicle formation, whereas cGvpE is a transcriptional activator for the c-gvpA promoter. The appearance of both proteins during the growth cycle is in line with the functions of these proteins in gas vesicle synthesis. The mechanism of the differential translation of cGvpD and cGvpE from the c-gvpDEFGHIJKLM rnRNA still has to be elucidated, but antisense RNAs complementary to the 5' terminus as well as the 3' portion of the c-gvpD mRNA might be involved in this regulation. Such RNAs occurred during early stationary growth when the cGvpD protein level decreased and may possibly inhibit the translation of the c-gvpD mRNA.

Conservation of chromosomal arrangement among three strains of the genetically unstable archaeon Halobacterium salinarium

Phenotypic variants of Halobacterium salinarium NRC-1 arise at a frequency of 10(-2). These result from transpositions of halobacterial insertion sequences and rearrangements mediated by halobacterial insertion sequences. We have tested the hypothesis that such mutations are confined to only a portion of the genome by comparing the chromosomal restriction map of H. salinarium NRC-1 and that of the derivative S9, which was made in 1969. The two chromosomes were mapped by using two-dimensional pulsed-field gel electrophoresis and the restriction enzymes AflII, AseI, and DraI. A comparison of the two deduced maps showed a domain of about 210 kbp to be subject to many rearrangements, including an inversion in S9 relative to NRC-1. However, the rest of the chromosome was conserved among NRC-1, S9, and an independent Halobacterium isolate, GRB, previously mapped by St. Jean et al. (A. St. Jean, B. A. Trieselmann, and R. L. Charlebois, Nucleic Acids Res. 22:1476-1483, 1994). This concurs with data from eubacteria suggesting strong selective forces maintaining gene order even in the face of rearrangement events occurring at a high frequency.

An insertion element of the extremely thermophilic archaeon Sulfolobus solfataricus transposes into the endogenous beta-galactosidase gene

Three phenotypically stable mutants of the extremely thermophilic archaeon Sulfolobus solfataricus have been isolated by screening for beta-galactosidase negative colonies on plates with X-Gal (5-bromo-4-chloro-3-indolyl-beta-D- galactopyranoside). From one of these mutants an insertion element, designated ISC1217, was isolated and characterized. Sequence analysis of ISC1217 and of the regions adjacent to the insertion site in the beta-galactosidase gene revealed features typical of a transposable element: ISC1217 contained terminal inverted repeats and was flanked by a direct repeat of 6 bp. The 1147 bp sequence contained an open reading frame encoding a putative protein of 354 amino acid residues and, overlapping this, two smaller open reading frames on the opposite strand. There were approximately 8 copies of the insertion element in the S. solfataricus genome. ISC1217 did not cross-hybridize with DNA of other Sulfolobus species. All three independently isolated beta-galactosidase mutants of S. solfataricus arose by transposition of ISC1217 or a related element.

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.

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.

Function and biosynthesis of gas vesicles in halophilic Archaea

The proteinaceous gas vesicles produced by various microorganisms including halophilic Archaea are hollow, gas-filled structures with a hydrophobic inner and a hydrophilic outer surface. The structural components of gas vesicles and their biosynthesis are still under investigation; an 8-kDa polypeptide appears to be the major constituent of the gas-vesicle envelope. Genetic analysis of the halobacterial gas-vesicle synthesis revealed an unexpected complexity: about 14 genes organized in three transcription units are involved in gas-vesicle structure, assembly, and gene regulation. Here we describe the comparison of three different genomic regions encoding gas vesicles in Halobacterium salinarium (p-vac and c-vac regions) and Haloferax mediterranei (mc-vac region) and speculate on the function of the gene products involved in gas-vesicle synthesis.

High-frequency rearrangements in the chromosome of Mycoplasma pulmonis correlate with phenotypic switching

Mycoplasma pulmonis is a murine pathogen that causes chronic respiratory disease in laboratory rats and mice. Several examples of high-frequency phenotypic switching have been reported for M. pulmonis, the molecular basis of which is unknown. We report here that during growth the M. pulmonis chromosome undergoes DNA rearrangements at a high frequency. Some of the rearrangements we examined correlated with changes in the susceptibility of the cells to mycoplasma virus P1, an example of phenotypic switching involving changes in surface antigen structure. Other rearrangements, unrelated to phenotypic switching, involved a DNA element present in the chromosome in multiple copies. The high level of DNA recombination that occurred in M. pulmonis indicates that this may be one of the most variable genomes studied to date. High levels of DNA recombination may contribute to the unusually high rate of evolution that mycoplasmas are thought to be undergoing. Understanding the molecular basis for this phenomenon may provide an insight into the chronic nature of many mycoplasmal infections.

A DNA region of 9 kbp contains all genes necessary for gas vesicle synthesis in halophilic archaebacteria

We determined the minimal size of the genomic region necessary for gas vesicle synthesis in halophilic archaebacteria by transformation experiments, comparative DNA sequence analysis and investigation of gas vesicle (Vac) mutants. The comparison of the three genomic regions encoding gas vesicles in Halobacterium halobium (p-vac- and c-vac-region) and Haloferax mediterranei (mc-vac-region) indicates high DNA sequence similarity throughout a contiguous sequence of 9 kbp. In each case, this area encompassed at least 13 open reading frames (ORFs). Ten of these ORFs (gvpD to gvpM) were located 5' to the vac gene encoding the major gas vesicle protein, but were transcribed from the opposite strand. At least two ORFs (gvpC, and gvpN) were located 3' to each vac gene and transcribed from the same strand as the respective vac gene. In the p-vac-region present on plasmid pHH1 these ORFs were transcribed as at least three units, one transcript encompassing gvpD-gvpE, the second encompassing ORFs gvpF to gvpM, and the third unit comprising the ORFs located 3' to the p-vac gene. In H. halobium Vac mutants copies of the insertion elements ISH2, ISH23, ISH26 or ISH27 were found to be integrated throughout the p-vac-region. The de novo synthesis of gas vesicles was tested by transformation of the Vac-negative species, Haloferax volcanii, with various subfragments of the mc-vac- or p-vac-region cloned into vector plasmids. In contrast to a fragment containing the entire 9 kbp region, none of the subfragments tested was sufficient to promote gas vesicle synthesis. However, gas vesicle synthesis could be restored in each Vac mutant containing an ISH element when the entire transcription unit encompassing the mutated gene on pHH1 was present in the wild-type form on the vector construct.

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

Halobacterium-halobium NRC-1 harbors a 200-kb plasmid, pNRC100, which contains a cluster of genes for synthesis of buoyant gas-filled vesicles. Physical mapping of pNRC100 by using pulsed-field gel electrophoresis showed the presence of a large (35 to 38-kb) inverted repeat (IR) sequence. Inversion isomers of pNRC100 were demonstrated by Southern hybridization analysis using two restriction enzymes, AflII and SfiI, that cut asymmetrically within the intervening small single-copy region and the large single-copy region, respectively, but not within the large IRs. No inversion isomers were observed for a deletion derivative of pNRC100 lacking one IR, which suggests that both copies are required for inversion to occur. Additionally, the identities and approximate positions of 17 insertion sequences (IS) in pNRC100 were determined by Southern hybridization and limited nucleotide sequence analysis across the IS element-target site junctions: ISH2, a 0.5-kb element, was found in four copies; ISH3, a 1.4-kb heterogeneous family of elements, was present in seven copies; ISH8, a 1.4-kb element, was found in five copies; and ISH50, a 1.0-kb element, was present in a single copy. The large IRs terminated at an ISH2 element at one end and an ISH3 element at the other end. pNRC100 is similar in structure to chloroplast and mitochondrial genomes, which contain large IRs and other large halobacterial and prokaryotic plasmids that are reservoirs of IS elements but lack the large IRs.

Transposition burst of the ISH27 insertion element family in Halobacterium halobium

Investigation of the plasmid pHH4 in single colonies of Halobacterium halobium PHH4 indicated transposition of insertion elements in 20% of the colonies. Seven ISH27 insertions were observed as well as one ISH23 insertion. The various copies of ISH27 were compared to the two ISH27 elements already present in pHH4, and to the ISH27 element that was identified in the bacteriopsin (bop) gene of a Bop mutant. These ten copies of ISH27 constitute three types on the basis of DNA sequence identity: ISH27-1 (1398 bp), ISH27-2, and ISH27-3 (1389 bp each). The DNA sequence comparison between the three types indicates a region of 1200 bp where the identity between ISH27-1 and ISH27-2 or ISH27-3 is 82-83%. ISH27-2 and ISH27-3 are 95% identical in this region. The remaining region exhibits a lower DNA similarity (64-74% identity) between the different copies. An open reading frame of 1167 nucleotides spans the more conserved region, and a corresponding transcript could be detected in H. halobium PHH4, but not in H. halobium wild-type. ISH27-1 is 91% identical to members of the insertion sequence-like elements ISH51 of Haloferax volcanii, whereas the other two ISH27 element types are 82-83% identical to ISH51. The transposition 'burst' of ISH27 was only seen after storage of the cells for more than two years at 4 degrees C. Upon continuous cultivation at 37 degrees C no transposition event could be observed, suggesting that stress factor(s) might have caused the high transposition rate.

Transformation of Halobacterium halobium: development of vectors and investigation of gas vesicle synthesis

We developed vector plasmids for the transformation of Halobacterium halobium, using the replicon region from the halobacterial phage H or from the plasmid pHH1 together with a DNA fragment conferring resistance to mevinolin. H. halobium P03, a strain lacking pHH1 as well as the restriction endonuclease activity found in wild-type H. halobium, was used as the recipient strain. All H. halobium fragments tested for autonomous replication as well as the Haloferax volcanii vector pWL102 enabled stable plasmid maintenance in this strain. A frequent loss of all vectors (including pWL102) was observed in Hf. volcanii, where >90% of the mevinolin-resistant colonies obtained after transformation had lost the vector, presumably because of restriction endonuclease activity and concomitant recombination of the mevinolin resistance marker with the chromosome. The expression of gas vesicle-encoding genes (vac) was analyzed by using a 4.5-kilobase-pair (kbp) fragment containing the plasmid-encoded p-vac gene from H. halobium or an 11-kbp fragment containing the mc-vac chromosomal gene from Haloferax mediterranei for transformation experiments with H. halobium and Hf. volcanii. These experiments indicated that the mc-vac fragment contains all information necessary to synthesize gas vesicles, whereas in the case of the smaller p-vac fragment, complementation by other genes was required for a Vac+ phenotype.