Genetic variability in Halobacterium halobium

Transcription of genes involved in bacterio-opsin gene expression in mutants of a halophilic archaebacterium

Recent studies on the regulation of the bacterio-opsin (bop) gene of the archaebacterium Halobacterium halobium suggest that the brp and putative bat genes are involved in bop gene expression or purple membrane assembly. These two genes are located 526 and 1,602 base pairs, respectively, upstream of the bop gene and are both transcribed in the opposite orientation to the bop gene. Transcription of the bop, brp, and putative bat genes was characterized in the wild type, 11 Bop mutants, and a Bop revertant by using a series of RNA probes. Quantitation of the relative mRNA levels for these three genes in the wild type revealed that the brp and bat transcripts are present at approximately 2 and 4%, respectively, of bop mRNA levels under the growth conditions used. Northern (RNA) blot analysis of Bop mutants indicated that insertions in the brp gene affect expression of the putative bat gene. In addition, deletion of most of the bat gene resulted in virtually undetectable levels of bop and brp mRNAs. These and other results lead us to propose that (i) brp gene expression can affect bat gene expression and (ii) the putative bat gene is involved in activating bop and brp gene expression.

Characterization of a second gene involved in bacterio-opsin gene expression in a halophilic archaebacterium

Southern blot analysis and nucleotide sequencing of DNA from three bacterio-opsin-deficient mutants of the archaebacterium Halobacterium halobium (M86, W105, and W109) revealed that they each contain an alteration in a region 2,000 to 3,800 base pairs (bp) upstream of the bacterio-opsin gene (bop). Nucleotide sequence analysis of this region, which is also located downstream of the previously characterized brp gene, revealed that it contains an open reading frame (ORF) of 2,022 bp. This 2,022-bp ORF has a start codon which overlaps the stop codon of the brp gene and is read in the same direction. The ORF could encode an acidic protein of 73,334 daltons (674 amino acids) with a predicted secondary structure typical of a soluble protein. Bop mutant M86 contains a 1,883-bp deletion extending from bp 351 of the ORF, to 197 bp beyond the stop codon. Mutant W105 has an ISH2 element integrated at bp 1239 of the ORF, and mutant W109 has an ISH26 element integrated at bp 1889. Our results suggest that the ORF is a gene (designated bat for bacterio-opsin activator gene) involved in bop gene expression.

Dynamic plasmid populations in Halobacterium halobium

Deletion events occurring in the major 150-kilobase-pair (kb) plasmid pHH1 of the archaebacterium Halobacterium halobium were investigated. We found four deletion derivatives of pHH1 in gas-vacuole-negative mutants, two of which (pHH23) [65 kb] and pHH4 [36 kb]) we analyzed. Both plasmids incurred more than one deletion, leading to the fusion of noncontiguous pHH1 sequences. pHH23 and pHH4 overlapped by only 4 kb of DNA sequence. A DNA fragment derived from this region was used to monitor the production of further deletion variants of pHH4. A total of 25 single colonies were characterized, 23 of which contained various smaller pHH4 derivatives. Of the 25 colonies investigated, 2 had lost pHH4 entirely and contained only large (greater than or equal to 100-kb) minor covalently closed circular DNAs. One colony contained the 17-kb deletion derivative pHH6 without any residual pHH4. The sizes of the pHH4 deletion derivatives, produced during the development of a single colony, ranged from 5 to 20 kb. In five colonies, pHH4 was altered by the integration of an additional insertion element. These insertions, as well as copies of the various insertion elements already present in pHH4, presumably serve as hot spots for recombination events which result in deletions. A second enrichment procedure led to the identification of colonies containing either a 16-kb (pHH7) or a 5-kb (pHH8) deletion derivative of pHH4 as the major plasmid. pHH8, the smallest plasmid found, contained the 4 kb of unique DNA sequence shared by pHH23 and pHH4, as well as some flanking pHH4 sequences. This result indicates that the 4-kb region contains the necessary sequences for plasmid maintenance and replication.

Two genes encoding gas vacuole proteins in Halobacterium halobium

The archaebacterium Halobacterium halobium contains two related gas vacuole protein-encoding genes (vac). One of these genes encodes a protein of 76 amino acids and resides on the major plasmid. The second gene is located on the chromosome in a (G + C)-rich DNA fraction and encodes a slightly larger but highly homologous protein consisting of 79 amino acids. The plasmid encoded vac gene is transcribed constitutively throughout the growth cycle while the chromosomal vac gene is expressed during the stationary phase of growth. Comparison of the nucleotide sequences of the two genes indicates differences in the putative promoter regions as well as 35 single base-pair exchanges within the coding regions of the two genes. The majority of the nucleotide exchanges in the coding region occur in the third position of a codon triplet generating the codon synonym. The only differences between the two encoded proteins are the exchange of 2 amino acids (positions 8 and 29) and a deletion of 3 amino acids near the carboxy-terminus of the plasmid encoded vac protein. The genomic DNAs from other halobacterial isolates (Halobacterium sp. SB3, GN101 and YC819-9) were found to contain only a chromosomal vac gene copy. There is a high conservation of the chromosomal vac gene and the genomic region surrounding it among the halobacterial strains investigated.

Evidence for two different gas vesicle proteins and genes in Halobacterium halobium

Most halobacteria produce gas vesicles (GV). The well-characterized species Halobacterium halobium and some GV+ revertants of GV- mutants of H. halobium produce large amounts of GV which have a spindlelike shape. Most other GV+ revertants of H. halobium GV- mutants and other recently characterized halobacterial wild-type strains possess GV with a cylindrical form. The number of intact particles in the latter isolates is only 10 to 30% of that of H. halobium. Analysis of GV envelope proteins (GVPs) by electrophoresis on phenol-acetic acid-urea gels showed that the GVP of the highly efficient GV-producing strains migrated faster than the GVP of the low-GV-producing strains. The relative molecular mass of the GVP was estimated to be 19 kilodaltons (kDa) for high-producing strains (GVP-A) and 20 kDa for low-producing strains (GVP-B). Amino acid sequence analysis of the first 40 amino acids of the N-terminal parts of GVP-A and GVP-B indicated that the two proteins differed in two defined positions. GVP-B, in relation to GVP-A, had Gly-7 and Val-28 always replaced by Ser-7 and Ile-28, respectively. These data suggest that at least two different gvp genes exist in H. halobium NRL. This was directly demonstrated by hybridization experiments with gvp-specific DNA probes. A fragment of plasmid pHH1 and a chromosomal fragment of H. halobium hybridized to the probes. Only a chromosomal fragment hybridized to the same gyp probes when both chromosomal and plasmid DNAs from the low-GV-producing halobacterial wild-type strains SB3 and GN101 were examined. These findings support the assumption that GVP-A is expressed by a pHH1-associated gvp gene and GVP-B by a chromosomal gvp gene.

A plasmid-encoded gas vesicle protein gene in a halophilic archaebacterium

The halophilic archaebacterium, Halobacterium halobium, displays spontaneous and revertible genetic variability for the gas vesicle phenotype (Vac) at frequencies as high as 0.5 to 5%. To investigate the mechanism of these high-frequency mutations, we have cloned a gas vesicle protein gene (gvpA) from the Vac+ wild-type H. halobium strain, NRC-1, and determined its nucleotide sequence, transcription start site, and genomic location. The gene sequence predicts that the gas vesicle protein has a molecular weight of 9156 and is relatively hydrophobic except for a hydrophilic C-terminal region. Northern hybridization analysis shows that the gene is transcribed into a 350-nucleotide mRNA, and primer extension analysis indicates that transcription begins 20 nucleotides upstream of the ATG start codon. Southern hybridization analysis shows that the gene is encoded by a large H. halobium plasmid. We discuss potential mechanisms for genetic variability of the Vac phenotype and identify sequences in the gvpA promoter region which may function as signals for transcription in H. halobium.

Insertion-sequence-dependent rearrangements of Pseudomonas cepacia plasmid pTGL1

Pseudomonas cepacia 249 (ATCC 17616) harbors a 170-kilobase (kb) plasmid designated pTGL1. We identified three insertion sequences, IS405, IS408, and IS411, on this plasmid. Various prototrophic and auxotrophic derivatives in our collection contained variants of pTGL1 formed by accretion and deletion of other elements. Plasmid pTGL6, the variant in one prototroph, evolved from pTGL1 by the addition of three copies of IS401 (1.3 kb) and one of IS402 (1 kb), to generate pTGL5, and recombination between two of the copies of IS401 on pTGL5 to form pTGL6. The latter event entailed loss of one copy of IS401 and an additional 5.4 kb of plasmid DNA. Derivatives of the broad-host-range plasmid pRP1 carrying the above insertion sequences and recombinant plasmids carrying fragments of plasmids pTGL6 and pTGL5 were used as probes to ascertain the extent of reiteration of the various elements in the P. cepacia genome. The data indicate a high frequency of genomic rearrangements which presumably contributes to the extraordinary adaptability of this bacterium.

ISH51: a large, degenerate family of insertion sequence-like elements in the genome of the archaebacterium, Halobacterium volcanii

We describe a new family of repetitive elements in the genome of the archaebacterium Halobacterium volcanii. There are some 20-30 copies of this element, which we designate ISH51. Sequenced copies show typical insertion sequence characteristics (terminal inverted repeats, direct flanking repeats of "target site" DNA). However, members of the ISH51 family are highly heterogeneous, showing on average only 85% primary sequence homology; and some genomic copies appear to be severely truncated. Some ISH51 elements are clustered together in regions of relatively AT-rich DNA. There are at least five such AT-rich "islands" in the H. volcanii genome. Repetitive sequences homologous to ISH51 are found in the genomes of most Halobacterium and Halococcus species.

Genetic rearrangements of a Rhizobium phaseoli symbiotic plasmid

Different structural changes of the Sym plasmid were found in a Rhizobium phaseoli strain that loses its symbiotic phenotype at a high frequency. These rearrangements affected both nif genes and Tn5 mob insertions in the plasmid, and in some cases they modified the expression of the bacterium's nodulation ability. One of the rearrangements was more frequent in heat-treated cells, but was also found under standard culture conditions; other structural changes appeared to be related to the conjugal transfer of the plasmid.

Alkalophilic Bacillus firmus RAB generates variants which can grow at lower Na+ concentrations than the parental strain

Obligately alkalophilic Bacillus firmus RAB cannot grow well on media containing less than 5 mM Na+. However, variant strains can be isolated on plates containing 2 to 3 mM Na+. These variants are observed only rarely in cultures that are plated before being subjected to repeated transfers in liquid medium. Cultures which have been transferred several times produce variants at an apparent frequency of 2 X 10(-4). Most of these variants are unstable, generating parental types at the high frequency of 10%; however, stable variants can be isolated. These strains grow better than the parental strain at very high pH values in the presence of 5 mM Na+ and have enhanced activity of the Na+ -H+ antiporter that has been implicated in pH homeostasis. By contrast, Na+ -coupled solute uptake is indistinguishable from that of the parental strain, and no obvious changes in the respiratory chain components are apparent in reduced versus oxidized difference spectra. The membranes of the variants show a marked enhancement, on sodium dodecyl sulfate-polyacrylamide gradient electrophoresis, in one polypeptide band with a molecular weight in the range of 90,000. The findings are discussed from the point of view of genetic mechanisms that might confer adaptability to even more extreme environments than usual and in view of earlier models relating the Na+ -translocating activities of the alkalophiles.

Molecular cloning and nucleotide sequence of a developmentally regulated gene from the cyanobacterium Calothrix PCC 7601: a gas vesicle protein gene

Since the gas vesicle protein (GVP) is highly conserved among the different gas-vacuolate prokaryotes, a 29-mer oligonucleotide corresponding to a portion of the Anabaena flos-aquae GVP gene was synthesized and used to isolate the GVP structural gene from Calothrix PCC 7601 (= Fremyella diplosiphon). Gas vacuole production in this filamentous cyanobacterium is restricted to hormogonia which occur at a specific stage during the developmental cell cycle. The GVP gene (gvpA) was localized on a 709 bp HindIII-HincII fragment. Nucleotide sequence analysis revealed a 213 bp open reading frame whose deduced amino-acid sequence shows a very high homology with that of the Anabaena flos-aquae GVP. Assuming that the first methionine residue is proteolytically processed, the molecular mass of the Calothrix GVP is 7375 daltons. Sequences resembling the Escherichia coli consensus promoter were found upstream from the gvpA gene. The initiator codon of the gvpA gene is preceded by a polypurine sequence assumed to be the ribosome binding site. Southern hybridizations with a probe specific for the gvpA gene indicated that this gene is not plasmid-borne, and that another homologous gene is present in the Calothrix genome.

Restoration of bacterioopsin gene expression in a revertant of Halobacterium halobium

Restoration of bacterioopsin (bop) gene expression in a revertant of Halobacterium halobium was investigated. The phenotype of the revertant is the result of a translocation of the 588-base-pair (bp) sequence "ISH25", adjacent to an ISH24 insertion found in the parental mutant IV-4. These insertions are located about 1,400 bp upstream of the bop gene within the coding region of the putative brp (bacterioopsin-related protein) gene. The level at which the brp gene affects bop gene expression is unknown. Analysis of bop and brp gene transcription in the wild type, mutant IV-4, and the revertant supports the hypothesis that transcription of the putative brp gene is necessary for bop gene expression in the revertant. Eight insertion mutants of the Bop revertant were analyzed to further elucidate restoration of bop gene expression in the revertant. Bop mutants of the revertant were recovered with a frequency of about 10(-4) and were found to contain insertion elements in addition to ISH24 and "ISH25". Six-eighths of these mutants have the insertion element ISH2, and two mutants have previously uncharacterized insertion elements (ISH27 [1,400 bp] and ISH28 [1,000 bp]). ISH27 and ISH28 are confined to the more A + T-rich fraction of the H. halobium genome, as are most copies of other halobacterial insertion elements. The insertion sites in the Bop mutants of the revertant mapped within the coding region of the bop gene (three mutants), immediately upstream of the bop gene presumably in the bop promoter region (two mutants), or within a region from 241 to 449 bp upstream of the bop gene (three mutants). This distribution of insertion sites suggests that the integrity of the 526-bp region between the bop and the brp genes is important for bop gene expression in the revertant.

Evidence for two restriction-modification systems in Halobacterium cutirubrum

Data from plating experiments indicated that Halobacterium cutirubrum NRC34001 has at least two separate restriction-modification systems. A spontaneous or induced loss of one or both systems resulted in four restriction-modification phenotypes. There was a positive correlation between changes in gas vacuolation phenotypes and either restriction-modification system.

Genome organization in Halobacterium halobium: a 70 kb island of more (AT) rich DNA in the chromosome

The more A + T rich fractionated component (FII DNA) of the Halobacterium halobium genome constitutes one third of the total DNA and upon isolation consists of covalently closed circular DNA (pHH1 and minor cccDNA) and nonsupercoiled sequences. We have investigated the physical organization of the non cccDNA in FII by a chromosome walk using one copy of the halobacterial insertion element ISH1 as a start point. This chromosome walk led to the isolation of 160 kb of chromosomal DNA containing 70 kb of FII DNA covalently linked to more G + C rich sequences (FI DNA). Copies of three previously characterized insertion elements (ISH1, ISH2, and ISH26) as well as at least 10 other repeated sequences are clustered within this chromosomal FII DNA "island". Unique sequences are found in the FI DNA flanking the FII DNA island as well as in 40 kb of FI DNA surrounding the bacterio-opsin gene. The presence of pHH1 in H. halobium and closely related species correlates with the occurrence of the characterized chromosomal FII DNA island. Halophilic purple membrane producing isolates YC81819-9, GN101, SB3 and GRA lack pHH1 and the 70 kb FII DNA, but contain all of the FI DNA sequences tested. We propose that pHH1 and this chromosomal FII DNA are characteristic genomic components of H. halobium and closely related species, and, that the 70 kb FII DNA might represent a large insertion in the chromosome of H. halobium and closely related species. The conservation of both FI and FII DNA sequences can be used for strain classification and determination of evolutionary relationships among halo-bacteria.

Characterization of a halobacterial gene affecting bacterio-opsin gene expression

A substantial number of spontaneous bacterio-opsin mutants of Halobacterium halobium are the result of insertion elements up to 1400 bp upstream of the bacterio-opsin (bop) gene. The nucleotide sequence of 1800 bp upstream of the bop gene has been determined. There is a 1118 bp open reading frame (ORF) located within this region which is transcribed and which coincides with the distribution of insertion elements upstream of the bop gene in Bop mutants. Therefore, we propose that there is a gene (brp gene) 526 bp upstream of the bop gene. This putative gene is transcribed in the opposite direction as the bop gene and could encode a protein of 37,500 D (359 amino acids) with a codon usage similar to bacterio-opsin. The 5' terminus of the brp transcript has been determined. The brp transcript and the bop mRNA are complementary for 13 residues near their 5' termini and both transcripts start at or near the initiating codon of the gene. Both transcripts could form similar hairpin loop structures at their 5' termini which contain possible ribosomal binding sites. The DNA sequences immediately upstream of the bop and the brp genes have significant homologies and there is a short complementary sequence. The role of the brp gene in bacterio-opsin gene expression is unclear.

Photoreactivation in pigmented and non-pigmented extreme halophiles

The sensitivity to ultraviolet radiation (254 nm) and the photoreactivability of four pigmented and three colourless strains of the extremely halophilic bacteria Halobacterium cutirubrum and Halobacterium salinarium have been studied. The results with three pigmented/non-pigmented pairs show that the pigments play an accessory role in photoreactivation at low visible light intensities and confirm that they do not provide passive protection against ultraviolet light. Evidence is presented that photoreactivation plays an unexpected direct role in the resistance of extreme halophiles to ultraviolet radiation and that colourless mutants of H. cutirubrum NRC 34001 only arise in cultures that have been both ultraviolet-irradiated and photoreactivated. None of these extreme halophiles is capable of excision repair of ultraviolet damage to DNA.

Characterization of insertions affecting the expression of the bacterio-opsin gene in Halobacterium halobium

We have determined the sequence of the inverted repeats and duplicated target DNA of the halobacterial insertion elements ISH2 (520 bp), ISH23 (900 bp) and ISH24 (3000 bp) associated with bacterio-opsin (bop) mutants. ISH2 has a perfect 19 bp inverted repeat (3,5), while both ISH23 and ISH24 have imperfect inverted repeats of 29 bp and 14 bp respectively. ISH23 was shown to be highly homologous to ISH50 (6). Variable lengths of duplicated target DNA are found when ISH2 and ISH23 (ISH50) transpose into different sites. A 550 bp DNA insert ("ISH25") reverts the Bop mutation caused by ISH24. "ISH25" lacks typical structural features of a transposable element. "ISH25" and ISH24 are found adjacent to each other upstream of the bop gene. An identical arrangement of "ISH25" and ISH24 is found in the cccDNA of H. halobium NRC817. Comparative sequence analysis of both areas suggests that the translocation of "ISH25" to the bop gene region occurred by a recombination event.

Phototrophic growth of halobacteria and its use for isolation of photosynthetically-deficient mutants

Phototrophic growth conditions for halobacteria in complex and synthetic media have been established, demonstrating the photosynthetic capacity of this class of archaebacteria. Mutagenesis, 5-bromo-2'-deoxyuridine selection and screening techniques are described which are useful tools in the elucidation of the structure-function relationship of retinal proteins in halobacteria.

Structure of the archaebacterial transposable element ISH50

We have sequenced in its entirety a new transposable element from the archaebacterium Halobacterium halobium. This 996 bp element shows some features not unlike those of insertion sequences from eubacteria, although it clearly differs from them in sequences which may be involved in transcription and or translation initiation.

High-frequency spontaneous mutation in the bacterio-opsin gene in Halobacterium halobium is mediated by transposable elements

We have recently characterized a transposable element, ISH1, which inactivates the bacterio-opsin (BO) gene in two purple membrane-deficient (Pum-) mutants of Halobacterium halobium. Examination of nine additional Pum- mutants now shows that in all of these the BO gene has been inactivated by insertion of one of two types of transposable elements. Four Pum- strains contain ISH1 within the BO gene, probably at the same site that we have previously characterized. A second element, ISH2, which is present in four more strains, inserts at multiple sites within the BO coding sequence. Significantly, another Pum- strain contains the ISH2 element 102 nucleotides upstream from the initiator codon for BO. ISH2, which is 520 nucleotides long, is the smallest insertion sequence known. Its sequence has been determined: it is A + T-rich (53%), contains a 19-base-pair inverted repeat at its termini, and, interestingly, duplicates either 10 or 20 base pairs at the target site during insertion. ISH2 is present in multiple copy numbers in the genome and contains several relatively short open reading frames.

Light as an Energy Source in Continuous Cultures of Bacteriorhodopsin-Containing Halobacteria

The role of light as an energy source for slightly aereated cultures of halobacteria was studied, using continuous cultures with low nutrient concentrations and a low oxygen supply. A series of experiments were carried out with non-illuminated and differently illuminated cultures and with different oxygen transfer rates. Under low oxygen availability, light proved to be a decisively important energy source that allowed the populations to reach higher growth rates and much higher population densities. Oxygen influenced the growth over only a minimal level, below which neither the illuminated nor the dark cultures were affected by the oxygen transfer rate. From these results, it appears that the bacteriorhodopsin-mediated energy supply could have a very important role for the ecology of halobacteria in their microaerophilic habitats. In the illuminated cultures, cells that originated purple colonies on plates appeared. These cells, which could be bacteriorhodopsin-constitutive mutants, are now being studied.

A transposable element from Halobacterium halobium which inactivates the bacteriorhodopsin gene

We describe the characterization of a transposable element from an archaebacterium. The bacteriorhodopsin genes from the wild-type and two mutant Halobacterium halobium strains have been cloned as BamHI fragments in pBR322. The cloned DNA fragments from the two mutants both contain a 1.1-kilobase-pair insertion sequence (ISH1) near the NH2 terminus of the bacteriorhodopsin coding sequence. ISH1 is present in the two mutants in an identical palindromic site but in opposite orientations. The complete sequence of ISH1 has been determined; it is 1,118 nucleotides long, it has 8-base-pair interrupted inverted repeats at the ends, and it duplicates an 8-base-pair (A-G-T-T-A-T-T-G) target sequence upon insertion. As for most eukaryotic and some prokaryotic transposable elements, the sequence of the ISH1 begins with T-G and ends in C-A. ISH1 contains an open reading frame 810 nucleotides long and codes for an RNA approximately 900 nucleotides long. The copy number of ISH1 ranges from one to five or more in different H. halobium strains. In at least one of the strains, one copy of ISH1 is present also on a plasmid DNA.

High-frequency genomic rearrangements involving archaebacterial repeat sequence elements

Halobacterium halobium is an obligately halophilic archaebacterium of interest to molecular biologists for many reasons, one of which is the unexplained high frequency (10(-4)-10(-2) mutants per cell plated) at which it yields readily identifiable and unstable mutants. We showed previously that the genome of H. halobium contains many (greater than 50) families of repeated sequences whose members are dispersed on both chromosome and plasmid. Here we report that most if not all of the members of most of these repeat sequence families effect or are affected by spontaneous genomic rearrangements. Quantitative analyses show that such repeat sequence-associated rearrangements (which may be of several kinds) occur at high frequencies (greater than 4 x 10(-3) events per family per cell generation), while unique-sequence DNAs are physically stable. The presence of so many families of elements of such great instability in the halobacterial genome gives it an unusual degree of structural and perhaps functional plasticity.

Unusual physical organization of the Halobacterium genome

The genomes of the extremely halophilic bacteria, Halobacterium halobium and Halobacterium volcanii, contain many repeated sequences. These sequences comprise many families, seem to be highly mobile and are arranged in both clustered and dispersed fashions within these genomes. At least some repeated sequences are more strongly conserved between the two species than are unique sequence DNAs.

Characterization of plasmids in halobacteria

Extrachromosomal, covalently closed circular deoxyribonucleic acid has been isolated from different species of halobacteria. Three strains of Halobacterium halobium and one of Halobacterium cutirubrum, all of which synthesize purple membrane (Pum+) and bacterioruberin (Rub+), contain plasmids of different size which share extensive sequence homologies. One strain of Halobacterium salinarium, another one of Halobacterium capanicum, and two new Halobacterium isolates from Tunisia, which are also Pum+ Rub+, do not harbor covalently closed circular deoxyribonucleic acid but contain sequences, presumably integrated into the chromosome, which are similar if not identical to those of pHH1, i.e., the plasmid originally isolated from H. halobium. Three other halophilic strains, Halobacterium trapanicum, Halobacterium volcanii, and a new isolate from Israel, do not carry pHH1-like sequences. These strains are, by morphological and physiological criteria, different from the others examined and harbor plasmids unrelated to pHH1.