Genetic transfer of the pigment bacteriorhodopsin into the eukaryote Schizosaccharomyces pombe

The gene encoding for bacterio-opsin (bop gene) from Halobacterium halobium has been introduced in a yeast expression vector. After transformation in Schizosaccharomyces pombe, bacterio-opsin (BO) is expressed and was detected by antisera. The precursor protein of BO (pre-BO) is processed by cleavage of amino acids at the N-terminal end as in H. halobium. Addition of the chromophore, retinal, to the culture medium results in a slight purple colour of the yeast cells indicating the in vivo regeneration of BO to bacteriorhodopsin (BR) and its incorporation into membranes. Therefore, in contrast to the expression in E. coli, isolation of the membrane protein and reconstitution in lipid vesicles is not necessary for functional analysis. The kinetics of the ground state signal of the photocycle BR in protoplasts is demonstrated by flash spectroscopy and is comparable to that of the natural system. The present investigation shows for the first time the transfer of an energy converting protein from archaebacteria to eukaryotes by genetic techniques. This is a basis for further studies on membrane biogenesis, genetics, and bioenergetics by analysis of in vivo active mutants.     

细菌视紫红质的基因克隆与表达

细菌视紫红质的基因克隆与表达卢春林,汪俭,梅祺,韦钰（东南大学吴建雄实验室,南京２１０Ｏ１８）叶寅,田波（中国科学院微生物研究所,北京１０００８０）关键词细菌视紫红质基因;聚合酶链反应（ＰＣＲ）;基因克隆与表达细菌视紫红质（ｂａｅ快ｒｉｏｒｈｏｄｏＰ...     

The primary structures of helices A to G of three new bacteriorhodopsin-like retinal proteins.

The primary structures of helices A to G of all bacteriorhodopsin (BR)-like retinal proteins identified in newly isolated halobacteria have been determined from the nucleotide sequence of the BR-like protein genes. Using PCR methods, gene fragments encoding the A- to G-helix region of BR-like proteins were directly amplified from the total genomic DNA of the seven new halobacterial strains. Oligonucleotide primers corresponding to highly conserved regions in the helices A to G were designed from the nucleotide sequences of bacterioopsin (bop) and archaeopsin-I (aop-I), and some primers were effective for the amplification of the gene encoding C- to G-helix region of all new BR-like proteins. The primer corresponding to A-helix region was designed either from the nucleotide sequence of bop and aop-I or from the N-terminus amino acid sequence of a BR-like protein. Three new BR-like proteins were identified from the amino acid sequence, which was deduced from the nucleotide sequence of the genes encoding A- to G-helix region of the BR-like proteins. It was found that not only the amino acid sequence, but also the nucleotide sequence of the gene encoding the C- and G-helix region, in which a number of important residues for proton translocation are located, is highly conserved in three new BR-like proteins. Analysis of the primary structures of the A- to G-helix region of new BR-like proteins revealed that one has about 85% homology with aR-I and aR-II, and the rest have about 55% homology with halobium BR, aR-I and aR-II.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic variability in Halobacterium halobium.

Halobacterium halobium exhibits an extraordinary degree of spontaneous variability. Mutants which are defective in the formation of gas vacuoles (vac) arise at a frequency of 10(-2). Other easily detectable phenotypes, like the synthesis of bacterioruberin (Rub) or the synthesis of retinal (Ret) and bacterio-opsin (Ops), the two components which form the purple membrane (Pum) of H. halobium, are lost at a frequency of about 10(-4). With the same frequency a mutant type appears which exhibits an extremely high variability in these phenotypes. With the exception of the ret mutants, all spontaneously arising mutants show alterations, i.e., insertions, rearrangements, or deletions, in the plasmid pHH1. It appears that the introduction of one insertion into pHH1 triggers further insertions, which makes the identification of relationships between phenotypic and genotypic alterations rather difficult. From the analysis of a large number of spontaneous vac mutants and their vac+ revertants it can be concluded that the formation of the gas vacuoles is determined or controlled by plasmid genes. No such conclusion is yet possible for the rub mutants, although all mutants of this type so far analyzed exhibit a defined insertion. pum mutants which have lost the capability of forming bacterio-opsin carry insertions in the plasmid which are distributed over a rather large region of the plasmid. No strains of H. halobium could be obtained which had lost plasmid pHH1 completely.     

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.     

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.     

tfoX (sxy)-dependent transformation of Aggregatibacter (Actinobacillus) actinomycetemcomitans

tfoX (sxy) is a regulatory gene needed to turn on competence genes. Aggregatibacter (Actinobacillus) actinomycetemcomitans has a tfoX gene that is important for transformation. We cloned this gene on an IncQ plasmid downstream of the inducible tac promoter. When this plasmid was resident in cells of A. actinomycetemcomitans and tfoX was induced, the cells became competent for transformation. Several strains of A. actinomycetemcomitans, including different serotypes, as well as rough (adherent) and isogenic smooth (nonadherent) forms were tested. Only our two serotype f strains failed to be transformed. With the other strains, we could easily get transformants with extrachromosomal plasmid DNA when closed circular, replicative plasmid carrying an uptake signal sequence (USS) was used. When a replicative plasmid carrying a USS and cloned DNA from the chromosome of A. actinomycetemcomitans was linearized by digestion with a restriction endonuclease or when genomic DNA was used directly, the outcome was allelic exchange. To facilitate allelic exchange, we constructed a suicide plasmid (pMB78) that does not replicate in A. actinomycetemcomitans and carries a region with two inverted copies of a USS. This vector gave allelic exchange in the presence of cloned and induced tfoX easily and without digestion. Using transposon insertions in cloned katA DNA, we found that as little as 78 bp of homology at one of the ends was sufficient for that end to participate in allelic exchange. The cloning and induction of tfoX makes it possible to transform nearly any strain of A. actinomycetemcomitans, and allelic exchange has proven to be important for site-directed mutagenesis.     

Bacterioopsin-mediated regulation of bacterioruberin biosynthesis in Halobacterium salinarum

Integral membrane protein complexes consisting of proteins and small molecules that act as cofactors have important functions in all organisms. To form functional complexes, cofactor biosynthesis must be coordinated with the production of corresponding apoproteins. To examine this coordination, we study bacteriorhodopsin (BR), a light-induced proton pump in the halophilic archaeon Halobacterium salinarum. This complex consists of a retinal cofactor and bacterioopsin (BO), the BR apoprotein. To examine possible novel regulatory mechanisms linking BO and retinal biosynthesis, we deleted bop, the gene that encodes BO. bop deletion resulted in a dramatic increase of bacterioruberins, carotenoid molecules that share biosynthetic precursors with retinal. Additional studies revealed that bacterioruberins accumulate in the absence of BO regardless of the presence of retinal or BR, suggesting that BO inhibits bacterioruberin biosynthesis to increase the availability of carotenoid precursors for retinal biosynthesis. To further examine this potential regulatory mechanism, we characterized an enzyme, encoded by the lye gene, that catalyzes bacterioruberin biosynthesis. BO-mediated inhibition of bacterioruberin synthesis appears to be specific to the H. salinarum lye-encoded enzyme, as expression of a lye homolog from Haloferax volcanii, a related archaeon that synthesizes bacterioruberins but lacks opsins, resulted in bacterioruberin synthesis that was not reduced in the presence of BO. Our results provide evidence for a novel regulatory mechanism in which biosynthesis of a cofactor is promoted by apoprotein-mediated inhibition of an alternate biochemical pathway. Specifically, BO accumulation promotes retinal production by inhibiting bacterioruberin biosynthesis.     

An efficient system for site-directed mutagenesis to make various mutants of the env gene of human immunodeficiency virus type 1

We developed an efficient system of site-directed mutagenesis for the envelope (env) gene of human immunodeficiency virus type 1 (HIV-1). To make a template plasmid for mutagenesis, pS+B/MluI, two independent selection markers, i.e. a unique restriction site, MluI, and an in-frame termination codon, were introduced into the region encoding the V3 domain of the env gene of an HIV-1 strain, NL4-3, which had been cloned in the pUC118 plasmid. When the env gene of the pS+B/MluI plasmid was mutated successfully using mutagenic primers such as synthetic oligonucleotides or PCR-amplified DNA fragments longer than 1.5 kbp, the plasmids became resistant to digestion with MluI and competent env genes were formed by suppression of the in-frame termination. Various site-directed mutants of the env gene of HIV-1 were accurately constructed in a short time even in the absence of proper restriction sites by this system. The system of site-directed mutagenesis we reported here will be a useful method to analyze the functions of variable genes like the env gene of HIV-1 precisely and rapidly.     

Construction of a mobilizable cloning vector for site-directed mutagenesis of gram-negative bacteria: application to Rhizobium leguminosarum

A mobilizable cloning vector was constructed from defined fragments to serve as a suicide plasmid for site-directed mutagenesis. The new vector, pKOK4, closely resembles plasmid pBR325. However, the inverted duplication existing in the latter was not introduced. The useful cloning sites of pBR325 (EcoRI, HindIII, EcoRV, BamHI, SalI, PstI and PvuI) were retained and are located in one of the three resistance markers, ApR, CmR or TcR, respectively. Also, in pKOK4 the CmR gene retains its own promoter. The mob site of plasmid RP4 was introduced as a 760-bp fragment at a defined location. The mobilization frequency of pKOK4 within Escherichia coli strains is approx. 4 x 10(-2) per recipient cell. The size of pKOK4, deduced from the construction, is 6368 bp. We used pKOK4 for site-directed mutagenesis of hup-specific DNA from Rhizobium leguminosarum B10. Integration of the vector could be distinguished reliably from marker exchange by screening for the antibiotic resistance(s) of the plasmid. This reduced the number of clones to be retested by colony and Southern hybridization to approx. 1% of the original number. Of these, almost 70% contained the desired marker exchange.