The bacterial attachment site of the temperate Rhizobium phage 16-3 overlaps the 3′ end of a putative proline tRNA gene

Bacteriophage 16-3 inserts its genome into the chromosome of Rhizobium meliloti strain 41 (Rm41) by site-specific recombination. The DNA regions around the bacterial attachment site (attB) and one of the hybrid attachment sites bordering the integrated prophage (attL) were cloned and their nucleotide sequences determined. We demonstrated that the 51 by region, where the phage and bacterial DNA sequences are identical, is active as a target site for phage integration. Furthermore it overlaps the 3′ end of a putative proline tRNA gene. This gene shows 79% similartiy to the corresponding proline tRNA-like genomic target sequence of certain integrative plasmids in Actinomycetes.     

Site-specific integrative elements of rhizobiophage 16-3 can integrate into proline tRNA (CGG) genes in different bacterial genera.

The integrase protein of the Rhizobium meliloti 41 phage 16-3 has been classified as a member of the Int family of tyrosine recombinases. The site-specific recombination system of the phage belongs to the group in which the target site of integration (attB) is within a tRNA gene. Since tRNA genes are conserved, we expected that the target sequence of the site-specific recombination system of the 16-3 phage could occur in other species and integration could take place if the required putative host factors were also provided by the targeted cells. Here we report that a plasmid (pSEM167) carrying the attP element and the integrase gene (int) of the phage can integrate into the chromosomes of R. meliloti 1021 and eight other species. In all cases integration occurred at so-far-unidentified, putative proline tRNA (CGG) genes, indicating the possibility of their common origin. Multiple alignment of the sequences suggested that the location of the att core was different from that expected previously. The minimal attB was identified as a 23-bp sequence corresponding to the anticodon arm of the tRNA.     

Isolation and characterization of an R-prime plasmid from Rhizobium meliloti.

Using a simple enrichment procedure, we isolated an R-prime derivative of plasmid R68.45 carrying a 17.8-megadalton segment of the Rhizobium meliloti 41 chromosome. The chromosomal segment carried on this plasmid (pGY1) includes the markers cys-24+, cys-46+, and att16-3. Plasmid pGY1 mobilized the chromosome in a polarized way starting from the region of homology, but cannot promote chromosome transfer from other sites. The att16-3 site on pGY1 allowed the integration of phage 16-3 into pGY1, and a composite plasmid of 91.8 megadaltons was formed. This vector (pGY2) is suitable for the introduction of Rhizobium bacteriophage 16-3 into other gram-negative bacteria.     

Identification of Site-Specific Recombination Genes int and xis of the Rhizobium Temperate Phage 16-3

Phage 16-3 is a temperate phage of Rhizobium meliloti 41 which integrates its genome with high efficiency into the host chromosome by site-specific recombination through DNA sequences of attB and attP. Here we report the identification of two phage-encoded genes required for recombinations at these sites: int (phage integration) and xis (prophage excision). We concluded that Int protein of phage 16-3 belongs to the integrase family of tyrosine recombinases. Despite similarities to the cognate systems of the lambdoid phages, the 16-3 int xis att system is not active in Escherichia coli, probably due to requirements for host factors that differ in Rhizobium meliloti and E. coli. The application of the 16-3 site-specific recombination system in biotechnology is discussed.     

Lysogenic control of temperate phage 16-3 of Rhizobium meliloti 41 is governed by two distinct regions

Summary In addition to the regulator gene C of temperate phage 16-3 of Rhizobium meliloti 41, a second repressor function, called immune X, was identified and cloned into the low copy number cosmid vector pLAFR1. Both repressor functions are necessary to establish complete immunity against superinfecting non-virulent 16-3 strains, but either of the two alone decreases the efficiency of plating (e.o.p.) dramatically. It was shown that the primary target of gene product immune X was the avirT operator locus. The coding region of immune X was localized to the left arm of the phage genome, inside the EcoRI L and H fragments. This region maps about 14 kb from cistron C and had been thought to be genetically silent.     

Orientation of the genetic and physical map of Rhizobium meliloti temperate phage 16-3

Summary The attachment site, the C cistron of Rhizobium meliloti temperate phage 16-3, and the insertion of the host cys46 ⁺ gene in the phage genome were localized on the HindIII and EcoRJ restriction endonuclease maps, as well as mapped genetically. The strategy employed included restriction analysis and Southern in situ hybridization of plasmid pGY1, which carries the bacterial chromosome region containing the integration site of 16-3, plasmid pGY2, which carries the 16-3 prophage, deletion and inversion mutants, and the cys46 ⁺ transducing 16-3 particles. The colinear array of genetic and physical data was possible. The possibility of isolation of a replacement phage vector for Rhizobium is discussed.     

A proline tRNA(CGG) gene encompassing the attachment site of temperate phage 16-3 is functional and convertible to suppressor tRNA

Several temperate bacteriophage utilize chromosomal sequences encoding putative tRNA genes for phage attachment. However, whether these sequences belong to genes which are functional as tRNA is generally not known. In this article, we demonstrate that the attachment site of temperate phage 16-3 (attB) nests within an active proline tRNA gene in Rhizobium meliloti 41. A loss-of-function mutation in this tRNA gene leads to significant delay in switching from lag to exponential growth phase. We converted the putative Rhizobium gene to an active amber suppressor gene which suppressed amber mutant alleles of genes of 16-3 phage and of Escherichia coli origin in R. meliloti 41 and in Agrobacterium tumefaciens GV2260. Upon lysogenization of R. meliloti by phage 16-3, the proline tRNA gene retained its structural and functional integrity. Aspects of the co-evolution of a temperate phage and its bacterium host is discussed. The side product of this work, i.e. construction of amber suppressor tRNA genes in Rhizobium and Agrobacterium, for the first time widens the options of genetic study.     

In vivo cloning strategy for Rhizobium plasmids

We have developed a simple system to clone indigenous Rhizobium plasmids into E. coli. The strategy consists of three matings: the first is to insert Tn5 in the plasmid to be cloned, the second incorporates the integrative vector into the inserted Tn5 in the native Rhizobium plasmid, and the last mating transfers the target plasmid directly into E. coli. This mating-based system was successfully used to clone plasmids of Rhizobium species with sizes ranging from 150 to 270 kb. In addition, a 500-kb fragment of a 600-kb megaplasmid was also cloned. This strategy could be used for cloning indigenous replicons of other gram-negative bacteria into a different host.     

Plasmid integration in a wide range of bacteria mediated by the integrase of Lactobacillus delbrueckii bacteriophage mv4.

Bacteriophage mv4 is a temperate phage infecting Lactobacillus delbrueckii subsp. bulgaricus. During lysogenization, the phage integrates its genome into the host chromosome at the 3' end of a tRNA(Ser) gene through a site-specific recombination process (L. Dupont et al., J. Bacteriol., 177:586-595, 1995). A nonreplicative vector (pMC1) based on the mv4 integrative elements (attP site and integrase-coding int gene) is able to integrate into the chromosome of a wide range of bacterial hosts, including Lactobacillus plantarum, Lactobacillus casei (two strains), Lactococcus lactis subsp. cremoris, Enterococcus faecalis, and Streptococcus pneumoniae. Integrative recombination of pMC1 into the chromosomes of all of these species is dependent on the int gene product and occurs specifically at the pMC1 attP site. The isolation and sequencing of pMC1 integration sites from these bacteria showed that in lactobacilli, pMC1 integrated into the conserved tRNA(Ser) gene. In the other bacterial species where this tRNA gene is less or not conserved; secondary integration sites either in potential protein-coding regions or in intergenic DNA were used. A consensus sequence was deduced from the analysis of the different integration sites. The comparison of these sequences demonstrated the flexibility of the integrase for the bacterial integration site and suggested the importance of the trinucleotide CCT at the 5' end of the core in the strand exchange reaction.     

Identification of cohesive ends and genes encoding the terminase of phage 16-3

Cohesive ends of 16-3, a temperate phage of Rhizobium meliloti 41, have been identified as 10-base-long, 3'-protruding complementary G/C-rich sequences. terS and terL encode the two subunits of 16-3 terminase. Significant homologies were detected among the terminase subunits of phage 16-3 and other phages from various ecosystems.     

大黄鱼源溶藻弧菌的鉴定及其菌蜕制备

【背景】菌蜕是诱导Phi X174噬菌体裂解基因E(Lysis E)在革兰氏阴性菌中表达后所获得无细胞内容物的细菌空壳。菌蜕生物安全性高,能以类似活菌方式诱导机体产生良好的系统和黏膜免疫应答。【目的】对分离自患溃疡病大黄鱼肝脏中的病原菌株16-3进行种属鉴定,利用温控调节表达系统控制Phi X174噬菌体裂解基因E在该菌株中的表达来制备菌蜕,为防控鱼类溶藻弧菌感染提供有效手段。【方法】采用形态特征观察、生理生化特性测定及16S r RNA基因序列分析等方法对菌株16-3进行鉴定;构建温控裂解质粒p BV220-Lysis E,并将其电转至溶藻弧菌菌株16-3,形成重组溶藻弧菌菌株16-3(p BV220-Lysis E);将不同起始浓度的重组溶藻弧菌培养物同时进行42°C升温诱导,比较其溶菌动力曲线和裂解效率的差异;在最佳条件下制备溶藻弧菌菌株16-3菌蜕,电镜观察其形态与结构,采用倾注平板法测定冻干菌蜕中的活菌数。【结果】综合菌株16-3在形态、生理生化及16S r RNA基因系统发育等方面的特性,确定其为溶藻弧菌;构建了温控裂解质粒p BV220-Lysis E和重组溶藻弧菌菌株16-3(p BV220-Lysis E);溶藻弧菌菌株16-3菌蜕制备的最佳条件是选择起始浓度OD600为0.3的菌液进行诱导,诱导3 h后即可收获菌蜕,其裂解效率为96.9%,但经冻干处理后的菌蜕无活菌残留;电镜观察发现菌株16-3菌蜕保持原细胞的基本形态,但细胞表面有明显的溶菌孔道,且由于细胞内容流失而使细胞表面发生皱缩。【结论】制备出溶藻弧菌菌株16-3菌蜕,为其作为疫苗或疫苗递送载体奠定了基础。     

Phylogenetic diversity of non-nodulating Rhizobium associated with pine ectomycorrhizae

Most Rhizobium species described are symbionts that form nodules on legume roots; however, non-nodulating strains of Rhizobium are also widespread in nature. Unfortunately, knowledge of non-nodulating Rhizobium is quite limited compared with nodulating Rhizobium . Here, we studied the phylogenetic diversity of Rhizobium species that inhabit Japanese red pine roots ( Pinus densiflora ). Because fine roots of pine trees are usually colonized by ectomycorrhizal fungi in nature, we mainly used ectomycorrhizal root tips for bacterial isolation. Out of 1195 bacteria isolated from 75 independent root samples from the field and greenhouse experiments, 102 isolates were confirmed to be Rhizobium following partial 16S rRNA gene analysis. Rhizobium species were occasionally dominant in culturable bacterial communities, whereas no Rhizobium species were isolated from the soil itself. Molecular phylogenetic analyses using 16S rRNA, atpD , and recA gene sequences revealed that isolated Rhizobium strains were phylogenetically diverse and that several were distantly related to known Rhizobium species. Considering that a single species of pine is associated with unique and phylogenetically diverse Rhizobium populations, we should pay more attention to non-nodulating strains to better understand the diversity, ecology, and evolution of the genus Rhizobium and plant– Rhizobium associations.     

Characterization of Rhizobium 'hedysari' by RFLP analysis of PCR amplified rDNA and by genomic PCR fingerprinting

The taxonomic and discriminatory power of RFLP analysis of PCR amplified parts of rhizobial rrn operons was compared to those of genomic PCR fingerprinting with arbitrary and repetitive primers. For this purpose, the two methods were applied for characterization of a group of bacterial isolates referred to as Rhizobium 'hedysari'. As outgroups, representatives of the family Rhizobiaceae, belonging to the Rhizobium galegae, Rhizobium meliloti, Rhizobium leguminosarum and Agrobacterium tumefaciens species were used. By the RFLP analysis of the PCR products corresponding to the variable 5'-half of the 23S rRNA gene and of the amplified spacer region between the 16S and 23S rRNA genes all Rh. 'hedysari' strains studied were tightly clustered together while the outgroups were placed in an outer position. The PCR products of the 3' end parts of the 23S rDNA did not show significant RFL polymorphism and no species differentiation on their basis was possible. In parallel, analysis of the same strains was performed by PCR amplification of their total DNA with 19, 18 and 10 bp long arbitrary primers (AP-PCR) as well as with single primers corresponding to several bacterial repetitive sequences (rep-PCR). By both AP and rep-PCR an identification of every particular strain was achieved. In general, all primers provided taxonomic results that are in agreement with the species and group assignments based on the RFLP analysis of the rrn operons. On the basis of the results presented here it can be concluded that AP and rcp-PCR are more informative and discriminative than rDNA and RFLP analysis of the rhizobial strains studied.     

A novel approach to plastid transformation utilizes the phiC31 phage integrase

Thus far plastid transformation in higher plants has been based on incorporation of foreign DNA in the plastid genome by the plastid's homologous recombination machinery. We report here an alternative approach that relies on integration of foreign DNA by the phiC31 phage site-specific integrase (INT) mediating recombination between bacterial and phage attachment sites (attB and attP, respectively). Plastid transformation by the new approach depends on the availability of a recipient line in which an attB site has been incorporated in the plastid genome by homologous recombination. Plastid transformation involves insertion of an attP vector into the attB site by INT and selection of transplastomic clones by selection for antibiotic resistance carried in the attP plastid vector. INT function was provided by either expression from a nuclear gene, which encoded a plastid-targeted INT, or expressing INT transiently from a non-integrating plasmid in plastids. Transformation was successful with both approaches using attP vectors with kanamycin resistance or spectinomycin resistance as the selective marker. Transformation efficiency in some of the stable nuclear INT lines was as high as 17 independently transformed lines per bombarded sample. As this system does not rely on the plastid's homologous recombination machinery, we expect that INT-based vectors will make plastid transformation a routine in species in which homologous recombination rarely yields transplastomic clones.     

Electron microscopic characterization of Rhizobium bacteriophage 16-6-12 and its isolated deoxyribonucleic acid.

Bacteriophage 16-6-12 of Rhizobium lupini has a long, non-contractile tail and a head which is hexagonal in outline. The tail is 140 nm in length, 11 nm in diameter, and carries a short term fiber. Analysis of the tail structure by optical diffraction indicates that it is of the helical "stacked disc" type. After phenol-extraction from purified particles, the DNA of phage 16-6-12 can circularize in vitro. No significant difference in contour length was observed between the linear (14.34 plus or minus 0.28 mum) and circular (14.44 plus or minus 0.24 mum) forms of molecules. After partial denaturation with alkali an AT-GC-map was constructed, which shows an asymmetric distribution of AT- and GC-rich regions. It is concluded that this phage DNA can circularize due to the presence of cohesive ends and that it is not circularly permuted.     

Isolation and Characterization of a Bacteriophage Tail-Like Bacteriocin from a Strain of Rhizobium

Bacterial strain 16-3 spontaneously produces a bacteriocin which inhibits the growth of closely related strain 16-2. Both strains were newly isolated from root nodules of lupines and probably belong to the species Rhizobium lupini. Production of infectious progeny of newly isolated virulent phage 16-2-4 in strain 16-2 is inhibited completely if complexes are bacteriocin-treated during the first half of the latent period. Treatment begun during the second half leads to premature lysis of complexes and inactivates only those progeny phages which were not yet fully matured at the moment of the particle-induced lysis. Examination by electron microscope of the bacteriocin enrichment revealed the presence of particles 123 nm in length which resemble the tails of T-even bacteriophages. Since the particles sediment together with the bactericidal activity in the sucrose gradient and adsorb specifically to bacteriocin-sensitive cells, it is concluded that they are identical with the bactericidal agent. The particles are not found attached to phage heads and cannot self-propagate; they are regarded as incomplete and are named INCO particles. INCO particles consist of a core enveloped by a contractile sheath. One end of the sheath is connected to a baseplate to which six fibers, each 32 nm in length, are attached. These connect the baseplate of an adsorbing particle to the cell surface. Since INCo cores are probably empty, it is concluded that specific adsorption of the particles to the bacterial surface is sufficient to inactive sensitive cells irreversibly.     

Attachment of a long-tailed Rhizobium bacteriophage to the pili of its host

Bacterial strain 16-12 was isolated from the root nodules of lupines and was found to be mitomycin C-inducible for the production of a bacteriophage (“16-12-1”) with a long noncontractile tail. The phage was found to attach with a fork-like terminal tail structure to the pili of strain 16-12. In addition, it was also found adsorbed to the bacterial cell poles. It is suggested that phage 16-12-1 may be pilus dependent.     

Genetic diversity of rhizobia nodulating lentil (Lens culinaris) in Bangladesh

In order to determine the bacterial diversity and the identity of rhizobia nodulating lentil in Bangladesh, we performed a phylogenetic analysis of housekeeping genes (16S rRNA, recA, atpD and glnII) and nodulation genes (nodC, nodD and nodA) of 36 bacterial isolates from 25 localities across the country. Maximum likelihood (ML) and Bayesian analyses based on 16S rRNA sequences showed that most of the isolates (30 out of 36) were related to Rhizobium etli and Rhizobium leguminosarum. Only these thirty isolates were able to re-nodulate lentil under laboratory conditions. The protein-coding housekeeping genes of the lentil nodulating isolates showed 89.1-94.8% genetic similarity to the corresponding genes of R. etli and R. leguminosarum. The same analyses showed that they split into three distinct phylogenetic clades. The distinctness of these clades from closely related species was also supported by high resolution ERIC-PCR fingerprinting and phenotypic characteristics such as temperature tolerance, growth on acid-alkaline media (pH 5.5-10.0) and antibiotic sensitivity. Our phylogenetic analyses based on three nodulation genes (nodA, nodC and nodD) and cross-inoculation assays confirmed that the nodulation genes are related to those of R. leguminosarum biovar viciae, but clustered in a distinct group supported by high bootstrap values. Thus, our multi-locus phylogenetic analysis, DNA fingerprinting and phenotypic characterizations suggest that at least three different clades are responsible for lentil nodulation in Bangladesh. These clades differ from the R. etli-R. leguminosarum group and may correspond to novel species in the genus Rhizobium.