Circular Permutation of the Genome of a Temperate Bacteriophage from Streptococcus cremoris BK5

The temperate bacteriophage BK5-T was isolated from Streptococcus cremoris BK5 by induction with mitomycin C. Electron microscopy revealed that BK5-T DNA consists of linear molecules, ranging in size from 39.7 to 46 kilobase pairs. Restriction analysis of self-ligated BK5-T DNA showed that the ends of the DNA were not cohesive. The EcoRI restriction fragments of the phage genome were cloned into pACYC184. Restriction enzyme analysis of both the phage DNA and the cloned EcoRI fragments with EcoRI, BstEII, PstI, ClaI, and XbaI yielded a 37.6-kilobase-pair-long circular restriction map for the phage genome. It was concluded that the BK5-T DNA molecules in the population differ in their sequence by a circular permutation and that individual DNA molecules are terminally redundant. The map location of the sites at which packaging of BK5-T DNA into phage heads is initiated (pac) and at which the phage integrates into the bacterial chromosome (att) were established.     

Sequence homology and recombination between the genomes of morphologically dissimilar bacteriophages LP 52 and theta

Summary A restriction fragment map of Bacillus licheniformis temperate phage LP 52 DNA (molecular weight 38.5×10⁶) was established, using restriction endonucleases BamHI (8 target sites), BglI (10 sites), BglII (13 sites) and EcoRI (22 sites). The map is linear, with well-defined ends, without any signs of circular permutation. The DNA of a related phage, LP 51, produced identical restriction fragments. At least 62% DNA of LP 52 has been found homologous to the DNA of the recently discovered, morphologically quite dissimilar, phage , as demonstrated by hybridization of electrophoretically separated restriction fragments of DNA. Under the same conditions, the DNAs of LP 52 and of the morphologically similar Bacillus subtilis phage 105 did not cross-hybridize. The homologous regions in the genomes of phages LP 52 and have been shown to be colinear. Comparison of the cleavage maps of phages LP 52 and has shown that, within the regions of homology, not a single restriction fragment and few restriction sites have been conserved during divergent evolution. Three major regions of heterology were defined; the longest one, covering the right-hand end of the map (73±2.75% up to 100% LP 52 genome length) appeared to contain genes coding for structural proteins of the virions; a shorter region at the left-hand end of the map (coordinates zero to 10.3±3.3% LP 52 genome length) and a very short central region (coordinates 41.8–43.9%) could be identified, the latter apparently containing a regulatory locus responsible for the heteroimmune behavior of the two phages. Recombinants between phages LP 52 and were isolated. Mapping of recombinant genomes has indicated mutual substitution of allelic pieces of LP 52 and DNAs upon strict conservation of overall genome length.     

Interactions of Tn7 and temperate phage F116L of Pseudomonas aeruginosa

Summary Tn7 insertions into the genome of F116L, a Pseudomonas aeruginosa generalized transducing phage, were isolated by repeated cycles of transducing phage, were of strains lysogenic for F116cts mutants with selection for trimethoprim resistance (Tp¹). Two non-defective F116Lcts:Tn7 phage were characterized. They have reduced plaquing ability, produced non-lysogenic Tp^r transductants, and have yielded a deletion mutant of the phage genome upon selection for plaque formation in single infection. F116L DNA is circularly permuted and terminally redundant. A circular restriction map of 61.7 kb has been defined, and a cleavage site common to many enzymes has been identified at coordinate 23.3 kb on the map. It is presumed that this site represents the sequence for the initiation of DNA encapsidation by a headful packaging mode. The Tn7 insertion targets and a 13.4 kb deletion define regions of the F116L genome non-essential for either vegetative growth or lysogenization. The restriction map of Tn7 has been determined for five enzymes. Non-lysogenic Tp^r transuctants reveal a Tn7 insertion hot-spot in the P. aeruginosa genome.     

Isolation,physical map and gene map of mitochondrial DNA from the cryptomonad Pyrenomonas salina

Mitochondrial DNA (mtDNA) from the cryptomonad Pyrenomonas salina was isolated by CsCl-buoyant density centrifugation of whole-cell DNA in the presence of Hoechst dye 33258. mtDNA consists of circular molecules about 47 kb in size as estimated from restriction enzyme analysis. A physical map for six restriction enzymes (Bam HI, Bge I, Eco RI, Pst I, Sac I and Sac I) has been constructed. Genes coding for the small subunit of rRNA, cytochrome oxidase subunits I and II, and apocytochrome b were localized on this map using Southern blot hybridization with heterologous gene probes from Oenothera. Genes for 5S rRNA and NADH dehydrogenase subunit 5 are absent from P. salina mtDNA. The mitochondrial genome, being the first analysed to this extent in chromophytic algae, should be valuable for taxonomic and phylogenetic studies.     

The genome of B. subtilis phage SPP1:

Summary DNA molecules of B. subtilis phage SPP1 exhibit terminal redundancy and are partially circularly permuted. This was established by the hybridization of selected EcoRI restriction fragments to single strands of SPP1 DNA and by an analysis of the distribution of denaturation loops in partially denatured SPP1 DNA molecules. Deletions in SPP1 DNA are not compensated by an increase in terminally repetitious DNA. This finding, which is unique to SPP1, is discussed in terms of a modification of the Streisinger/Botstein model of phage maturation.     

Physical mapping of the virion and the prophage DNAs of a temperate Lactobacillus phage phi FSW

We analysed the physical structure of the DNA of phi FSW, which is a temperate phage of Lactobacillus casei S-1. A circular restriction map of the virion DNA has been constructed with three restriction endonucleases, BamHI, SalI and XhoI. Other data indicated that the phage genome was circularly permuted. In lysogens, the DNA of the prophage was found to be linearized at a specific site and integrated into a specific locus of the host genome, with the same orientation in each case, as evidenced by Southern filter hybridization. We compared the physical structure of phi FSW with its three virulent mutants. One of them had a restriction map indistinguishable from that of phi FSW and two of them contained host-derived DNA sequence(s) in a specific region of the phi FSW genome (V-region). The prophage integration site was mapped on a different segment of the phage genome to the V-region. Derivation of virulent mutants from phi FSW is discussed in relation to the physical structure of the phage genome.     

A physical map of the genome of ethanol fermentative bacterium Zymomonas mobilis ZM4 and localization of genes on the map

A physical map of the Zymomonas mobilis ZM4 genome has been constructed from the results of reciprocal Southern hybridization with PmeI, PacI, and NotI-digested genomic DNA fragments and linking cosmid clones. Restriction enzyme-digested Z. mobilis ZM4 genome was electrophoresed with phage lambda DNA concatemers as a size standard in a Bio-Rad CHEF-DRII pulsed-field gel electrophoresis (PFGE) system. The restriction enzyme PmeI generated 15 fragments (3–625 kb), and PacI produced 19 fragments (7–525 kb). Each size of restriction fragment was calculated by comparison to the size of phage lambda DNA concatemers, and the genome size of Z. mobilis ZM4 was estimated to be 2085.5 kb. The 19 known genes and three rrn operons were localized on the map.     

Construction of a chromosome map for the phage group II Staphylococcus aureus Ps55.

The genome size and a partial physical and genetic map have been defined for the phage group II Staphylococcus aureus Ps55. The genome size was estimated to be 2,771 kb by pulsed-field gel electrophoresis (PFGE) using the restriction enzymes SmaI, CspI, and SgrAI. The Ps55 chromosome map was constructed by transduction of auxotrophic and cryptic transposon insertions, with known genetic and physical locations in S. aureus NCTC 8325, into the Ps55 background. PFGE and DNA hybridization analysis were used to detect the location of the transposon in Ps55. Ps55 restriction fragments were then ordered on the basis of genetic conservation between the two strains. Cloned DNA probes containing the lactose operon (lac) and genes encoding staphylococcal protein A (spa), gamma hemolysin (hlg), and coagulase (coa) were also located on the map by PFGE and hybridization analysis. This methodology enabled a direct comparison of chromosomal organization between NCTC 8325 and Ps55 strains. The chromosome size, gene order, and some of the restriction sites are conserved between the two phage group strains.     

Cloning of bacteriophage T5 DNA fragments in plasmid pBR322 and bacteriophage lambda gtWES

Bacteriophage T5 was digested with the restriction endonucleases HindIII and EcoRI and the resulting fragments were inserted into the plasmid pBR322 and the bacteriophage lambda gtWES as vectors. Approx. 15% of the phage genome was recovered in recombinant clones. The recombinants were characterized by restriction analysis, DNA/DNA hybridization employing Southern blots, and ability to complement or recombine with amber mutants of T5. The results obtained allow revisions of the physical map of the T5 genome and partial correlation of the physical map with the genetic map.     

Cloning and physical mapping of enteric adenoviruses (candidate types 40 and 41)

We have studied the DNAs of fastidious enteric adenoviruses recovered from the stools of infants with gastroenteritis. By endonuclease analysis, the strains examined represent candidate adenovirus types 40 and 41, which are thought to comprise new adenovirus subgroups F and G. Cloning of DNA from representative enteric adenovirus isolates, together with hybridization and subcleavage analysis, permitted the mapping of restriction enzyme cleavage sites. Although the restriction profiles are different for the two strains, they appear to have several cleavage sites in common. Cross hybridization studies show considerable homology between the subgroup F and G strains but much less homology to adenovirus 2. In addition, regions on both ends of enteric adenovirus genomes (map units, 2.9 to 11.3 and 75 to 100) possess little or no homology to adenovirus 2. Restriction enzyme digests reveal submolar fragments that map to the terminal regions of the genome. Electron micrographic studies of denatured and renatured DNA strands suggest that the submolar fragments may derive from cleavage of defective molecules. Inverted terminal repeat sequences were shown to comprise 0 to 3.2% of the length of complete (greater than or equal to 22 megadaltons) enteric adenovirus DNA molecules but 4 to 69% of incomplete-length (less than 22-megadalton) molecules.     

Y enriched and Y specific DNA sequences from the genome of the mediterranean fruit fly,Ceratitis capitata

DNA sequences that are enriched or specific to the genome of the male medfly, Ceratitis capitata, have been isolated using a differential hybridization approach. Twelve phage clones from a genomic library have been identified that consistently display more intense hybridization with a genomic DNA probe from males as opposed to one from females. Southern DNA blot analysis reveals that these recombinant clones contain at least one EcoRI fragment that is either specific to the male genome, or more highly represented in it, as compared with the female genome. These EcoRI fragments, when used as probes, all generate a similar pattern of intense multiple bands in genomic DNA of males. This suggests the presence of repetitive sequences that are at least partially homologous in these regions of the genome that are specific to or enriched in males. In situ hybridization to mitotic chromosomes confirms a Y chromosomal origin for the male specific repetitive sequences. Data on the genomic organization, representation and evolutionary conservation of these sequences that are specific to or enriched in males are presented. Studies of the genomic organization and representation of flanking sequences that are not male specific are presented as well.by R. Appels     

Localization of the dihydrofolate reductase gene on the physical map of bacteriophage T5

Summary Large quantities of dihydrofolate reductase are synthesized in bacteriophage T5 infected E. coli cells. Some evidence that this enzyme is the product of a viral gene was published by Mathews (1967). Further evidence is presented now by showing that the newly synthesized enzyme differs from the preexisting E. coli reductase in molecular weight and salt solubility.The expression of the T5 dihydrofolate reductase gene was not affected by deletions in the del region of the phage genome. The map position of the reductase gene was determined by marker rescue experiments designed as helped transfection procedure: When E. coli B cells were preinfected with T5 dihydrofolate reductase amber mutants, made competent, and transfected with T5 wild type DNA, viable phages were obtained. Wild type recombinant phages were observed, when the transfecting DNA had been digested with the restriction endonucleases EcoRI, HpaI, PstI, and SalI. No rescue occurred when the DNA had been digested with AluI, EcoRII, HindII, HindIII, MboII, Sau3A, and XbaI. Single EcoRI, HpaI, and SalI restriction fragments were isolated and found to rescue the dihydrofolate reductase gene. Their common overlapping sequence corresponds to 8.6% of the phage DNA, a segment of about 10,000 base pairs length, which extends from position 0.37 to position 0.46 of the physical map. After cleaving this segment at its single HindIII recognition site marker rescue no longer occurred. From these results it was concluded that the dihydrofolate reductase gene either lies at or very close to this site at position 0.4.The helped transfection method was also used to rescue T5 mutants with defects in the genes C2 and D9. Gene C2 was localized on an EcoRI fragment that covers the DNA from map position 0.08 to map position 0.25. By localizing the two genes B3 and C2 on the restriction map of the T5 DNA a correlation of the genetic and the physical maps of the T5 genome has been established. Abbreviations. The symbols for T5 phages follow those of McCorquodale (1975) and the nomenclature for restriction nucleases that of Smith and Nathans (1973). kb=kilo base pairs     

Recombination between bacteriophage T4 and plasmid pBR322 molecules containing cloned T4 DNA

Reciprocal recombination between T4 DNA cloned in plasmid pBR322 and homologous sequences in bacteriophage T4 genomes leads to integration of complete plasmid molecules into phage genomes. Indirect evidence of this integration comes from two kinds of experiments. Packaging of pBR322 DNA into mature phage particles can be detected by a DNA--DNA hybridization assay only when a T4 restriction fragment is cloned in the plasmid. The density of the pBR322 DNA synthesized after phage infection is also consistent with integration of plasmid vector DNA into vegetative phage genomes. Direct evidence of plasmid integration into phage genomes in the region of DNA homology comes from genetic and biochemical analysis of cytosine-containing DNA isolated from mature phage particles. Agarose gel electrophoresis of restriction endonuclease-digested DNA, followed by Southern blot analysis with nick-translated probes, shows that entire plasmid molecules become integrated into phage genomes in the region of T4 DNA homology. In addition, this analysis shows that genomes containing multiple copies of complete plasmid molecules are also formed. Among phage particles containing at least one integrated copy, the average number of integrated plasmid molecules is almost ten. A cloning experiment done with restricted DNA confirms these conclusions and illustrates a method for walking along the T4 genome.     

Molecular genetics of growth and development in Populus. III. A genetic linkage map of a hybrid poplar composed of RFLP,STS, and RAPD markers

We have evaluated three DNA-based marker types for linkage map construction in Populus: RFLPs detected by Southern blot hybridization, STSs detected by a combination of PCR and RFLP analysis, and RAPDs. The mapping pedigree consists of three generations, with the F₁ produced by interspecific hybridization between a P. trichocarpa female and a P. deltoides male. The F₂ generation was made by inbreeding to the maximum degree permitted by the dioecious mating system of Populus. The applicability of STSs and RAPDs outside the mapping pedigree has been investigated, showing that these PCR-based marker systems are well-suited to breeding designs involving interspecific hybridization. A Populus genome map (343 markers) has been constructed from a combination of all three types. The length of the Populus genome is estimated to be 2400–2800 cM.Abbreviations RFLP restriction fragment length polymorphism - STS sequence-tagged site - PCR polymerase chain reaction - RAPD random amplified polymorphic DNA     

Tandem repeat of the 23S and 5S ribosomal RNA genes in Borrelia burgdorferi, the etiological agent of Lyme disease.

The DNA fragments containing the rrl and rrf genes were subcloned from a EMBL3 recombinant phage of Borrelia burgdorferi strain B31 into pUC18 and were characterized by restriction analysis and Southern hybridization. A fine restriction map of the fragments was constructed and the organization of the genes was determined. The genomic hybridization using the gene probes from B. burgdorferi showed that there are two sets of rrl/rrf genes in that genome. The results also revealed the important fact that the gene sets are repeated directly by 3.2-kb long. This is the first report of this remarkable feature in the organization of the eubacterial rRNA genes.     

The physical map of the chloroplast DNA from Asparagus officinalis L.

The genus Asparagus consists of 100–300 species of both dioecious and hermaphrodite plants. Since there are diploid, tetraploid, and hexaploid plants in this genus, RFLP (restriction fragment length polymorphism) analysis of chloroplast DNA (ctDNA) is suitable for examining the phylogenetic relationships. We have constructed a physical map of the ctDNA of garden asparagus (A. officinalis L. cv Mary Washington 500 W) using five restriction endonucleases, namely, BamHI, PstI, SalI, HindIII, and XhoI. Asparagus ctDNA was digested with restriction enzymes and cloned into plasmid and phage vectors, and a clone bank was constructed that covered 70% of the genome. A physical map was constructed by Southern hybridization of total DNA from asparagus with homologous and heterologous probes. The asparagus ctDNA was about 155 kb long and it contained two inverted repeats (23kb each) separated by a large single-copy region (90kb) and a small single-copy region (19kb). Fifteen genes, encoding photosynthesis-related proteins, rDNAs, and tRNAs, were localized on the physical map of asparagus ctDNA. Comparing the length and the gene order of asparagus ctDNA with that of other plants, we found that asparagus ctDNA was similar to tobacco ctDNA but different from rice ctDNA. The restriction patterns of the ctDNAs from several varieties of A. officinalis and three species of Asparagus were analyzed. The restriction patterns of the varieties of A. officinalis were very similar, but polymorphisms were detected among the three species of Asparagus.     

Characterization of phage isolates from a phage-carrying culture of Leuconostoc oenos 58N

Summary During large-scale cultivation of Leuconostoc oenos strain 58N, growth inhibition was detected and attributed to the presence of the virulent phage P581. To determine if this phage originated from a temperate phage, L. oenos 58N was exposed to mitomycin C, and this treatment led indeed to release of phages (P58II). Further examination of the lytic potential of phages P581 and P58II revealed that these two phages were able to lyse the same strains of L. oenos with the exception of the original host strain, which was only sensitive to P581. Results of DNA/DNA hybridization experiments failed to show homology between the DNA of phage P58II and the chromosomal DNA of L. oenos 58N. A phage-free culture of L. oenos 58N could be obtained after repeated subculture. These results indicate that the original L. oenos 58N was in a special type of phage-carrier state. Phages P58I and P58II were compared on the basis of morphology, lytic spectra, restriction enzyme analysis, DNA homology, genome size and protein structure and proved to be identical. It is assumed that P58I arose from the phage-carrier culture of L. oenos 58N and became virulent by some mutational event.Offprint requests to: E. K. Arendt     

BREX is a novel phage resistance system widespread in microbial genomes

The perpetual arms race between bacteria and phage has resulted in the evolution of efficient resistance systems that protect bacteria from phage infection. Such systems, which include the CRISPR‐Cas and restriction‐modification systems, have proven to be invaluable in the biotechnology and dairy industries. Here, we report on a six‐gene cassette in Bacillus cereus which, when integrated into the Bacillus subtilis genome, confers resistance to a broad range of phages, including both virulent and temperate ones. This cassette includes a putative Lon‐like protease, an alkaline phosphatase domain protein, a putative RNA‐binding protein, a DNA methylase, an ATPase‐domain protein, and a protein of unknown function. We denote this novel defense system BREX (Bacteriophage Exclusion) and show that it allows phage adsorption but blocks phage DNA replication. Furthermore, our results suggest that methylation on non‐palindromic TAGGAG motifs in the bacterial genome guides self/non‐self discrimination and is essential for the defensive function of the BREX system. However, unlike restriction‐modification systems, phage DNA does not appear to be cleaved or degraded by BREX, suggesting a novel mechanism of defense. Pan genomic analysis revealed that BREX and BREX‐like systems, including the distantly related Pgl system described in Streptomyces coelicolor, are widely distributed in ~10% of all sequenced microbial genomes and can be divided into six coherent subtypes in which the gene composition and order is conserved. Finally, we detected a phage family that evades the BREX defense, implying that anti‐BREX mechanisms may have evolved in some phages as part of their arms race with bacteria.     

Integrated map of the Schizosaccharomyces pombe genome

A restriction map of the entire Schizosaccharomyces pombe genome was constructed using two restriction enzymes (BamHI and PstI) that recognize 6 bp. The restriction map contains 420 minimally overlapping clones (miniset) and has 22 gaps. We located 126 genes, marker fragments of DNA (NotI and SfiI linking clones), and 36 transposable elements by hybridization to unique restriction fragments. Received: 21 November 1996; in revised form: 3 March 1997 / Accepted: 27 March 1997