Bacteriophages of Saccharopolyspora erythraea

Five bacteriophages infecting only Saccharopolyspora erythraea (formerly Streptomyces erythreus) among 43 Streptomyces spp. tested were classified into two groups by phage-host relationships, restriction enzyme mapping, cohesive-end determinations, and Southern hybridizations. phi SE6, the most frequently isolated phage, produced clear plaques on all hosts tested, while phi SE45, phi SE57, phi SE60, and phi SE69 produced turbid plaques. phi SE6 DNA was linear, had a molecular weight of (27.6 +/- 1) X 10(6) and, like the DNAs of phi SE45, phi SE57, and phi SE69, lacked cohesive ends. The characteristic patterns of of ClaI and HindIII restriction digests of phi SE6 DNA and the results of Southern hybridizations with three different ClaI fragments of phi SE6 DNA as probes indicated that phi SE6 DNA was partially circularly permuted and terminally redundant, suggesting that it was packaged by a headful packaging mechanism. Southern hybridization data also showed that phi SE45, phi SE57, and phi SE69 were closely related to phi SE6. phi SE60 DNA, in contrast, had cohesive ends, and restriction mapping plus Southern hybridization data showed that phi SE60 was unrelated to the other four phages.     

Construction and transduction of a shuttle vector bearing the cos site of Streptomyces phage phi C31 and determination of its cohesive ends

A plasmid has been constructed which is a bifunctional vector for Escherichia coli and for streptomycetes, containing the cos site of Streptomyces phage phi C31. It can be efficiently transduced into S. lividans 66 and into several other Streptomyces species. The nucleotide sequence of a 311-bp DNA fragment containing the cohesive ends has been determined. The cohesive ends consist of 10 bases protruding at the 3'-end of the phage genome.     

Characterization of SE-3, a virulent bacteriophage of Saccharopolyspora erythraea

SE-3 is a virulent bacteriophage isolated from a large-scale culture of Saccharopolyspora erythraea, an erythromycin producer. The host range of the phage is narrow, limited to some strains of this species. Another strain of Sac. erythraea, and a strain of Sac. hirsuta, are able to adsorb phage particles but do not sustain their complete multiplication. SE-3 is closely related to the phage SE-5 as shown by DNA restriction mapping. The differences between SE-3 and SE-5 genomes are apparently limited to two DNA segments flanked by short inverted repeats, visualized by electron microscopy.     

Site-specific integration in Saccharopolyspora erythraea and multisite integration in Streptomyces lividans of actinomycete plasmid pSE101.

An 11.3-kilobase-pair plasmid, designated pSE101, exists in Saccharopolyspora erythraea NRRL 2338 as an integrated sequence (pSE101int) at a unique chromosomal location and in the free form in less than an average of 1 copy per 10 chromosomes. The plasmid sequence is missing from S. erythraea NRRL 2359. Restriction maps of the free and integrated forms of pSE101 showed point-to-point correspondence. Plasmid pECT2 was constructed by ligation of pSE101, pBR322, and the gene for thiostrepton resistance (tsr). When introduced by polyethylene glycol-mediated transformation into protoplasts of S. erythraea NRRL 2359, all thiostrepton-resistant regenerants examined were found to carry a single copy of pECT2 in the integrated state at a single chromosomal site. The chromosomal site of pECT2 integration in strain NRRL 2359 (attB) corresponded to the chromosomal location of pSE101int in strain NRRL 2338. The plasmid crossover site (attP) was mapped to the plasmid site that corresponded to the site of interruption of the plasmid sequence in the host carrying pSE101int, indicating that site-specific integrative recombination had occurred. An additional 2.8-kilobase-pair chromosomal sequence homologous to a segment of pSE101 was also observed in strains NRRL 2338 and NRRL 2359. After introduction of pECT2 into Streptomyces lividans, approximately half of the transformants examined were found to carry the plasmid as a stable, autonomously replicating element. The other half carried a single copy of pECT2 as an integrated sequence, but the location of pECT2int in Streptomyces lividans varied from one transformant to another. In each case, integrative crossover used the attP site. A model is proposed to account for the determination of the particular state of pSE101 in Streptomyces lividans.     

Development of a system of plasmid transfer in the strains Streptomyces avermitilis ATCC 31272 and Saccharopolyspora erythraea ATCC 11635 by the method of intergeneric conjugation

A new method of plasmid DNA transfer from the donor strain Escherichia coli S17-1 to the erythomycin-producing strain Saccharopolyspora erythraea and avermectin-producing strain Streptomyces avermitilis via intergeneric conjugation was proposed. The optimal parameters of the method were chosen for increasing the efficiency of crosses and ensuring easily reproducible results. The behavior of the multicopy plasmid pPM803 and the integration vector pTO1 along with a number of new plasmids specially created by us, was examined in these strains. A new plasmid vector (pSI60) capable of integrating into the chromosome of actinomycetes at the integration site of the temperate actinophage phi C31 was constructed. This vector possesses unique sites convenient for cloning and may be stably maintained in exconjugants of S. avermitilis and in the model strain Streptomyces lividans. The gene encoding resistance to spectinomycin and streptomycin was cloned into the vector pSI60 in this strain. For cloning in strain Sac. erythraea, vectors pSI261-280, which integrate into the chromosome via homology with the cloned DNA and can be stably maintained in exconjugants, were constructed.     

Study of Brevibacterium flavum phage PhiBSh6]

Properties of a virulent Brevibacterium flavum bacteriophage phi BSh6 were studied. The phage was placed in morphological group B1 according to Ackerman classification, head diameter being 74-3 nm, tail length being 337 +/- 15 nm. The phage was shown to have double stranded DNA as a genetic material. The chromosome is linear having cohesive ends. Chromosome length was estimated to be about 71 kbp by restriction analysis and electron microscopy. A unique EcoRI-EcoRI fragment of bacteriophage DNA (0.8 kbp) was cloned in Escherichia coli. Restriction chart of cos region was determined, the dyad symmetry being absent from cos sequence. Deletion mutant of the phage was obtained and restriction map of the corresponding genome region was constructed. The phage phi BSh6 was shown to be a close relative to phages phi B and BB14 described earlier.     

Transductional selection of cloned bacteriophage phi 105 and SP02 deoxyribonucleic acids in Bacillus subtilis.

The Bacillus subtilis temperate bacteriophages phi 105 and SP02 are incapable of transduction of the small, multicopy drug resistance plasmids pUB110 and pCM194. Cloning endonuclease-generated fragments of phi 105 or SP02 DNA into each of the plasmids renders the chimeric derivatives susceptible to transduction specifically by the phage whose deoxyribonucleic acid is present in the chimera. The majority of phage deoxyribonucleic acid fragments identified that render plasmids transducible by phi 105 or SP02 appear to be internal fragments, not fragments containing the cohesive ends. However, the highest overall transduction frequency was observed in SP02-mediated transduction of a derivative of pUB110 containing a 1.6-megadalton EcoRI fragment that likely contains the SP02 cohesive ends (plasmid pPL1010). The transducing activity present in a phi 105 transducing lysate had a buoyant density slightly greater than infectious particles, whereas the majority of transducing particles in an SP02(pPL1010) transducing lysate had a buoyant density slightly less than infectious particles. Although no detectable change in plasmid structure resulted from transduction by phi 105 or SP02, deoxyribonucleic acid isolated from a purified SP02(pPL1010) transducing lysate contained no detectable monomeric pPL1010, but did contain a form of pPL1010 of higher molecular weight than the monomer.     

Biological characterization of induced phages from Saccharopolyspora hirsuta 367 and comparison with phage JHJ-1.

Phages JHJ-2 and JHJ-3 were isolated from Saccharopolyspora hirsuta 367 UC 8106 following induction with mitomycin C and amplified on S. hirsuta NRRL B-5792. Their properties were compared with those of phage JHJ-1, isolated previously from S. hirsuta 367 NRRL 12045. The DNA restriction patterns appeared to be identical. One-step growth experiments showed no differences between the replication cycles. Burst sizes ranged from 100 to 110 p.f.u. per cell. However, the three phages showed some differences in their behaviour in different hosts. The host range of phage JHJ-1, on non-lysogenic strains, was emended to include all of the Saccharopolyspora strains tested; the host range of phage JHJ-2 was shown to be identical to JHJ-1. Phage JHJ-3 did not form detectable plaques on strains of S. rectivirgula or S. erythraea except S. erythraea NRRL 2359. Neither phage JHJ-2 nor JHJ-3 formed plaques on any lysogenic strains, while JHJ-1 formed plaques on all such strains except S. hirsuta 367 UC8106. Phage JHJ-3 was characterized as a temperate bacteriophage because it formed turbid, self-limiting plaques and lysogenized S. hirsuta NRRL B-5792. It was spontaneously released from UC8106. Both JHJ-1 and JHJ-2 formed clear and invasive (Inv+ phenotype: the property to grow on old mycelium) plaques on some Saccharopolyspora strains but clear and self-limiting plaques on others. Thus, the expression of the Inv+ phenotype encoded by JHJ-1 and JHJ-2 appears to be modulated by the host cell.     

Mutation and cloning of eryG, the structural gene for erythromycin O-methyltransferase from Saccharopolyspora erythraea, and expression of eryG in Escherichia coli.

A mutant strain derived by chemical mutagenesis of Saccharopolyspora erythraea (formerly known as Streptomyces erythreus) was isolated that accumulated erythromycin C and, to a lesser extent, its precursor, erythromycin D, with little or no production of erythromycin A or erythromycin B (the 3"-O-methylation products of erythromycin C and D, respectively). This mutant lacked detectable erythromycin O-methyltransferase activity with erythromycin C, erythromycin D, or the analogs 2-norerythromycin C and 2-norerythromycin D as substrates. A 4.5-kilobase DNA fragment from S. erythraea originating approximately 5 kilobases from the erythromycin resistance gene ermE was identified that regenerated the parental phenotype and restored erythromycin O-methyltransferase activity when transformed into the erythromycin O-methyltransferase-negative mutant. Erythromycin O-methyltransferase activity was detected when the 4.5-kilobase fragment was fused to the lacZ promoter and introduced into Escherichia coli. The activity was dependent on the orientation of the DNA relative to lacZ. We have designated this genotype eryG in agreement with Weber et al. (J.M. Weber, B. Schoner, and R. Losick, Gene 75:235-241, 1989). It thus appears that a single enzyme catalyzes all of the 3"-O-methylation reactions of the erythromycin biosynthetic pathway in S. erythraea and that eryG codes for the structural gene of this enzyme.     

Genetic characteristics and genome structure of Streptomyces coelicolor actinophages]

Actinophage phi C31 of Streptomyces coelicolor A3 (2) and two novel temperate actinophages phi C43 and phi C62 isolated from strains of blue actinomycetes group are homoimmune, serologically and functionally related. DNA molecules of phages phi C31, phi C43 and phi C62 have cohesive ends; sizes of DNAs of these phages and some mutants have been determined. The extent of homology between the DNAs of three phages is 93-96% as shown by heteroduplex analysis. The regions of non-homology are of a deletion-insertion type and of approximately 1500 base pairs in the length. Location of deletions in DNAs of mutant phages phi C31 vd and phi C31 c5 has been shown. Structural modifications in phage dnas have been found only to occur in the right part of molecules. Heteroduplex maps have been constructed for all phages studied.     

Analysis of genes involved in 6-deoxyhexose biosynthesis and transfer in Saccharopolyspora erythraea

Glycosylation represents an attractive target for protein engineering of novel antibiotics, because specific attachment of one or more deoxysugars is required for the bioactivity of many antibiotic and antitumour polyketides. However, proper assessment of the potential of these enzymes for such combinatorial biosynthesis requires both more precise information on the enzymology of the pathways and also improved Escherichia coli-actinomycete shuttle vectors. New replicative vectors have been constructed and used to express independently the dnmU gene of Streptomyces peucetius and the eryBVII gene of Saccharopolyspora erythraea in an eryBVII deletion mutant of Sac. erythraea. Production of erythromycin A was obtained in both cases, showing that both proteins serve analogous functions in the biosynthetic pathways to dTDP-L-daunosamine and dTDP-L-mycarose, respectively. Over-expression of both proteins was also obtained in S. lividans, paving the way for protein purification and in vitro monitoring of enzyme activity. In a further set of experiments, the putative desosaminyltransferase of Sac. erythraea, EryCIII, was expressed in the picromycin producer Streptomyces sp. 20032, which also synthesises dTDP-D-desosamine. The substrate 3-alpha-mycarosylerythronolide B used for hybrid biosynthesis was found to be glycosylated to produce erythromycin D only when recombinant EryCIII was present, directly confirming the enzymatic role of EryCIII. This convenient plasmid expression system can be readily adapted to study the directed evolution of recombinant glycosyltransferases.     

Phage-conversion of cytotoxin production in Pseudomonas aeruginosa

We isolated a temperate phage which carried the cytotoxin gene (ctx) from a cytotoxin (CTX)-producing Pseudomonas aeruginosa strain, PA158. The phage, phi CTX, had a head with a hexagonal outline and a contractile tail with tail fibres. The phage genome was a linear double-stranded 35.5 kb DNA with single-stranded cohesive ends (cos). The attP, cos and ctx genes were all located very close to one another within a 2.3 kb segment on the phage genome in the order given (in the circular form). phi CTX converted CTX non-producing P. aeruginosa strains into CTX producers. A single copy of phi CTX DNA was integrated at the same site on the host chromosome (attB) in every lysogen, including PA158. However, the amount of CTX produced in these lysogens varied from strain to strain and was less than that in PA158.     

Identification and cloning of a type III polyketide synthase required for diffusible pigment biosynthesis in Saccharopolyspora erythraea

The soluble, diffusible red-brown pigment produced by a Saccharopolyspora erythraea "red variant" has been shown to contain glycosylated and polymerized derivatives of 2,5,7-trihydroxy-1,4-naphthoquinone (flaviolin). Flaviolin is a spontaneous oxidation product of 1,3,6,8-tetrahydroxynaphthalene (THN), which is biosynthesized in bacteria by a chalcone synthase-like (CS-like) type III polyketide synthase (PKS). A fragment of the gene responsible for THN biosynthesis in S. erythraea E_8-7 was amplified by polymerase chain reaction (PCR) using degenerate primers based on conserved regions of known plant CS and bacterial CS-like genes. From the isolated fragment, a suicide vector was prepared, which was subsequently used to disrupt the red-brown pigment-producing (rpp) locus in S. erythraea, generating a mutant that displayed an albino phenotype. Chromosomal DNA from the albino mutant was subsequently used in a vector-recapture protocol to isolate a plasmid that contained an insert spanning the entire rpp locus. Sequencing of the insert revealed that the disrupted open reading frame (ORF) encodes a CS-like protein displaying 69% sequence identity to the rppA gene of Streptomyces griseus. The S. griseus rppA gene encodes RppA, the first characterized bacterial CS-like protein, which is sufficient in vitro for the synthesis of THN from malonyl-CoA. The rppA disruption mutant and rppA sequence provided a means by which to address the mechanism of diffusible pigment biosynthesis, as well as to investigate any link between this and the modulation of erythromycin A titre, which has been observed for S. erythraea variants.     

Characterization of Infectious Deoxyribonucleic Acid from Temperate Bacillus subtilis Bacteriophage φ 105

Phenol-extracted, infectious deoxyribonucleic acid (DNA) species from phi105 phage particles, from phi105 lysogenic bacteria, and from induced phi105 lysogenic bacteria were sedimented in sucrose gradients. Infectious DNA from phi105 particles sedimented like the bulk of mature phage DNA in neutral sucrose. Infectivity of prophage DNA was associated with fast-sedimenting material of heterogenous size. Infectious vegetative phage DNA sedimented somewhat faster than mature phage DNA; it was rapidly converted to a poorly infectious form during the infection.     

Saccharopolyspora hirsuta strain 367 releases JHJ-1, a bacteriophage capable of propagation on old mycelium

Bacteriophage JHJ-1 was isolated from Saccharopolyspora hirsuta strain 367 NRRL 12045 as an endogenous but virulent phage. The plaque size was not self-limiting, since a few p.f.u. could completely lyse a lawn. Electron microscopy showed that this phage belonged to group B of Bradley's morphological classification. The JHJ-1 genome is a linear DNA molecule of 41.1 kbp with cohesive ends and a G + C content of 68.8-70.0 mol%. The DNA cleavage map was established for 12 restriction endonucleases. The host range is apparently very narrow, being limited to two strains of S. hirsuta (NRRL 12045 and NRRL B-5792). However, JHJ-1 did not lytically infect S. hirsuta strain 367 UC 8106. Phage JHJ-1 was shown, by Southern blot analysis, to lysogenize both S. hirsuta NRRL 12045 and UC 8106. It thus appears to behave as a virulent mutant of a temperate phage on one, but not on the other, JHJ-1 lysogen.     

Characterization of Deoxyribonucleic Acid of Virulent Bacteriophage and its Infectivity to Host Bacteria, Pseudomonas solanacearum

Virulent bacteriophage PK-101 was isolated from soil infested with strain K-101 of Pseudomonas solanacearum and nucleic acid was prepared from the phages. Some chemical properties of phage nucleic acid and its infectivities to various strains of P. solanacearum were examined in the present study. By digestion with restriction endonucleases, phage nucleic acid was shown to be linear duplex DNA approximately 35 kb long. Restriction fragment length polymorphism was observed when electrophoresis patterns of enzyme-digested PK-101 DNA were compared with those of DNA prepared from different phage isolates. Transfection of host strains by PK-101 DNA was carried out, and it was infectious not only to host strain K-101, but also to other strains which were resistant to phage particles. Transfection efficiency was considerably enhanced by directly introducing phage DNA into bacterial cells by means of an electroporation. The electroporation technique was also effective to transform P. solanacearum with large-size plasmid DNA.     

Correlated genetic and EcoRI cleavage map of Bacillus subtilis bacteriophage phi105 DNA.

The seven previously identified EcoRI cleavage fragments of phi 105 DNA were ordered with respect to their sites of origin on the phage genome by marker rescue. One fragment, H, did not carry any determinants essential for replication. This fragment was totally missing in a deletion mutant which exhibited a lysogenization-defective phenotype. There is a nonessential region on the phi 105 genome which begins in fragment B, spans fragment H, and ends in fragment F. The size of the nonessential region, as estimated by alterations observed in the fragmentation patterns of deletion mutant DNAs, is approximately 2.7 X 10(6) daltons. Two new EcoRI cleavage fragments with molecular weights of approximately 0.2 X 10(6) were detected by autoradiography of 32P-labeled DNA. These small fragments were not located on the cleavage map.