Transferable Streptomyces DNA amplification and coamplification of foreign DNA sequences.

The 8.8-kb amplifiable unit of DNA of Streptomyces achromogenes subsp. rubradiris, AUD-Sar 1, which carries 0.8-kb terminal direct repeats and a spectinomycin resistance determinant, can mediate high-level amplification of an AUD-Sar 1-derived 8.0-kb DNA sequence not only in S. achromogenes but also in the heterologous host Streptomyces lividans. This was seen upon introduction of AUD-Sar 1 into chloramphenicol-sensitive strains of S. lividans via the temperature-sensitive (39 degrees C) plasmid pMT660, which contains the thiostrepton resistance gene tsr. Following the cultivation of transformants at 39 degrees C on media containing spectinomycin, a number of strains which were unable to grow on thiostrepton and which carried the amplified 8.0-kb DNA sequence as arrays of 200 to 300 copies of tandem 8.0-kb repeats were found. Chloramphenicol-resistant strains of S. lividans did not yield amplified sequences under similar conditions. Studies with plasmids carrying inserted antibiotic resistance genes at two sites of AUD-Sar 1 yielded coamplified sequences which contain the inserted DNA. Transformation with a plasmid carrying a 1.0-kb deletion in AUD-Sar 1 followed by growth under similar conditions yielded a 7.0-kb repeated DNA sequence. Southern analysis revealed the absence of vector sequences located on the right side of AUD-Sar 1 in the input plasmids in all examined DNA samples of amplified strains. In contrast, a majority of the samples revealed the presence at unit copy level of AUD-Sar 1 left-adjacent sequences which are part of the input plasmids and in several samples the presence of certain vector sequences located near them. The results suggest input plasmid integration into the S. lividans chromosome prior to the generation of the amplified sequences and the deletion of AUD-Sar 1 adjacent sequences.     

Cloning and amplified expression in Streptomyces lividans of a gene encoding extracellular beta-lactamase from Streptomyces albus G

A 4.9-kb DNA fragment containing the bla gene for the extracellular beta-lactamase (BLA) of Streptomyces albus G was cloned in Streptomyces lividans using the conjugative, low-copy-number plasmid pIJ61 as vector. No expression of bla was observed when this DNA fragment was introduced into Escherichia coli HB101 on a plasmid vector. A 1.5-kb PstI-SstI fragment containing the bla gene was cloned in S. lividans on the nonconjugative, high-copy-number plasmid pIJ702. A tenfold higher yield of BLA was obtained from S. lividans carrying this plasmid than from S. albus G grown under optimal production conditions. The BLA from the clone reacts with beta-iodopenicillanate according to a branched pathway which is characteristic of the original S. albus G BLA enzyme.     

DNA amplification in Streptomyces achromogenes subsp. rubradiris is accompanied by a deletion, and the amplified sequences are conditionally stable and can be eliminated by two pathways.

Southern blot analysis of BglII-digested DNA isolated from wild-type Streptomyces achromogenes, which harbors the 8.8-kilobase amplifiable unit of DNA, AUD-Sar 1, and of similarly digested DNA from 12 strains carrying an array of 200 to 300 tandem copies of a specific AUD-Sar 1-derived 8.0-kilobase DNA sequence, ADS-Sar 1, revealed the absence of the 12.4-kilobase BglII AUD-Sar 1-chromosome right junction band in the latter strains, whereas the corresponding 26.0-kilobase left junction band remained unaltered. Further Southern analyses indicated in all of the seven amplified strains tested the occurrence of a deletion of at least 10 kilobases of the DNA adjacent to the right side of the AUD. The deletion has one endpoint in the vicinity of the ADS array. Corroborating and expanding upon previously reported results, we found that the amplified DNA of strain C010 was stably maintained for at least 20 transfers when the transfers involved mycelia propagated in spectinomycin-free liquid medium. In contrast, when strain C010 was subjected separately to one cycle of protoplast formation and regeneration or to three cycles of spore germination, aerial mycelium formation, and sporulation on spectinomycin-free media, only approximately 20% of the protoplast regenerants and spores retained the reiterated DNA sequences and the ability subsequently to form colonies on media containing high levels of spectinomycin. Approximately 80% of these units completely deleted the reiterated DNA and left adjacent sequences and exhibited sensitivity to 25 micrograms of spectinomycin per ml. One among 24 protoplast-derived deletants apparently retained the left portion of the AUD-ADS left direct repeat plus left adjacent sequences.     

Transformation and transfection of anthracycline-producing streptomycetes.

Streptomyces peucetius and Streptomyces strain C5, producers or anthracycline antibiotics, were converted to protoplasts from vegetatively growing mycelia. Conditions are described for maximal protoplast formation (greater than 99%) and for regeneration frequencies of up to 13%. Streptomycete plasmids pIJ61, pIJ702, and pIJ922, from the replicons SLP1, pIJ101, and SCP2, respectively, were isolated from Streptomyces lividans 66 and successfully introduced into S. peucetius and Streptomyces strain C5 by polyethylene glycol-mediated protoplast transformation. Frequencies of up to 10(6) transformations X microgram of plasmid DNA-1 were achieved by these procedures. Analyses showed that the two anthracycline-producing strains can stably harbor the plasmids without deletion of plasmid sequences or loss of the plasmids for several transfers through selective media. Fragments of DNA from S. peucetius ligated into pIJ702 and introduced into Streptomyces strain C5 were stable after several transfers through selective media. Both anthracycline producers also were sensitive to infection and transfection by actinophages KC401 and KC515, clear plaque derivatives of bacteriophage phi C31. Optimal conditions were determined for the transfection of S. peucetius and Streptomyces strain C5 protoplasts with phi C31 KC401 and KC515 DNA with liposome-assisted, polyethylene glycol-mediated protoplast transfection.     

Plasmid transformation of Streptomyces tendae after heat attenuation of restriction.

Streptomyces tendae ATCC 31160 produces nikkomycin, a fungicide and insecticide that inhibits chitin synthases. Exposure of S. tendae protoplasts to 50 degrees C for 30 min is required for transformation (10(2) thiostrepton-resistant transformants micrograms of DNA-1) with plasmid pIJ702 or pIJ680 from Streptomyces lividans. pIJ702 and pIJ680 DNA isolated from the S. tendae transformants is efficient (10(6) to 10(7) transformants micrograms of DNA-1) in subsequent transformations of S. tendae protoplasts generated at 30 degrees C. PstI fails to cut the single PstI site in pIJ702 and cuts only one of the two PstI sites in pIJ680 DNA isolated from S. tendae transformants. Digests of plasmid DNA mixtures showed that plasmid DNA from S. tendae does not inhibit PstI activity. pIJ702 and pIJ680 DNA from S. tendae transformants was used to transform S. lividans to show that plasmid DNA remains unchanged, except for modification at some PstI sites in S. tendae, as a consequence of passage through S. tendae. The DNA modification is lost when S. lividans is transformed with plasmid DNA from S. tendae transformants. Since S. tendae modifies only some PstI sites, it appears the modification (presumably restriction activity also) activity in S. tendae recognizes a sequence that includes or overlaps the PstI hexanucleotide recognition sequence.     

Cloning and expression of the tyrosinase gene from Streptomyces antibioticus in Streptomyces lividans

In two separate studies a BclI-generated DNA fragment coding for the enzyme tyrosinase, responsible for melanin synthesis, was cloned from Streptomyces antibioticus DNA into two SLP1.2-based plasmid vectors (pIJ37 and pIJ41) to generate the hybrid plasmids, designated pIJ700 and pIJ701, using S. lividans 66 as the host. The fragment (1.55 kb) was subcloned into the multicopy plasmid pIJ350 (which carries thiostrepton resistance and has two non-essential BclI sites) to generate four new plasmids (pIJ702-pIJ705) with the tyrosinase insert located in either orientation at each site. All six plasmids conferred melanin production (the Mel+ phenotype) on their host. As in the S. antibioticus parent, strains of S. lividans carrying the gene specifying tyrosinase synthesis possessed an enzyme activity which was inducible. Most of the tyrosinase activity was secreted during growth of S. antibioticus; in contrast, the majority remained intracellular in the S. lividans clones. The specific activity of the induced tyrosinase activity (intracellular) was higher (up to 36-fold) when the gene was present on the multicopy vector in comparison with its location on the low copy plasmids, pIJ700 or pIJ701, or in S. antibioticus. Restriction mapping of the tyrosinase fragment in pIJ702 revealed endonuclease cleavage sites for several enzymes, including single sites for BglII, SphI and SstI that are absent from the parent vector (pIJ350). Insertion of DNA fragments at any one of these sites abolished the Mel+ phenotype. The results indicate that pIJ702 is a useful cloning vector with insertional inactivation of the Mel+ character as the basis of clone recognition.     

Analysis of the nourseothricin-resistance gene (nat) of Streptomyces noursei

A gene (nat) conferring resistance to the streptothricin antibiotic nourseothricin (Nc) was cloned from the producer Streptomyces noursei into Streptomyces lividans on the vector pIJ702 to form pNAT1. The nat gene was localized on a 1-kb SalI-MboI fragment, which also carries the nat promoter. Divergent promoter activity from the nat promoter region was identified on the cloned fragment using promoter probe plasmids pIJ486 and pIJ487. The nat gene is not expressed from its own promoter in Escherichia coli as shown by its failure to promote cat expression in promoter-less plasmid pBB100 and by the expression of NcR in only one orientation, when cloned in pUC19. In S. lividans 7A, harbouring plasmid pNAT1, an Nc-acetylating activity (NAT) was associated with the cloned resistance gene. The substrate specificity of NAT correlated well with the substrate range of the acetyltransferase in S. noursei and Tn1825-determined streptothricin resistance in Gram-negative bacteria. Moreover, an extract of S. lividans carrying pNAT1 showed specific serological cross-reactivity with an extract of E. coli carrying Tn1825.     

Plasmid transformation of Streptomyces tendae after heat attenuation of restriction

Streptomyces tendae ATCC 31160 produces nikkomycin, a fungicide and insecticide that inhibits chitin synthases. Exposure of S. tendae protoplasts to 50 degrees C for 30 min is required for transformation (10(2) thiostrepton-resistant transformants micrograms of DNA-1) with plasmid pIJ702 or pIJ680 from Streptomyces lividans. pIJ702 and pIJ680 DNA isolated from the S. tendae transformants is efficient (10(6) to 10(7) transformants micrograms of DNA-1) in subsequent transformations of S. tendae protoplasts generated at 30 degrees C. PstI fails to cut the single PstI site in pIJ702 and cuts only one of the two PstI sites in pIJ680 DNA isolated from S. tendae transformants. Digests of plasmid DNA mixtures showed that plasmid DNA from S. tendae does not inhibit PstI activity. pIJ702 and pIJ680 DNA from S. tendae transformants was used to transform S. lividans to show that plasmid DNA remains unchanged, except for modification at some PstI sites in S. tendae, as a consequence of passage through S. tendae. The DNA modification is lost when S. lividans is transformed with plasmid DNA from S. tendae transformants. Since S. tendae modifies only some PstI sites, it appears the modification (presumably restriction activity also) activity in S. tendae recognizes a sequence that includes or overlaps the PstI hexanucleotide recognition sequence.     

Transformation and transfection of anthracycline-producing streptomycetes

Streptomyces peucetius and Streptomyces strain C5, producers or anthracycline antibiotics, were converted to protoplasts from vegetatively growing mycelia. Conditions are described for maximal protoplast formation (greater than 99%) and for regeneration frequencies of up to 13%. Streptomycete plasmids pIJ61, pIJ702, and pIJ922, from the replicons SLP1, pIJ101, and SCP2, respectively, were isolated from Streptomyces lividans 66 and successfully introduced into S. peucetius and Streptomyces strain C5 by polyethylene glycol-mediated protoplast transformation. Frequencies of up to 10(6) transformations X microgram of plasmid DNA-1 were achieved by these procedures. Analyses showed that the two anthracycline-producing strains can stably harbor the plasmids without deletion of plasmid sequences or loss of the plasmids for several transfers through selective media. Fragments of DNA from S. peucetius ligated into pIJ702 and introduced into Streptomyces strain C5 were stable after several transfers through selective media. Both anthracycline producers also were sensitive to infection and transfection by actinophages KC401 and KC515, clear plaque derivatives of bacteriophage phi C31. Optimal conditions were determined for the transfection of S. peucetius and Streptomyces strain C5 protoplasts with phi C31 KC401 and KC515 DNA with liposome-assisted, polyethylene glycol-mediated protoplast transfection.     

Transfer of conjugative plasmids and mobilization of a nonconjugative plasmid between Streptomyces strains on agar and in soil.

The conjugative plasmid pIJ101 and its conjugative nondeletion derivatives pIJ303 and pIJ211 were tested for their transferability between strains of Streptomyces on laboratory media and in the soil environment. Their roles in the mobilization of the cloning vector plasmid pIJ702, a nonconjugative deletion derivative of pIJ101, were also examined. Biparental and triparental crosses were performed on agar slants and in sterile soil between the plasmid donor Streptomyces lividans and several recipient Streptomyces strains previously isolated from soil. Conjugative plasmids were transferred to seven recipients in slant crosses and to three recipients in soil. Plasmids isolated from recipients showed restriction fragment patterns identical to that of the original plasmid in S. lividans. Plasmid pIJ303 was transferred less frequently in soil than on slants, and the frequency of transfer was higher at 30 degrees C than at the other temperatures examined. Transconjugant Streptomyces strains differed in their ability to maintain pIJ303. The nonconjugative plasmid pIJ702 was mobilized on agar slants into S. coelicolor 2708, which already contains a self-transmissible plasmid. Plasmid pIJ702 was also mobilized into S. flavovirens, Streptomyces sp. strain 87A, and S. parvulus on slants and in sterile soil after triparental crosses with two donors, one containing pIJ702 and the other containing either pIJ101 or pIJ211. The presence of a conjugative plasmid donor was required for the transfer of pIJ702 to S. parvulus 1234, S. flavovirens 28, and Streptomyces sp. strain 87A. Plasmid pIJ702 was always transferred in its normal, autonomous form. Chromosomal recombination also occurred in transconjugants after the transfer of pIJ702. This is the first report of gene transfer between Streptomyces strains in soil.     

High frequency transformation of Streptomyces niveus protoplasts by plasmid DNA.

A procedure has been developed for transforming protoplasts of the novobiocin producing strain Streptomyces niveus at high frequency. This required the isolation of strains LH13 and LH20 defective in DNA restriction from the wild type (ATCC 19793) which is transformed at very low frequencies. The LH13 and LH20 derivatives were obtained by curing pIJ702 DNA from the few S. niveus transformed protoplasts obtained by transformation of the wild type with high concentrations of pIJ702 DNA. Protoplasts of S. niveus strains LH13 and LH20 produced about 10(6) transformants/micrograms DNA with modified pIJ702 DNA derived by replication in S. niveus. Unmodified DNA (derived from replication in S: lividans) from a series of pIJ101, SCP2 and pSN2-based derivatives, gave transformation frequencies in the range of 10(2)-10(3) transformants/micrograms DNA. Optimal conditions for the formation and transformation of S. niveus protoplasts are described.     

Development of a system for cloning a DNA fragment, containing the determinant of resistance to actinomycin for Streptomyces chrysomallus No.2--a producer of actinomycin C]

To study the modes of actinomycin biosynthesis and the mechanism responsible for resistance to the antibiotic producing S. chrysomallus No. 2, the authors undertook an examination and studies into the cloning system for gene(s) of resistance to actinomycin from a S. chrysomallus No. 2 actinomycin C producer and the cloning of a S. chrysomallus No. DNA fragment to the actinomycin-sensitive Streptomyces Sp. 26-115 H-I on the vector plasmid pIJ702. The cloning gave rise to actinomycin-resistant strains. The character of actinomycin resistance is inheritable in a steady fashion.     

Cloning of a chloramphenicol acetyltransferase gene of Streptomyces acrimycini and its expression in Streptomyces and Escherichia coli

A gene (cat) for chloramphenicol (Cm) acetyltransferase (CAT) was cloned from Streptomyces acrimycini into S. lividans 66 on the plasmid vector pIJ61. The cat gene was localized on a 1.7-kb BclI fragment, which probably also carries the cat promoter. This DNA fragment conferred Cm resistance, through CAT activity, on S. lividans, S. coelicolor and S. parvulus, but not on Escherichia coli when inserted in the BamHI site of the tetracycline-resistance(TcR) gene of pBR322. However, when inserted in a particular orientation in this site, spontaneous deletions of 0.7 kb led to CAT activity and Cm resistance. DNA homologous to the 1.7-kb BclI cat fragment was found in most, but not all, of a series of other streptomycetes that have CAT activity. The cat provides a potentially useful screening marker for Streptomyces cloning vectors.     

Properties of in vitro recombinant derivatives of pJV1, a multi-copy plasmid from Streptomyces phaeochromogenes

The 10.8 kb plasmid pJV1, isolated from Streptomyces phaeochromogenes, has a high copy number (about 150) and a broad host range among Streptomyces spp. Several pJV1 derivatives carrying the thiostrepton resistance gene (tsr) of S. azureus were made. One derivative, pWOR191, was shown to promote its own transfer and to mobilize chromosomal markers in S. lividans. Another derivative, pWOR109, was non-transmissible. Deletion in vitro of a segment of pWOR109 gave pWOR120 (5.6 kb), which has single BamHI and Bg/II sites shown to be capable of accepting 'foreign' DNA such as a previously cloned S. antibioticus DNA fragment encoding tyrosinase, giving vectors (pWOR125, pWOR126) with properties resembling the well-established multicopy vector pIJ702. Shuttle vectors capable of functioning in both S. lividans and Escherichia coli were also constructed. The region of pJV1 essential for replication and maintenance was localized to a 2.5 kb segment. Stable maintenance of pWOR109 and pWOR120 was observed in the presence of derivatives of pIJ101, the progenitor of pIJ702.     

Transformation of Arthrobacter and studies on the transcription of the Arthrobacter ermA gene in Streptomyces lividans and Escherichia coli.

We report the development of a plasmid-mediated transformation system for Arthrobacter sp. NRRLB3381, using the Streptomyces cloning vector pIJ702. Our procedure gives a transformation frequency of 10(3)/micrograms of plasmid DNA. In addition we have explored the expression of the Arthrobacter ermA gene in Streptomyces lividans and Escherichia coli, and shown that the ermA promoter is recognized in S. lividans not E. coli. The relationship between Arthrobacter, Streptomyces and E. coli promoters is discussed.     

Cloning of the xylanase gene of Streptomyces lividans

The xylanase (xln) gene of Streptomyces lividans 1326 was cloned by functional complementation of the xylanase-negative and beta-1,4-glucan-glucanohydrolase-negative double mutant of S. lividans using the multicopy plasmid pIJ702. Three clones had a common 2-kb DNA fragment as determined by restriction mapping and Southern hybridization. These clones secreted a xylanase of Mr 43,000 which reacted with specific anti-xylanase antibodies and corresponded exactly to the enzyme previously isolated from the wild-type strain. The DNA fragment likely carried the full structural gene, the xln promoter and also the regulatory sequence, since the xylanase activity was inducible by xylan. Enzyme levels of up to 380 IU/ml of culture filtrate were obtained.     

Transfer of conjugative plasmids and mobilization of a nonconjugative plasmid between Streptomyces strains on agar and in soil

The conjugative plasmid pIJ101 and its conjugative nondeletion derivatives pIJ303 and pIJ211 were tested for their transferability between strains of Streptomyces on laboratory media and in the soil environment. Their roles in the mobilization of the cloning vector plasmid pIJ702, a nonconjugative deletion derivative of pIJ101, were also examined. Biparental and triparental crosses were performed on agar slants and in sterile soil between the plasmid donor Streptomyces lividans and several recipient Streptomyces strains previously isolated from soil. Conjugative plasmids were transferred to seven recipients in slant crosses and to three recipients in soil. Plasmids isolated from recipients showed restriction fragment patterns identical to that of the original plasmid in S. lividans. Plasmid pIJ303 was transferred less frequently in soil than on slants, and the frequency of transfer was higher at 30 degrees C than at the other temperatures examined. Transconjugant Streptomyces strains differed in their ability to maintain pIJ303. The nonconjugative plasmid pIJ702 was mobilized on agar slants into S. coelicolor 2708, which already contains a self-transmissible plasmid. Plasmid pIJ702 was also mobilized into S. flavovirens, Streptomyces sp. strain 87A, and S. parvulus on slants and in sterile soil after triparental crosses with two donors, one containing pIJ702 and the other containing either pIJ101 or pIJ211. The presence of a conjugative plasmid donor was required for the transfer of pIJ702 to S. parvulus 1234, S. flavovirens 28, and Streptomyces sp. strain 87A. Plasmid pIJ702 was always transferred in its normal, autonomous form. Chromosomal recombination also occurred in transconjugants after the transfer of pIJ702. This is the first report of gene transfer between Streptomyces strains in soil.