Functional analysis of the Streptomyces ambofaciens element pSAM2.

pSAM2 is an 11-kb element integrated in the Streptomyces ambofaciens ATCC23877 genome and found additionally as a free replicon present at several copies per chromosome in strain JI3212, the derivative of ATCC23877 isolated after uv irradiation. In spite of its small size, this element specifies numerous functions including maintenance, site-specific integration, self-transmissibility, pock formation, and mobilization of chromosomal markers. After transfer of the free form of pSAM2 to Streptomyces lividans, the free and the integrated forms coexist. A functional map of pSAM2 was deduced from phenotypes exhibited in S. lividans by numerous deletion or insertion derivatives. In addition to the previously characterized regions sufficient for site-specific integration we have shown that separate regions are involved in either plasmid maintenance as a free molecule, plasmid transfer, and pock formation. Transfer of pSAM2 could depend on its ability to be maintained in a free form, since plasmids deficient in this function are transferred at very low frequency. Deletions of some regions of the plasmid are lethal for the plasmid or the host, but if some other regions are deleted simultaneously, transformants can be obtained.     

Excision and integration of a self-transmissible replicon of Streptomyces ambofaciens

When Streptomyces ambofaciens OSF was crossed with the plasmid-free Streptomyces lividans TK24, almost all S. lividans exconjugants contained the free 11.1-kb plasmid pOS1. Southern hybridizations showed that pOS1 was derived from the integrated copy of previously recognized plasmid pSAM2 present in strain OSF. A shorter derivative of pOS1 was constructed carrying the tsr gene in a non-essential region, and this pOS7 plasmid was used in transformation experiments with protoplasts of S. ambofaciens ATCC23877 (containing pSAM2 only as an integrated sequence) and S. ambofaciens DSM40697 (devoid of pSAM2-related forms). In both cases, some clones carrying pOS7 in an integrated state were found. Integration into strain ATCC23877 was into the pre-existing integrated copy of pSAM2. In contrast, plasmid pOS7 integrated through specific plasmidic and chromosomal sites into strain DSM40697. Thus it is probable that pSAM2 integrates by interaction between preferred regions of the plasmid and host genomes.     

The integrated conjugative plasmid pSAM2 of Streptomyces ambofaciens is related to temperate bacteriophages.

Streptomyces ambofaciens ATCC23877 and derivatives contain the 11-kb element pSAM2 present in an integrated state or as a free and integrated plasmid. This element, able to integrate site-specifically in the genome of different Streptomyces species, is conjugative and mobilizes chromosomal markers. Besides these plasmid functions, we have shown that the site-specific recombination system of pSAM2 presents strong similarities with that of several temperate phages. The integration event is promoted by a site-specific recombinase of the integrase family. The int gene encoding this integrase is closely linked to the plasmid attachment site (attP). A small open reading frame (ORF) overlaps the int gene and the predicted protein exhibits similarities with Xis proteins involved in phages excision. The integrated copy of pSAM2 in strain ATCC23877 is flanked by att sequences (attL and attR). Another att sequence (attX) is present in this strain and attX and attL are the boundaries of a 42-kb fragment (xSAM1) absent, as well as pSAM2, from S.ambofaciens DSM40697. Sequences partially similar to pSAM2 int gene are found near the chromosomal integration zone in both S.ambofaciens strains. The possible origin of pSAM2, an element carrying plasmid as well as phage features, is discussed.     

Structural analysis of loci involved in pSAM2 site-specific integration in Streptomyces

pSAM2 is an 11-kb plasmid integrated in the Streptomyces ambofaciens ATCC23877 and ATCC15154 genomes and found additionally as a free replicon in an uv derivative. After transfer into S. ambofaciens DSM40697 (devoid of pSAM2) or into Streptomyces lividans, specific integration of pSAM2 occurred very efficiently. A 58-bp sequence (att) present in both pSAM2 (attP) and S. ambofaciens strain DSM40697 (attB) attachment regions is found at the boundaries (attL and attR) of integrated pSAM2 in S. ambofaciens strain ATCC23877. The S. lividans chromosomal integration zone contained an imperfectly conserved att sequence (attB), and the integration event of pSAM2 was located within a 49-bp sequence of attB. Only one primary functional attB sequence was present in the S. lividans or S. ambofaciens DSM40697 total DNA. The integration zone of S. lividans hybridized with the integration zone of S. ambofaciens DSM40697. The two integration zones were homologous only to the right side of the att sequence. The conserved region contained an open reading frame (ORF A) with a stop codon located 99 bp from the attB sequence in both strains. S. ambofaciens DSM40697 contained DNA sequences related to pSAM2 on the left side of the att site. The att sequence was included in a region conserved in Streptomyces antibioticus, Streptomyces actuosus, Streptomyces bikiniensis, Streptomyces coelicolor, Streptomyces glaucescens, and Streptomyces parvulus. Site-specific integration of a pSAM2 derivative was characterized in another unrelated strain, Streptomyces griseofuscus. This strain contained an imperfectly conserved 58-bp attB sequence, and the integration event took place within a 45-bp sequence of attB. Site-specific integration of pSAM2 in three nonrelated Streptomyces strains suggests the wide host range of pSAM2 integration in Streptomyces.     

Site-specific integration of plasmid pSAM2 in Streptomyces lividans and S. ambofaciens

Summary Streptomyces ambofaciens strain ATCC23877 contains the 11.1 kb plasmid pSAM2 stably integrated into its chromosome. This plasmidic sequence is able to loop out and to be transferred at high frequency to S. lividans where it is found simultaneously as both free and integrated plasmid. When a UV derivative of strain ATCC23877 (strain ATCC15154) is used, the resident copy of pSAM2 can be transferred to S. lividans, but only the integrated form is found in this strain. In both cases, the integration occurs at a unique chromosomal region through the same plasmidic integration site as that in strain ATCC23877. The resident copy of strain ATCC15154 can also be transferred at low frequency to S. ambofaciens DSM40697 (devoid of any pSAM2 sequence). In this case, as several copies of pSAM2 are integrated, the integration pattern is complicated. Integration of a complete pSAM2 sequence in this strain occurs in a region that hybridizes with the integration zones of S. lividans and of S. ambofaciens strain ATCC23877. Comparison of the cloned integration zone of S. lividans before and after the integration event showed that the restriction pattern of the resident pSAM2 in strain ATCC15154 is similar to that of the free form of pSAM2 found naturally in another UV derivative of strain ATCC23877 (strain JI3212).     

Pulsed-field gel electrophoresis analysis of the genome of Streptomyces ambofaciens strains

The genome of four Streptomyces ambofaciens strains from different geographical origins (ATCC15154, DSM40697, ETH9247 and ETH 11317) was analysed by pulsed-field gel electrophoresis (PFGE). The PFGE technique has allowed the study of the extrachromosomal content of these strains and the characterization of their genomic DNA by restriction analyses. Electrophoretic migration of undigested DNA allowed us to detect a 80 kb-length linear molecule with concatemeric forms in S. ambofaciens ATCC15154. These extrachromosomal molecules were shown to be homologous to the circular plasmid pSAM1 (80 kb) suggesting that pSAM1 could exist not only in circular form but also in linear form. In the same way a 45 kb-length linear molecule was detected in S. ambofaciens ETH9427 and ETH11317. In contrast, no extrachromosomal DNA could be detected in S. ambofaciens DSM40697. The analysis of the macrorestriction patterns using the rate-cutting enzymes AseI and DraI indicated a close relationship between the DSM- and ETH- strains. Indeed, three types of restriction patterns were distinguished: while S. ambofaciens ETH9427 and ETH11317 were characterized by the same pattern and share more than 75% of comigrating fragments with the strain DSM40697, S. ambofaciens ATCC15154 exhibited a restriction pattern different from the other three. The total genome sizes of S. ambofaciens ATCC15154, DSM40697, ETH9427 and ETH11317 were estimated to be about 6500, 8000, 8200 and 8200 kb, respectively.     

Plasmid cloning vectors that integrate site-specifically in Streptomyces spp

Cloning vectors based on the Streptomyces ambofaciens plasmid pSAM2 and the streptomycete phage phi C31 were developed for use in Streptomyces spp. These vectors replicate in Escherichia coli but integrate by site-specific recombination in Streptomyces spp. Both pSAM2-based and phi C31-based vectors transformed a number of different Streptomyces spp; however, the phi C31-based vectors consistently transformed at higher frequencies than pSAM2-based vectors. Southern analysis indicated that the phi C31-based vectors integrated at a unique site in the S. ambofaciens chromosome, while the pSAM2-based vectors gave complex patterns which could indicate structural instability or use of multiple loci. Both types of vectors utilize the apramycin (Am)-resistance gene which can be selected in E. coli and Streptomyces spp. with either Am or the commercially available antibiotic Geneticin (G418).     

Genetic analysis in Streptomyces ambofaciens

A chromosomal linkage map of ten markers was established for Streptomyces ambofaciens by the four-factor cross method and allele-gradient analysis. Mutants were obtained by nitrous acid treatment as well as UV mutagenesis. The fertility of crosses was enhanced over 100-fold by pSAM2, a plasmid present in some strains of S. ambofaciens, and over 1000-fold by the conjugative plasmid pIJ303.     

Cloning of Frankia species putative tRNA(Pro) genes and their efficacy for pSAM2 site-specific integration in Streptomyces lividans.

pSAM2 is a conjugative Streptomyces ambofaciens mobile genetic element that can transfer and integrate site specifically in the genome. The chromosomal attachment site (attB) for pSAM2 site-specific recombination for two Frankia species was analyzed. It overlaps putative proline tRNA genes having a 3'-terminal CCA sequence, an uncommon feature among actinomycetes. pSAM2 is able to integrate into a cloned Frankia attB site harbored in Streptomyces lividans. The integration event removes the 3'-terminal CCA sequence and introduces a single nucleotide difference in the T psi C loop of the putative Frankia tRNA(Pro) gene. Major differences between the attP sequence from pSAM2 and the Frankia attB sequence restrict the identity segment to a 43-bp-long region. Only one mismatch is found between these well-conserved att segments. This nucleotide substitution makes a BstBI recognition site in Frankia attB and was used to localize the recombination site in a 25-bp region going from the anticodon to the T psi C loop of the tRNA(Pro) sequence. Integration of pSAM2 into the Frankia attB site is the first step toward introduction of pSAM2 derivatives into Frankia spp.     

Site-specific integration of the Streptomyces plasmid pSAM2 in Mycobacterium smegmatis

A method which allowed the stable integration of DNA fragments at a single site (attB) in the chromosome of Mycobacterium smegmatis was developed using an integrative element from Streptomyces ambofaciens, pSAM2. Vectors containing an Escherichia coli replicon (pBR322), the kanamycin resistance gene from Tn903 for selection in mycobacteria, and a fragment of pSAM2 containing the int gene as well as the attachment site (attP) were constructed and introduced to M. smegmatis by electroporation. Transformants showed stable integration of the plasmid into a single site (attB) of the mycobacterial genome. This approach should be valuable for analyses of gene expression in various mycobacterial species and permit the development of stable recombinant mycobacterial vaccine strains expressing bacterial or viral genes inserted in pSAM2.     

Structure of the chromosomal insertion site for pSAM2: functional analysis in Escherichia coli

The element pSAM2 from Streptomyces ambofaciens integrates into the chromosome through site-specific recombination between the element ( att  P) and the chromosomal ( att  B) sites. These regions share an identity segment of 58 bp extending from the anti-codon loop through the 3' end of a tRNA^Pro gene. To facilitate the study of the att  B site, the int and xis genes, expressed from an inducible promoter, and att  P from pSAM2 were cloned on plasmids in Escherichia coli . Compatible plasmids carrying the different att  B regions to be tested were introduced in these E . coli strains. Under these conditions, Int alone could promote site-specific integration; Int and Xis were both required for site-specific excision. This experimental system was used to study the sequences required in att  B for efficient site-specific recombination. A 26 bp sequence, centred on the anti-codon loop region and not completely included in the identity segment, retained all the functionality of att  B; shorter sequences allowed integration with lower efficiencies. By comparing the 26-bp-long att  B with att  P, according to the Lambda model, we propose that B and B', C and C' core-type Int binding sites consist of 9 bp imperfect inverted repeats separated by a 5 bp overlap region.     

Amino acid catabolism and antibiotic synthesis: valine is a source of precursors for macrolide biosynthesis in Streptomyces ambofaciens and Streptomyces fradiae.

Targeted inactivation of the valine (branched-chain amino acid) dehydrogenase gene (vdh) was used to study the role of valine catabolism in the production of tylosin in Streptomyces fradiae and spiramycin in Streptomyces ambofaciens. The deduced products of the vdh genes, cloned and sequenced from S. fradiae C373.1 and S. ambofaciens ATCC 15154, are approximately 80% identical over all 363 amino acids and 96% identical over a span of the first N-terminal 107 amino acids, respectively, to the deduced product of the Streptomyces coelicolor vdh gene. The organization of the regions flanking the vdh genes is the same in all three species. Inactivation of the genomic copy of the vdh gene in S. fradiae and S. ambofaciens by insertion of a hygromycin resistance (hyg) gene caused loss of the valine dehydrogenase (Vdh) activity, and thus only one enzyme is responsible for the Vdh activity in these organisms. Analysis of the culture broth by bioassay revealed that the vdh::hyg mutants produce an approximately sixfold-lower level of tylosin and an approximately fourfold-lower level of spiramycin than the wild-type S. fradiae and S. ambofaciens strains, while maintaining essentially identical growth in a defined minimal medium with either 25 mM ammonium ion or 0.05% asparagine as the nitrogen source. The addition of the valine catabolite, propionate or isobutyrate, and introduction of the wild-type vdh gene back to each vdh::hyg mutant reversed the negative effect of the vdh::hyg mutation on spiramycin and tylosin production. These data show that the catabolism of valine is a major source of fatty acid precursors for macrolide biosynthesis under defined growth conditions and imply that amino acid catabolism is a vital source of certain antibiotic precursors in actinomycetes.     

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.     

Site-Specific Integration of the Double-Mutation Glucose Isomerase (GIG138PG247D) Gene in Streptomyces lividans and Its Stable Expression

A recombinant expression plasmid pYH12, containing the double-mutation glucose isomerase (GIG138PG247D, GI2) coding gene and its natural regulatory sequence, was constructed for site-specific integration in Streptomyces. The resulting plasmid was introduced into Streptomyces lividans TK54 by protoplast transformation and two apramycin-resistance (Am^R) transformants, designated GY2 and BY7, respectively, were obtained further based on enzyme assays. These results for polymerase chain reaction (PCR), Dot blot, and recovery of cloned fragments from the transformant chromosome indicated that the GI2 gene was integrated into the S. lividans chromosome by site-specific recombination, and which was further verified by Southern blot. We found that the free form of plasmid pYH12 co-existing with the integrated form was present in S. lividans. SDS-PAGE analysis showed that the GI2 gene was expressed in S. lividans. The intracellular GI2 specific activity was 1.15 U/mg. The stability of integrants demonstrated that the cloned GI2 gene was stably integrated and expressed even in the absence of selective pressure. Received: 28 March 2001 / Accepted: 14 May 2001     

Selection of Streptomyces ambofaciens mutants that produce large quantities of spiramycin and determination of optimal conditions for spiramycin production.

The aim of this work was to develop a strategy to isolate a morphologically stable mutant of Streptomyces ambofaciens ATCC 15154 which produced high titers of spiramycin. The rationale was to grow a nitrosoguanidine-mutated population for many generations under nonselective conditions followed by two cycles of protoplast formation and regeneration. A total of 2,400 surviving colonies were then screened for spiramycin production and subsequently checked for stability. From this experiment, strain 6-37 was isolated that produced 181 mg of spiramycin per liter and only one morphological type. The parent strain (ATCC 15154) produced 107 mg of spiramycin per liter and four morphological types. Strain 6-37 was then mutated with nitrosoguanidine, and 14,000 colonies were screened for spiramycin production. From this experiment, five strains were isolated that produced titers ranging from 187 to 373 mg of spiramycin per liter. Subsequent media and time studies with these strains resulted in a fermentation that produced 1,728 mg of spiramycin per liter.     

Plasmids in different strains of Streptomyces ambofaciens: free and integrated form of plasmid pSAM2

Summary Five strains of Streptomyces ambofaciens were examined for their plasmid content. Among these strains, four belong to the same lineage (strains B) and the other was isolated independently (strain A). A large plasmid (ca. 80 kb), called pSAM1 in this paper and already described, was present in all B strains, and absent in strain A. A second plasmid, not described before, was found as covalently closed circular DNA in two of the four B strains. This plasmid with a size 11.1 kb was called pSAM2. A restriction map for 14 enzymes was established. Hybridization experiments showed that a unique sequence homologous to this plasmid is integrated in a larger replicon, which is not pSAM1 and is probably the chromosome, in all B strains and not in strain A. It seems probable that the integrated se1uence is the origin of the free plasmid found in two strains of the B family. It is noteworthy that the integrated form and the free plasmid may be found together. Transformation experiments proved that pSAM2 may be maintained autonomously in S. ambofaciens strain A and in S. lividans. pSAM2 is a self-transmissible plasmid, able to elicit the lethal zygosis reaction. pSAM2 was compared to the plasmids SLP1, pIJ110 and pIJ408, which all come from integrated sequences in three Streptomyces species and are found as autonomous plasmids after transfer to S. lividans. If pSAM2 resembles these plasmids in its origin, it does not appear to be related directly to them. Concerning their plasmid content, the two isolates of S. ambofaciens are very different. One of them contains neither pSAM1 not pSAM2. As this isolate produces spiramycin, these plasmids probably do not play an important role in spiramycin production. Apart from its intrinsic biological interest, pSAM2 may be useful in the construction of cloning vectors for S. ambofaciens. Very stable transformants might be obtained in certain strains of S. ambofaciens, because of the possibility of integration of the pSAM2 derivative vector.     

Transfer functions of the conjugative integrating element pSAM2 from Streptomyces ambofaciens: characterization of a kil-kor system associated with transfer.

pSAM2 is an 11-kb integrating element from Streptomyces ambofaciens. During matings, pSAM2 can be transferred at high frequency, forming pocks, which are zones of growth inhibition of the recipient strain. The nucleotide sequences of the regions involved in pSAM2 transfer, pock formation, and maintenance have been determined. Seven putative open reading frames with the codon usage typical of Streptomyces genes have been identified: traSA (306 amino acids [aa]), orf84 (84 aa), spdA (224 aa), spdB (58 aa), spdC (51 aa), spdD (104 aa), and korSA (259 aa). traSA is essential for pSAM2 intermycelial transfer and pock formation. It could encode a protein with similarities to the major transfer protein, Tra, of pIJ101. TraSA protein contains a possible nucleotide-binding sequence and a transmembrane segment. spdA, spdB, spdC, and spdD influence pock size and transfer efficiency and may be required for intramycelial transfer. A kil-kor system similar to that of pIJ101 is associated with pSAM2 transfer: the korSA (kil-override) gene product could control the expression of the traSA gene, which has lethal effects when unregulated (Kil phenotype). The KorSA protein resembles KorA of pIJ101 and repressor proteins belonging to the GntR family. Thus, the integrating element pSAM2 possesses for transfer general features of nonintegrating Streptomyces plasmids: different genes are involved in the different steps of the intermycelial and intramycelial transfer, and a kil-kor system is associated with transfer. However, some differences in the functional properties, organization, and sizes of the transfer genes compared with those of other Streptomyces plasmids have been found.     

The integrative element pSAM2 from Streptomyces: kinetics and mode of conjugal transfer

pSAM2 is an 11 kb integrative element from Streptomyces ambofaciens that is capable of conjugal transfer. A system based on differential DNA modification by SalI methyltransferase was used to localize pSAM2 in the donor or recipient strain, and thus to determine the various steps associated with transfer. Initiation (i.e. excision and replication of pSAM2 in the donor) occurs a few hours after mating with a recipient strain. pSAM2 replicates in the recipient strain, spreads within the mycelium and then integrates into the chromosome. Transfer generally involves single-stranded DNA. In Streptomyces, only a few genes, such as traSA for pSAM2, are required for conjugal transfer. Using the differential sensitivity to the SalI restriction-modification system of transfers involving single- and double-stranded DNA, we found that pSAM2 was probably transferred to the recipient as double-stranded DNA. This provides the first experimental evidence for the transfer of double-stranded DNA during bacterial conjugation. Thus, TraSA, involved in pSAM2 transfer, and SpoIIIE, which is involved in chromosome partitioning in Bacillus subtilis, display similarities in both sequence and function: both seem to transport double-stranded DNA actively, either from donor to recipient or from mother cell to prespore.