Genetic instability and associated genome plasticity in Streptomyces ambofaciens: pulsed-field gel electrophoresis evidence for large DNA alterations in a limited genomic region.

Using pulsed-field gel electrophoresis (PFGE) analysis, the amplifiable units of DNA (AUD) loci AUD6 and AUD90 of Streptomyces ambofaciens DSM40697 could be mapped in the wild-type genome within two adjacent AseI restriction fragments estimated to be about 75 and 850 kb. In addition, the genetic instability and formation of very large deletions were strictly correlated. Their sizes were estimated to range from 250 to more than 2,000 kb. These deletions affected the DNA region overlapping both amplifiable loci. PFGE also allowed us to localize the amplified DNA sequences and to establish their structure: amplification takes place at the AUD locus as a tandem array of the wild-type AUD sequence.     

Heterogeneous genomic amplification in Streptomyces glaucescens: structure, location and junction sequence analysis

Summary Certain chromosomal markers inStreptomyces glaucescens behave unstably, being lost at high frequency as a result of extensive genomic deletion. Additionally, mutant strains possessing such deletions frequently display intense DNA amplification. With the help of a wild-type cosmid library we investigated the structure of the amplified DNA sequences (ADS) and the corresponding wild-type amplifiable units of DNA (AUD). The reiterations were heterogeneous in location, copy number and sequences involved and originated predominantly from a single 100 kb region of the chromosome called the AUD locus. All strains bearing reiterations possessed associated deletions which terminated either close to or at the ADS. The termini of four AUDs were sequenced in order to gain more knowledge about these heterogeneous amplifications. In three of the four cases investigated small, interrupted homologies were found bordering the AUDs. With the help of orthogonal-field-alternation gel electrophoresis (OFAGE) we were able to visualize a tandem reiteration of more than 1500 kb in length.     

The very large amplifiable element AUD2 from Streptomyces lividans 66 has insertion sequence-like repeats at its ends.

In a spontaneous, chloramphenicol-sensitive (Cms), arginine-auxotrophic (Arg-) mutant of Streptomyces lividans 1326, two amplified DNA sequences were found. One of them was the well-characterized 5.7-kb ADS1 sequence, amplified to about 300 copies per chromosome. The second one was a 92-kb sequence called ADS2. ADS2 encoding the previously isolated mercury resistance genes of S. lividans was amplified to around 20 copies per chromosome. The complete ADS2 sequence was isolated from a genomic library of the mutant S. lividans 1326.32, constructed in the phage vector lambda EMBL4. In addition, the DNA sequences flanking the corresponding amplifiable element called AUD2 in the wild-type strain were isolated by using another genomic library prepared from S. lividans 1326 DNA. Analysis of the ends of AUD2 revealed the presence of an 846-bp sequence on both sides repeated in the same orientation. Each of the direct repeats ended with 18-bp inverted repeated sequences. This insertion sequence-like structure was confirmed by the DNA sequence determined from the amplified copy of the direct repeats which demonstrated a high degree of similarity of 65% identity in nucleic acid sequence to IS112 from Streptomyces albus. The recombination event leading to the amplification of AUD2 occurred within these direct repeats, as shown by DNA sequence analysis. The amplification of AUD2 was correlated with a deletion on one side of the flanking chromosomal region beginning very near or in the amplified DNA. Strains of S. lividans like TK20 and TK21 which are mercury sensitive have completely lost AUD2 together with flanking chromosomal DNA on one or both sides.     

Extremely large chromosomal deletions are intimately involved in genetic instability and genomic rearrangements in Streptomyces glaucescens

Summary Genetic instability inStreptomyces glaucescens characteristically involves the occurrence of gross genomic rearrangements including high-level sequence amplification and extensive deletion. We investigated the relationship of the unstablemelC andstrS loci and a 100 kb region of the chromosome which frequently gives rise to intense heterogeneous DNA amplification. Standard chromosome walking using a cosmid bank in conjunction with a “reverse-blot” procedure enabled us to construct a contiguous genomicBamHI map of the unstable region exceeding 900 kb. The unstable genes and the amplifiable region (AUD locus) are physically linked within a 600 kb segment of the chromosome. The previously characterized deletions which affect these loci are merely components of much larger deletions ranging from 270 to over 800 kb which are polar in nature, effecting the sequential loss of thestrS andmelC loci. The more extensive deletions terminate either adjacent to, or in the vicinity of DNA reiterations at the AUD locus. Additionally, a deletion junction fragment and the corresponding deletion ends were cloned and analysed at the sequence level.     

Genetic instability and DNA amplification in Streptomyces lividans 66.

Streptomyces lividans 66 exhibits genetic instability, involving sequential loss of resistance to chloramphenicol (Cams) and subsequent mutation of argG. Associated with this instability is the amplification of a 5.7-kilobase (kb) amplified DNA sequence (ADS). We have characterized a second, independent pathway of genetic instability, involving sequential loss of resistance to tetracycline (Tets) followed by mutation in nitrogen assimilation (Ntr). We detected DNA amplification in many of these mutant strains, as well as other reiterations coresident with the 5.7-kb ADS in Cams Arg mutants. However, in contrast to the 5.7-kb ADS, none of the novel elements were observed to amplify at high frequency. The mutation of argG is due to a deletion, one endpoint of which is defined by the 5.7-kb ADS. This amplification derives from a structure, the tandemly duplicated amplifiable unit of DNA (AUD), present in the wild-type genome. We found that progenitor strains containing just a single-copy AUD failed to reproducibly generate amplification of this element in Cams argG mutants, and DNA deletion endpoints proximal to the element were found to be unspecific. These results suggest that a duplicated AUD structure is required for high-frequency amplification and that this reiteration can subsequently buffer the extent of deletion formation in the relevant chromosomal region.     

Nucleotide sequence and role in DNA amplification of the direct repeats composing the amplifiable element AUD1 of Streptomyces lividans 66

The amplifiable unit of DNA no. 1 (AUD1) of Streptomyces lividans consists of three 1 kb repeats (left direct repeat, LDR; middle direct repeat, MDR; and the slightly different right direct repeat, RDR) and two 4.7 kb repeats alternately arranged in identical orientation to each other. Both 4.7 kb repeats have been sequenced. They are identical and contain one open reading frame ( orf4.7  ). The deduced amino acid sequence has a low similarity to chitinases, and two amino acid repeats present high similarities to fibronectin type III modules. Sequencing had previously shown that the ORF corresponding to each 1 kb repeat encodes a putative DNA-binding protein. Crude extracts of Escherichia coli overexpressing the orfRDR- encoded protein and of S. lividans Jni1, having a high amplification of AUD1 and therefore orfMDR , were used in gel retardation assays. The orfRDR - and probably the orfMDR -encoded proteins can bind to an imperfect palindromic sequence upstream from MDR and RDR and to another sequence downstream from RDR. An extrachromosomal DNA amplification system was constructed containing different combinations of the sequences composing AUD1. In mutants having a deletion of the chromosomal AUD1, the 4.7 kb repeats could be reduced in size, mutated or replaced by E. coli DNA without altering the ability to amplify when RDR was present. Therefore, the only function of the 4.7 kb repeats in amplification is to provide directly repeated DNA sequences. When RDR was lacking or mutated, no amplification was observed. This strongly suggests that the DNA-binding protein encoded by orfRDR is required for AUD1 amplification.     

Primary structure analysis of a duplicated region in the amplifiable AUD6 locus of Streptomyces ambofaciens DSM40697

Abstract In Streptomyces ambofaciens , an amplifiable unit of DNA ( AUD6 ) contains two homologous sequences, one located on the right extremity of the AUD ( S1R ), the other being internal ( IHS ). This paper presents the molecular analysis of this duplication. The nucleotide sequences are almost identical (95%) and each contains an ORF of about 330 codons, the two ORFs being nearly identical. The two hypothetical proteins, deduced from these sequences, show about 30% identity with different bacterial repressors. They also show a particularly strong similarity (90% identity between the full-length sequences) with hypothetical proteins of Streptomyces lividans 66 encoded by sequences also present on an amplifiable DNA region ( AUD1 ).     

Evolution of the terminal regions of the Streptomyces linear chromosome

Comparative analysis of the Streptomyces chromosome sequences, between Streptomyces coelicolor, Streptomyces avermitilis, and Streptomyces ambofaciens ATCC23877 (whose partial sequence is released in this study), revealed a highly compartmentalized genetic organization of their genome. Indeed, despite the presence of specific genomic islands, the central part of the chromosome appears highly syntenic. In contrast, the chromosome of each species exhibits large species-specific terminal regions (from 753 to 1,393 kb), even when considering closely related species (S. ambofaciens and S. coelicolor). Interestingly, the size of the central conserved region between species decreases as the phylogenetic distance between them increases, whereas the specific terminal fraction reciprocally increases in size. Between highly syntenic central regions and species-specific chromosomal parts, there is a notable degeneration of synteny due to frequent insertions/deletions. This reveals a massive and constant genomic flux (from lateral gene transfer and DNA rearrangements) affecting the terminal contingency regions. We speculate that a gradient of recombination rate (i.e., insertion/deletion events) toward the extremities is the force driving the exclusion of essential genes from the terminal regions (i.e., chromosome compartmentalization) and generating a fast gene turnover for strong adaptation capabilities.     

Artificial circularization of the chromosome with concomitant deletion of its terminal inverted repeats enhances genetic instability and genome rearrangement in Streptomyces lividans

The unstable linear chromosome of Streptomyces lividans was circularized by homologous recombination and its terminal inverted repeats deleted. Strains with circularized chromosomes showed no obvious phenotypic disadvantages compared to the wild type. However, they segregated about 20 times more chloramphenicol-sensitive mutants than the wild type (24.3% vs. 1.4%), due to a higher incidence of large deletions. In addition, in all circularized chromosomes amplification of 30–60 kb fragments was observed at the new chromosomal junction, to levels of approximately 10 copies per chromosome. Arginine auxotrophs that arose spontaneously among the progeny of strains with a circularized chromosome showed high-copy-number amplification of the DNA element AUD1, as also seen in mutants of the wild type. These observations demonstrate that the circular form of the Streptomyces chromosome is more unstable than the linear one.     

The unstable region of Streptomyces ambofaciens includes 210 kb terminal inverted repeats flanking the extremities of the linear chromosomal DNA

Physical maps of the chromosomes of three strains of Streptomyces ambofaciens were constructed by ordering Ase I fragments generated from the genomic DNA as a single linear chromosome of about 8 Mb. The physical maps of the three strains were very similar. For strain DSM40697, a Dra I map was obtained by positioning the Dra I sites relative to the Ase I map. Eighteen genetic markers as well as the deletable and amplifiable region were assigned to the Ase I and Dra I fragments in this strain. The resulting genetic map resembled that of Streptomyces coelicolor A3(2). The twoterminal Ase I fragments exhibited retarded pulsed-field gel electrophoresis mobility, demonstrating that proteins are covalently bound at this position. A restriction map of this region was made using four additional endonucleases. Repeated sequences present at both ends of the chromosome were mapped as long terminal inverted repeats stretching over 210 kb. This corresponds to the longest terminal inverted repeats so far characterized. The deletable region of S. ambofaciens was localized at the chromosomal extremities.     

Influence of disruption of the recA gene on genetic instability and genome rearrangement in Streptomyces lividans.

Streptomyces lividans TK23 gives rise to chloramphenicol-sensitive (Cml(s)) mutants at a frequency of about 0.5%. This is due to the frequent occurrence of very large chromosomal deletions removing the corresponding chloramphenicol resistance gene. A mutant in which the recA gene has been disrupted (S. lividans FrecD3 [G. Muth, D. Frese, A. Kleber, and W. Wohlleben, personal communication]) segregated about 70 times more chloramphenicol-sensitive mutants than the parental strain. An enhancement of the deletion frequency was responsible for this mutator phenotype. The amplifiable locus AUD1 has a duplicated structure in some S. lividans strains and is frequently highly amplified in some mutants generated by genetic instability. The chromosomal AUD1 is not amplified in strain TK23 because of the lack of one duplication. Nevertheless, AUD1-derived amplifiable units presenting the typical duplicated organization amplified very well in TK23 when carried on a plasmid. No amplification of these units was observed in the recA mutant. The ability to amplify was restored when the wild-type recA gene was introduced into the plasmid carrying the amplifiable unit. These results suggest that the RecA protein plays a role in reducing the level of genetic instability and chromosomal deletions and show that the recA gene is necessary to achieve high-copy-number amplification of AUD1.     

High frequency conjugal transfer of tylosin genes and amplifiable DNA in Streptomyces fradiae

Summary Genes encoding enzymes for tylosin biosynthesis, genes involved in the expression of resistance to tylosin (Tyl), hygromycin B (Hm), chloramphenicol (Cm), and mitomycin C (MC), and a single copy of an amplifiable unit of DNA (AUD) were jointly transferred at very high frequencies by conjugation from several different Streptomyces fradiae strains to S. fradiae JS85, a mutant defective in many or possibly all tylosin biosynthetic reactions and containing a multiple tandem reiteration of the AUD. No recombination was observed between nar, rif and spc genes in conjugal matings, but recombination was observed between these genes after protoplast fusion. Tylosin biosynthetic genes were transferred at a much lower frequency to S. fradiae JS87, another mutant defective in many or all tylosin biosynthetic reactions, but deleted for the AUD and other DNA sequences. These findings suggest that tylosin structural genes, several genes encoding antibiotic resistance determinants, and amplifiable DNA are present on a self-transmissible element that does not mobilize chromosomal genes, and that JS85 and JS87 contain deletions, and JS85 an amplification, of overlapping portions of this element.     

Genetic instability inStreptomyces

Genetic instability is very common amongStreptomyces strains and the affected strains display several distinctive phenotypes. In several cases DNA rearrangements, specifically deletions and amplifications of specific segments of DNA, were demonstrated. Depending upon the reproducible amplification of a segment in independent isolates one could predict the basic structural elements involved in the amplification process. In the case ofS. lividans 66,5.7 kb amplifiable DNA sequence is located near the end of the linear chromosome. Amplification of this sequence and deletion of the chromosome linked to it leads to the creation of a new end or in some cases even circularisation of the chromosome occurs. A model incorporating these aspects is discussed. The possible involvement of proteins encoded by the amplifiable region is also discussed.     

Artificial circularization of the chromosome with concomitant deletion of its terminal inverted repeats enhances genetic instability and genome rearrangement in Streptomyces lividans

The unstable linear chromosome of Streptomyces lividans was circularized by homologous recombination and its terminal inverted repeats deleted. Strains with circularized chromosomes showed no obvious phenotypic disadvantages compared to the wild type. However, they segregated about 20 times more chloramphenicol-sensitive mutants than the wild type (24.3% vs. 1.4%), due to a higher incidence of large deletions. In addition, in all circularized chromosomes amplification of 30–60 kb fragments was observed at the new chromosomal junction, to levels of approximately 10 copies per chromosome. Arginine auxotrophs that arose spontaneously among the progeny of strains with a circularized chromosome showed high-copy-number amplification of the DNA element AUD1, as also seen in mutants of the wild type. These observations demonstrate that the circular form of the Streptomyces chromosome is more unstable than the linear one. Received: 28 July 1996 / Accepted: 18 November 1996     

Circularized chromosome with a large palindromic structure in Streptomyces griseus mutants

Streptomyces linear chromosomes display various types of rearrangements after telomere deletion, including circularization, arm replacement, and amplification. We analyzed the new chromosomal deletion mutants Streptomyces griseus 301-22-L and 301-22-M. In these mutants, chromosomal arm replacement resulted in long terminal inverted repeats (TIRs) at both ends; different sizes were deleted again and recombined inside the TIRs, resulting in a circular chromosome with an extremely large palindrome. Short palindromic sequences were found in parent strain 2247, and these sequences might have played a role in the formation of this unique structure. Dynamic structural changes of Streptomyces linear chromosomes shown by this and previous studies revealed extraordinary strategies of members of this genus to keep a functional chromosome, even if it is linear or circular.     

Amplified DNA in Streptomyces fradiae.

A spontaneous mutant of Streptomyces fradiae contained an amplifiable unit of DNA with a sequence length of approximately 10.5 kilobases that was amplified to approximately 500 copies per chromosome. The amplified DNA appears to be cryptic. SalI fragments of the amplified DNA were cloned into Escherichia coli to construct a restriction map and characterize the amplified DNA. The amplified DNA contained tandem repeats of the amplifiable unit of DNA. The unit had an average base composition of 71% guanine plus cytosine, similar to the chromosomal DNA of Streptomyces species. At least a portion of the amplifiable unit of DNA was present at a low copy number in the wild-type strain. The phenotype of amplified DNA was designated Ads1SF for amplified DNA sequence 1 in S. fradiae.     

Relationship of an unstable argG gene to a 5.7-kilobase amplifiable DNA sequence in Streptomyces lividans 66.

The relationship between an unstable argG gene and a 5.7-kilobase (kb) amplifiable DNA sequence in Streptomyces lividans 66 was investigated. Spontaneous, high-frequency Arg mutants deleted for this gene typically contain 200 to 300 copies of the tandemly reiterated sequence. A library of S. lividans 66 (strain 1326) wild-type genomic DNA was prepared in the vector lambda Charon 35. Chromosome walking over 44 kb established that argG is located 25 kb distant from a duplicated amplifiable DNA structure. A sequence was characterized, located farther distal from the amplifiable structure, containing strong homology with an internal sequence of the amplifiable DNA, which may have a role in the deletion of argG. Genetic mapping showed that argG and the 5.7-kb amplifiable sequence are linked to another unstable gene, determining chloramphenicol resistance (Camr) and that together these genes may be located in a silent chromosomal arc.     

Analysis of putative DNA amplification genes in the element AUD1 of Streptomyces lividans 66

The amplifiable AUD1 element of Streptomyces lividans 66 consists of two copies of a 4.7 kb sequence flanked by three copies of a 1 kb sequence. The DNA sequences of the three 1 kb repeats were determined. Two copies (left and middle repeats) were identical: (1009 by in length) and the right repeat was 1012 bp long and differed at 63 positions. The repeats code for open reading frames (ORFs) with typical Streptomyces codon usage, which would encode proteins of about 36 kD molecular weight. The sequences of these ORFs suggest that they specify DNA-binding proteins and potential palindromic binding sites are found adjacent to the genes. The putative amplification protein encoded by the right repeat was expressed in Escherichia coli.     

Analysis of putative DNA amplification genes in the element AUD1 of Streptomyces lividans 66

The amplifiable AUD1 element of Streptomyces lividans 66 consists of two copies of a 4.7 kb sequence flanked by three copies of a 1 kb sequence. The DNA sequences of the three 1 kb repeats were determined. Two copies (left and middle repeats) were identical: (1009 by in length) and the right repeat was 1012 bp long and differed at 63 positions. The repeats code for open reading frames (ORFs) with typical Streptomyces codon usage, which would encode proteins of about 36 kD molecular weight. The sequences of these ORFs suggest that they specify DNA-binding proteins and potential palindromic binding sites are found adjacent to the genes. The putative amplification protein encoded by the right repeat was expressed in Escherichia coli.     

Intraspecific variability of the terminal inverted repeats of the linear chromosome of Streptomyces ambofaciens

The sequences of the terminal inverted repeats (TIRs) ending the linear chromosomal DNA of two Streptomyces ambofaciens strains, ATCC23877 and DSM40697 (198 kb and 213 kb, respectively), were determined from two sets of recombinant cosmids. Among the 215 coding DNA sequences (CDSs) predicted in the TIRs of strain DSM40697, 65 are absent in the TIRs of strain ATCC23877. Reciprocally, 45 of the 194 predicted CDSs are specific to the ATCC23877 strain. The strain-specific CDSs are located mainly at the terminal end of the TIRs. Indeed, although TIRs appear almost identical over 150 kb (99% nucleotide identity), large regions of DNA of 60 kb (DSM40697) and 48 kb (ATCC23877), mostly spanning the ends of the chromosome, are strain specific. These regions are rich in plasmid-associated genes, including genes encoding putative conjugal transfer functions. The strain-specific regions also share a G+C content (68%) lower than that of the rest of the genome (from 71% to 73%), a percentage that is more typical of Streptomyces plasmids and mobile elements. These data suggest that exchanges of replicon extremities have occurred, thereby contributing to the terminal variability observed at the intraspecific level. In addition, the terminal regions include many mobile genetic element-related genes, pseudogenes, and genes related to adaptation. The results give insight into the mechanisms of evolution of the TIRs: integration of new information and/or loss of DNA fragments and subsequent homogenization of the two chromosomal extremities.