Physical map of the linear chromosome of Streptomyces griseus

Recombineering linear BACs

Recombineering is a powerful genetic engineering technique based on homologous recombination that can be used to accurately modify DNA independent of its sequence or size. One novel application of recombineering is the assembly of linear BACs in E. coli that can replicate autonomously as linear plasmids. A circular BAC is inserted with a short telomeric sequence from phage N15, which is subsequently cut and rejoined by the phage protelomerase enzyme to generate a linear BAC with terminal hairpin telomeres. Telomere-capped linear BACs are protected against exonuclease attack both in vitro and in vivo in E. coli cells and can replicate stably. Here we describe step-by-step protocols to linearize any BAC clone by recombineering, including inserting and screening for presence of the N15 telomeric sequence, linearizing BACs in vivo in E. coli, extracting linear BACs, and verifying the presence of hairpin telomere structures. Linear BACs may be useful for functional expression of genomic loci in cells, maintenance of linear viral genomes in their natural conformation, and for constructing innovative artificial chromosome structures for applications in mammalian and plant cells.

Chromosomal circularization of the model Streptomyces species, Streptomyces coelicolor A3(2)

Streptomyces linear chromosomes frequently cause deletions at both ends spontaneously or by various mutagenic treatments, leading to chromosomal circularization and arm replacement. However, chromosomal circularization has not been confirmed at a sequence level in the model species, Streptomyces coelicolor A3(2). In this work, we have cloned and sequenced a fusion junction of a circularized chromosome in an S. coelicolor A3(2) mutant and found a 6-bp overlap between the left and right deletion ends. This result shows that chromosomal circularization occurred by nonhomologous recombination of the deletion ends in this species, too. At the end of the study, we discuss on stability and evolution of Streptomyces chromosomes.

A large inversion in the linear chromosome of Streptomyces griseus caused by replicative transposition of a new Tn3 family transposon

We have comprehensively analyzed the linear chromosomes of Streptomyces griseus mutants constructed and kept in our laboratory. During this study, macrorestriction analysis of AseI and DraI fragments of mutant 402-2 suggested a large chromosomal inversion. The junctions of chromosomal inversion were cloned and sequenced and compared with the corresponding target sequences in the parent strain 2247. Consequently, a transposon-involved mechanism was revealed. Namely, a transposon originally located at the left target site was replicatively transposed to the right target site in an inverted direction, which generated a second copy and at the same time caused a 2.5-Mb chromosomal inversion. The involved transposon named TnSGR was grouped into a new subfamily of the resolvase-encoding Tn3 family transposons based on its gene organization. At the end, terminal diversity of S. griseus chromosomes is discussed by comparing the sequences of strains 2247 and IFO13350.

Genome sequence of the streptomycin-producing microorganism Streptomyces griseus IFO 13350

We determined the complete genome sequence of Streptomyces griseus IFO 13350, a soil bacterium producing an antituberculosis agent, streptomycin, which is the first aminoglycoside antibiotic, discovered more than 60 years ago. The linear chromosome consists of 8,545,929 base pairs (bp), with an average G+C content of 72.2%, predicting 7,138 open reading frames, six rRNA operons (16S-23S-5S), and 66 tRNA genes. It contains extremely long terminal inverted repeats (TIRs) of 132,910 bp each. The telomere's nucleotide sequence and secondary structure, consisting of several palindromes with a loop sequence of 5'-GGA-3', are different from those of typical telomeres conserved among other Streptomyces species. In accordance with the difference, the chromosome has pseudogenes for a conserved terminal protein (Tpg) and a telomere-associated protein (Tap), and a novel pair of Tpg and Tap proteins is instead encoded by the TIRs. Comparisons with the genomes of two related species, Streptomyces coelicolor A3(2) and Streptomyces avermitilis, clarified not only the characteristics of the S. griseus genome but also the existence of 24 Streptomyces-specific proteins. The S. griseus genome contains 34 gene clusters or genes for the biosynthesis of known or unknown secondary metabolites. Transcriptome analysis using a DNA microarray showed that at least four of these clusters, in addition to the streptomycin biosynthesis gene cluster, were activated directly or indirectly by AdpA, which is a central transcriptional activator for secondary metabolism and morphogenesis in the A-factor (a gamma-butyrolactone signaling molecule) regulatory cascade in S. griseus.

Genetic Characterization and Diversity of Rathayibacter toxicus

ABSTRACT Rathayibacter toxicus is a nematode-vectored gram-positive bacterium responsible for a gumming disease of grasses and production of a highly potent animal and human toxin that is often fatal to livestock and has a history of occurring in unexpected circumstances. DNA of 22 strains of R. toxicus from Australia were characterized using amplified fragment length polymorphism (AFLP) and pulsed-field gel electrophoresis (PFGE). AFLP analysis grouped the 22 strains into three genetic clusters that correspond to their geographic origin. The mean similarity between the three clusters was 85 to 86%. PFGE analysis generated three different banding patterns that enabled typing the strains into three genotypic groups corresponding to the same AFLP clusters. The similarity coefficient was 63 to 81% for XbaI and 79 to 84% for SpeI. AFLP and PFGE analyses exhibited an analogous level of discriminatory power and produced congruent results. PFGE analysis indicated that the R. toxicus genome was represented by a single linear chromosome, estimated to be 2.214 to 2.301 Mb. No plasmids were detected.

Genetics of Streptomyces rimosus, the oxytetracycline producer

From a genetic standpoint, Streptomyces rimosus is arguably the best-characterized industrial streptomycete as the producer of oxytetracycline and other tetracycline antibiotics. Although resistance to these antibiotics has reduced their clinical use in recent years, tetracyclines have an increasing role in the treatment of emerging infections and noninfective diseases. Procedures for in vivo and in vitro genetic manipulations in S. rimosus have been developed since the 1950s and applied to study the genetic instability of S. rimosus strains and for the molecular cloning and characterization of genes involved in oxytetracycline biosynthesis. Recent advances in the methodology of genome sequencing bring the realistic prospect of obtaining the genome sequence of S. rimosus in the near term.

Prediction and functional analysis of the replication origin of the linear plasmid pSCL2 inStreptomyces clavuligerus

pSCL2 (120 kb), one of the linear plasmids found in Streptomyces clavuligerus NRRL3585, was isolated and partially sequenced. Computational analysis of the central region of pSCL2 revealed the presence of two open reading frames that appear to encode proteins highly homologous to RepL1 and RepL2, replication proteins from pSLA2-L, the large linear plasmid in Streptomyces rochei. The S. clavuligerus open reading frames were designated repC1 and repC2, encoding the proteins RepC1 (150 amino acids) and RepC2 (102 amino acids), respectively. The RepC and RepL proteins have identical translation features and very similar predicted secondary and tertiary structures. Functional analysis confirmed that RepC1 is essential for replication initiation of pSCL2, whereas RepC2 is dispensable but may play a role in copy number control. The RepC and RepL proteins do not show similarity to any other bacterial plasmid replication proteins. Three regions of DNA sequence, Box 1 (1050–850 bp), Box 2 (723–606 bp), and Box 3 (224–168 bp), located upstream of repC1, were also shown to be essential or very important for replication of pSCL2.Key words: pSCL2, Streptomyces clavuligerus, replication origin.

Characterisation of a highly stable alpha-amylase from the halophilic archaeon Haloarcula hispanica

Intracellular and extracellular proteins from halophilic archaea face very saline conditions and must be able to maintain stability and functionality at nearly saturated salt concentrations. Haloarchaeal proteins contain specific adaptations to prevent aggregation and loss of activity in such conditions, but these adaptations usually result in a lack of stability in the absence of salt. Here, we present the characterisation of a secreted alpha-amylase (AmyH) from the halophilic archaeon Haloarcula hispanica. AmyH was shown to be very halophilic but, unusually for a halophilic protein, it retained activity in the absence of salt. Intrinsic fluorescence measurements and activity assays showed that AmyH was very stable in high-salt buffer and even maintained stability upon the addition of urea. Urea-induced denaturation was only achieved in the absence of NaCl, demonstrating clearly that the stability of the protein was salt-dependent. Sequencing of the amyH gene showed an amino acid composition typical of halophilic proteins and, moreover, the presence of a signal peptide containing diagnostic features characteristic of export via the Twin-arginine translocase (Tat). Analysis of the export of AmyH showed that it was translocated post-translationally, most likely in a folded and active conformation, confirming that AmyH is a substrate of the Tat pathway.

Construction of a combined physical and genetic map of the chromosome of Lactobacillus acidophilus ATCC 4356 and characterization of the rRNA operons

The combination of PFGE and hybridization approaches was used to study the genome of Lactobacillus acidophilus neotype strain ATCC 4356. PFGE analysis of chromosomal DNA after digestion with each of the rare-cutting restriction enzymes I-CeuI, NotI, CspI, SmaI, ApaI and SgrAI allowed the size of the circular chromosome of L. acidophilus to be estimated at 2.061 Mbp. The physical map contained 86 restriction sites for the six enzymes employed, with intervals between the sites varying from 1 to 88 kbp (approximately 0.05-4.3 % of the chromosome). Based on the physical map, a genetic map was constructed via Southern blot analyses of L. acidophilus DNA using specific gene probes. A total of 73 probes representing key genes, including 12 rRNA (rrn) genes, were positioned on the latter map. Mapping analysis also indicated the presence of four rrn operons (rrnA-D) on the chromosome, each containing a single copy of each of the three rrn genes 16S (rrl), 23S (rrs) and 5S (rrf). Operon rrnD was inverted in orientation with respect to the others and contained a long 16S-23S intergenic spacer region with tRNAIle and tRNAAla genes, whereas the other operons contained a short spacer lacking any tRNA genes. The high-resolution physical/genetic map constructed in this study provides a platform for genomic and genetic studies of Lactobacillus species and for improving industrial and probiotic strains.

Two chimeric chromosomes of Streptomyces coelicolor A3(2) generated by single crossover of the wild-type chromosome and linear plasmid scp1

Streptomyces coelicolor A3(2) strain 2106 carries a 1.85-Mb linear plasmid, SCP1'-cysD, in addition to a 7.2-Mb linear chromosome. Macrorestriction analysis indicated that both linear DNAs are hybrids of the wild-type chromosome and the linear plasmid SCP1 on each side. Nucleotide sequencing of the fusion junctions revealed no homology between the recombination regions. SCP1'-cysD contains an SCP1 telomere and a chromosomal telomere at each end and therefore does not have terminal inverted repeats. In addition, SCP1'-cysD could not be eliminated from strain 2106 by various mutagenic treatments. Thus, we concluded that both the 7.2-Mb chromosome and SCP1'-cysD are chimeric chromosomes generated by a single crossover of the wild-type chromosome and SCP1. This may be regarded as a model of chromosomal duplication in genome evolution.

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.

Characterization of the Streptomyces lavendulae IMRU 3455 linear plasmid pSLV45

Streptomyces lavendulae IMRU 3455 contains two large linear plasmids designated pSLV45 (45 kb) and pSLV195 (195 kb). A cosmid, pSPRX604, containing 42 kb from pSLV45 was cloned and sequenced. pSLV45 was tagged with a hygromycin-resistance marker by homologous recombination to generate the derivatives pSLV45.680 and pSLV45.681. An apramycin-resistance marker was introduced into S. lavendulae IMRU 467 using the pSPR910 integration vector to yield the recipient strain SPW910. The self-transmissible nature of pSLV45 was determined by transfer of pSLV45.680 and pSLV45.681 from the donor strains SPW680 and SPW681 into the recipient strain SPW910. Southern analysis indicated the presence of hygromycin- and pSLV45-hybridizing sequences within SPW910 exconjugants. PFGE analysis confirmed pSLV45.680 and pSLV45.681 were transferred intact and formed freely replicating linear plasmids. Sequence analysis of pSPRX604 revealed genes predicted to be involved in plasmid transfer, partitioning and regulation. The transfer of the linear plasmid pSLV45 from S. lavendulae IMRU 3455 into S. lavendulae IMRU 467 may allow the development of pSLV45 as an actinomycete-to-actinomycete conjugative shuttle vector.

Streptomyces genetics: a genomic perspective

Streptomycetes are gram-positive, soil-inhabiting bacteria of the order Actinomycetales. These organisms exhibit an unusual, developmentally complex life cycle and produce many economically important secondary metabolites, such as antibiotics, immunosuppressants, insecticides, and anti-tumor agents. Streptomyces species have been the subject of genetic investigation for over 50 years, with many studies focusing on the developmental cycle and the production of secondary metabolites. This information provides a solid foundation for the application of structural and functional genomics to the actinomycetes. The complete DNA sequence of the model organism, Streptomyces coelicolor M145, has been published recently, with others expected to follow soon. As more genomic sequences become available, the rational genetic manipulation of these organisms to elucidate metabolic and regulatory networks, to increase the production of commercially important compounds, and to create novel secondary metabolites will be greatly facilitated. This review presents the current state of the field of genomics as it is being applied to the actinomycetes.

Limited regions of homology between linear and circular plasmids encoding methylenomycin biosynthesis in two independently isolated streptomycetes

pSV1 is a plasmid in Streptomyces violaceoruber SANK95570 that carries the methylenomycin biosynthetic (mmy) gene cluster. An ordered cosmid map and an EcoRI map have been constructed for pSV1, confirming that pSV1 is a 163 kb circular plasmid. The mmy gene cluster has been found on three different replicon structures; the circular plasmid pSV1, the 356 kb linear plasmid SCP1 and, via SCP1 integration, the linear chromosome of Streptomyces coelicolor A3(2). Comparison of pSV1 and SCP1 sequences revealed that the two plasmids have homology to each other only around the mmy and parAB regions, eliminating models in which pSV1 was generated by circularization of SCP1 or vice versa. It is likely that the mmy gene cluster was horizontally transferred as a set together with the parAB region in the comparatively recent evolutionary past.

Chromosomal arm replacement in Streptomyces griseus

UV irradiation of Streptomyces griseus 2247 yielded a new chromosomal deletion mutant, MM9. Restriction and sequencing analysis revealed that homologous recombination between two similar lipoprotein-like open reading frames, which are located 450 and 250 kb from the left and right ends, respectively, caused chromosomal arm replacement. As a result, new 450-kb terminal inverted repeats (TIRs) were formed in place of the original 24-kb TIRs. Frequent homologous recombinations in Streptomyces strains suggest that telomere deletions can usually be repaired by recombinational DNA repair functioning between the intact and deleted TIR sequences on the same chromosome.

Once the circle has been broken: dynamics and evolution of Streptomyces chromosomes

Chromosomal instability has been a hallmark of Streptomyces genetics. Deletions and circularization often occur in the less-conserved terminal sequences of the linear chromosomes, which contain swarms of transposable elements and other horizontally transferred elements. Intermolecular recombination involving these regions also generates gross exchanges, resulting in terminal inverted repeats of heterogeneous size and context. The structural instability is evidently related to evolution of the Streptomyces chromosomes, which is postulated to involve linearization of hypothetical circular progenitors via integration of a linear plasmid. This scenario is supported by several bioinformatic analyses.

Survival mechanisms for Streptomyces linear replicons after telomere damage

The ability of linear replicons to propagate their DNA after telomere damage is essential for perpetuation of the genetic information they carry. We introduced deletions at specific locations within telomeres of streptomycete linear plasmids and investigated mechanisms that enable survival. Here, we report that rescue of such plasmids in Streptomyces lividans occurs by three distinct types of events: (i) repair of the damaged telomere by homologous recombination; (ii) circularization of the plasmid by non-homologous end-to-end joining; and (iii) formation of long palindromic linear plasmids that duplicate the intact telomere by a non-recombinational process. The relative frequency of use of these survival mechanisms depended on the location and length of the telomeric DNA deletion. Repair by intermolecular recombination between the telomeres of chromosomes and plasmids, deletion of additional DNA during plasmid circularization, and insertion of chromosomal DNA fragments into plasmids during end-to-end joining were observed. Our results show that damage to telomeres of Streptomyces linear replicons can promote major structural transformations in these replicons as well as genetic exchange between chromosomes and extrachromosomal DNA. Our findings also suggest that spontaneous circularization of linear Streptomyces chromosomes may be a biological response to instances of telomere damage that cannot be repaired by homologous recombination.

Cloning and analysis of the telomere and terminal inverted repeat of the linear chromosome of Streptomyces griseus

Cloning and sequencing of the telomere of Streptomyces griseus revealed five palindromic sequences in the terminal 116 nucleotides, all of which can make a hairpin loop structure. However, the end sequence cannot form the foldback secondary structure that is common in Streptomyces telomeres and is suggested to be necessary for terminal replication. Both inside ends of the terminal inverted repeat (TIR) were also cloned and sequenced. The results confirmed the size of the TIR to be 24 kb and identified two almost identical open reading frames that might have been involved in the formation of the TIR.

Physical map of the linear chromosome of Streptomyces hygroscopicus 10-22 deduced by analysis of overlapping large chromosomal deletions

The chromosomal DNA of Streptomyces hygroscopicus 10-22, a derivative of strain 5102-6, was digested with several restriction endonucleases and analyzed by pulsed-field gel electrophoresis (PFGE). Digestions with AseI gave 11 fragments with a total length of ca. 7.36 Mb. The AseI sites were mapped by analysis of overlapping chromosomal deletions in different mutants and confirmed by Southern hybridizations using partially digested genome fragments and linking cosmids as probes. PFGE analysis of DNA with and without proteinase K treatment, together with the hybridization results, suggested a linear organization with terminal proteins and large terminal inverted repeats. Some deletion mutants had circular chromosomes.

Mapping of genes encoding glycoside hydrolases on the chromosome of Cellulomonas fimi

Cellulomonas fimi genomic DNA was digested with HpaI, MunI, HindIII, and NsiI, producing fragments ranging in size from 20 to 1400 kbp that were resolved by pulsed field gel electrophoresis. Genetic and physical linkages were determined by Southern blotting and were used to construct a genome map. Cellulomonas fimi has a single circular chromosome of approx. 4000 kbp. Except for two closely linked genes, cbh6A and cel5A, the genes known to encode glycoside hydrolases are scattered widely on the chromosome.Key words: Cellulomonas fimi, genome map, pulsed field gel electrophoresis, glycoside hydrolases.

Genome sequence of an industrial microorganism Streptomyces avermitilis: deducing the ability of producing secondary metabolites

Streptomyces avermitilis is a soil bacterium that carries out not only a complex morphological differentiation but also the production of secondary metabolites, one of which, avermectin, is commercially important in human and veterinary medicine. The major interest in this genus Streptomyces is the diversity of its production of secondary metabolites as an industrial microorganism. A major factor in its prominence as a producer of the variety of secondary metabolites is its possession of several metabolic pathways for biosynthesis. Here we report sequence analysis of S. avermitilis, covering 99% of its genome. At least 8.7 million base pairs exist in the linear chromosome; this is the largest bacterial genome sequence, and it provides insights into the intrinsic diversity of the production of the secondary metabolites of Streptomyces. Twenty-five kinds of secondary metabolite gene clusters were found in the genome of S. avermitilis. Four of them are concerned with the biosyntheses of melanin pigments, in which two clusters encode tyrosinase and its cofactor, another two encode an ochronotic pigment derived from homogentiginic acid, and another polyketide-derived melanin. The gene clusters for carotenoid and siderophore biosyntheses are composed of seven and five genes, respectively. There are eight kinds of gene clusters for type-I polyketide compound biosyntheses, and two clusters are involved in the biosyntheses of type-II polyketide-derived compounds. Furthermore, a polyketide synthase that resembles phloroglucinol synthase was detected. Eight clusters are involved in the biosyntheses of peptide compounds that are synthesized by nonribosomal peptide synthetases. These secondary metabolite clusters are widely located in the genome but half of them are near both ends of the genome. The total length of these clusters occupies about 6.4% of the genome.

Identification of DNA amplifications near the center of the Streptomyces coelicolor M145 chromosome

Linear streptomycete chromosomes frequently undergo spontaneous gross DNA rearrangements at the terminal regions. Large DNA deletions of the chromosome ends are in many cases associated with tandemly reiterated DNA amplifications, found at the border of the deletable areas. In contrast to previous reports, we have discovered amplifications near the center of the Streptomyces coelicolor M145 chromosome. The detected amplified units of DNA are 19.9 kb and 16 kb in length and exist in copy numbers of 30 and 40, respectively. Both amplifications were located in the same region and share at least 3.6 kb.

Identification of two polyketide synthase gene clusters on the linear plasmid pSLA2-L in Streptomyces rochei

The 200kb linear plasmid pSLA2-L was suggested to be involved in the production of two macrolide antibiotics, lankamycin (Lm) and lankacidin (Lc), in Streptomyces rochei 7434AN4. Hybridization experiments with the polyketide synthase (PKS) genes for erythromycin and actinorhodin identified two eryAI-homologous regions and an actI-homologous region on pSLA2-L. The nucleotide sequence of a 3.6kb SacI fragment carrying one of the eryAI-homologs revealed that it codes for part of a large protein with four domains for ketoreductase, acyl carrier protein, ketosynthase, and acyltransferase. Gene disruption confirmed that the two eryAI-homologs are parts of a large type-I PKS gene cluster for Lm. A 4.8kb DNA carrying the actI-homologous region contains four open reading frames (ORF1-ORF4) as well as an additional ORF, i.e. ORF5, which might code for a thioesterase. Deletion of the ORF2-ORF4 region showed that it is not involved in the synthesis of Lm or Lc. Thus, it was confirmed that pSLA2-L contains two PKS gene clusters for Lm and an unknown type-II polyketide.

The homologous terminal sequence of the Streptomyces lividans chromosome and SLP2 plasmid

The chromosome of Streptomyces lividans shares 15.4 kb homology with one end of the linear plasmid SLP2, consisting of a 10.1 kb terminal sequence followed by the 5.3 kb transposable element Tn4811. The 10.1 kb terminal sequence was determined. The mean G+C content of this sequence is 67.9 mol% with a striking G vs C bias in the last kb. The terminal 232 nt contained 10 palindromic sequences with potential to form complex secondary structures. One typical Streptomyces coding sequence (designated ORF1) of 2643 bp was predicted in the determined sequence. The amino acid sequence of the ORF1 product contained a DEAH helicase motif, and exhibited similarity to type I restriction enzyme HsdR subunits in the database, suggesting a possible role in replication of the telomeres. However, all the ORF1 sequences on the chromosome and SLP2 could be simultaneously knocked out by targeted recombination without affecting the viability of the cells and the linearity of the chromosome and SLP2. This ruled out ORF1 as an essential component in the maintenance of the linear chromosome and plasmids.

Cluster organization of the genes of Streptomyces pristinaespiralis involved in pristinamycin biosynthesis and resistance elucidated by pulsed-field gel electrophoresis

Streptomyces pristinaespiralis synthesizes pristinamycin, a member of the streptogramin antibiotic family which consists of a mixture of two types of chemically unrelated compounds named pristinamycins I and pristinamycins II. In order to estimate the size of the Strep. pristinaespiralis chromosome and to elucidate the organization of the pristinamycin biosynthetic and resistance genes already identified, it was decided to use the pulsed-field gel electrophoresis technique. Results indicate that the Strep. pristinaespiralis chromosome is linear and about 7580 kb, as previously shown for several other Streptomyces species. By hybridization, it could be shown that the biosynthetic and resistance genes for pristinamycins I and pristinamycins II, except for the multidrug resistance gene ptr, are interspersed and seem to be organized as a single large cluster, covering less than 200 kb corresponding to 2.6% of the total size of the chromosome. The consequences and significance of such a genetic organization are discussed.

The linear plasmid SCP1 of Streptomyces coelicolor A3(2) possesses a centrally located replication origin and shows significant homology to the transposon Tn4811

The linear plasmid SCP1 of Streptomyces coelicolor A3(2) is one of the genetically more studied linear streptomycete replicons. Although the genetics of SCP1 and its interaction with the host chromosome have been analyzed for nearly three decades no information exists on its replication. With the help of an ordered cosmid contig for the complete 360-kb element, we have localized a 5439-bp fragment from the central region that confers autonomous replication in Streptomyces lividans. The minimal origin contains two overlapping ORFs which are separated from an AT-rich region which might correspond to the replication start point. ORF1 revealed intensive similarity to a class of DNA-primase/helicases of actinophages and archael plasmids. In addition, we have identified a region in both terminal inverted repeats of SCP1 that shows significant homology to the transposable element Tn4811 located near the ends of the S. lividans 66 chromosome.

Analysis of fusion junctions of circularized chromosomes in Streptomyces griseus

A filamentous soil bacterium, Streptomyces griseus 2247, carries a 7. 8-Mb linear chromosome. We previously showed by macrorestriction analysis that mutagenic treatments easily caused deletions at both ends of its linear chromosome and changed the chromosome to a circular form. In this study, we confirmed chromosomal circularization by cloning and sequencing the junction fragments from two deletion mutants, 404-23 and N2. The junction sequences were compared with the corresponding right and left deletion end sequences in the parent strain, 2247. No homology and a 6-bp microhomology were found between the two deletion ends of the 404-23 and N2 mutants, respectively, which indicate that the chromosomal circularization was caused by illegitimate recombination without concomitant amplification. The circularized chromosomes were stably maintained in both mutants. Therefore, the chromosomal circularization might have occurred to prevent lethal deletions, which otherwise would progress into the indispensable central regions of the chromosome.

Streptomyces genomes: circular genetic maps from the linear chromosomes

Streptomyces chromosomes are linear DNA molecules and yet their genetic maps based on linkage analysis are circular. The only other known examples of this phenomenon are in the bacteriophages T2 and T4, the linear genomic sequences of which are circularly permuted and terminally redundant, and in which replication intermediates include long concatemers. These structural and functional features are not found in Streptomyces. Instead, the circularity of Streptomyces genetic maps appears to be caused by a completely different mechanism postulated by Stahl & Steinberg (1964, Genetics 50, 531-538)--a strong bias toward even numbers of crossovers during recombination creates misleading genetic linkages between markers on the opposite arms of the chromosome. This was demonstrated by physical inspection of the telomeres in recombinant chromosomes after interspecies conjugation promoted by a linear or circular plasmid. The preference for even numbers of crossovers is probably demanded by the merozygosity of the recombining chromosomes, and by the association between the telomeres mediated by interactions of covalently bound terminal proteins.

The diverse and dynamic structure of bacterial genomes

Bacterial genome sizes, which range from 500 to 10,000 kbp, are within the current scope of operation of large-scale nucleotide sequence determination facilities. To date, 8 complete bacterial genomes have been sequenced, and at least 40 more will be completed in the near future. Such projects give wonderfully detailed information concerning the structure of the organism's genes and the overall organization of the sequenced genomes. It will be very important to put this incredible wealth of detail into a larger biological picture: How does this information apply to the genomes of related genera, related species, or even other individuals from the same species? Recent advances in pulsed-field gel electrophoretic technology have facilitated the construction of complete and accurate physical maps of bacterial chromosomes, and the many maps constructed in the past decade have revealed unexpected and substantial differences in genome size and organization even among closely related bacteria. This review focuses on this recently appreciated plasticity in structure of bacterial genomes, and diversity in genome size, replicon geometry, and chromosome number are discussed at inter- and intraspecies levels.

Chromosomal arm replacement generates a high level of intraspecific polymorphism in the terminal inverted repeats of the linear chromosomal DNA of Streptomyces ambofaciens

The chromosomal DNA of the bacteria Streptomyces ambofaciens DSM40697 is an 8-Mb linear molecule that ends in terminal inverted repeats (TIRs) of 210 kb. The sequences of the TIRs are highly variable between the different linear replicons of Streptomyces (plasmids or chromosomes). Two spontaneous mutant strains harboring TIRs of 480 and 850 kb were isolated. The TIR polymorphism seen is a result of the deletion of one chromosomal end and its replacement by 480 or 850 kb of sequence identical to the end of the undeleted chromosomal arm. Analysis of the wild-type sequences involved in these rearrangements revealed that a recombination event took place between the two copies of a duplicated DNA sequence. Each copy was mapped to one chromosomal arm, outside of the TIR, and encoded a putative alternative sigma factor. The two ORFs, designated hasR and hasL, were found to be 99% similar at the nucleotide level. The sequence of the chimeric regions generated by the recombination showed that the chromosomal structure of the mutant strains resulted from homologous recombination events between the two copies. We suggest that this mechanism of chromosomal arm replacement contributes to the rapid evolutionary diversification of the sequences of the TIR in Streptomyces.

Identification of two linear plasmids in the actinomycete Planobispora rosea

Two linear plasmids (pPR1, 27.5 kb, and pPR2, 16 kb) were identified in Planobispora rosea, an actinomycete that produces the antibiotic GE2270, an inhibitor of the elongation factor Tu. Strains lacking both plasmids still produce and are resistant to GE2270. The two plasmids share an internal region of high similarity, but no cross-hybridization was detected between their telomeric regions or between plasmid and chromosomal DNA. The 5' ends of the plasmids appear to be linked to terminal proteins. The telomeric regions of pPR2 were cloned after 3'-end homopolymer tailing and PCR amplification. The approximately 650 nt telomeric DNA sequences of pPR2 are repeated in inverted orientation and are rich in direct and inverted repeats; the 350 bp terminal region is less G + C-rich than the rest of the plasmid. The structural organization of these plasmids appears to be similar to Streptomyces linear replicons.

Physical-genetic map of the erythromycin-producing organism Saccharopolyspora erythraea

A physical map of the chromosome of the erythromycin-producing actinomycete Saccharopolyspora erythraea NRRL 2338 has been constructed using the restriction enzymes AseI and DraI. The map was constructed by a variety of methods including linking clone analysis, cross-hybridizations using labelled macrorestriction fragments, gene probing, two-dimensional PFGE and restriction enzyme site generation. Analysis of the individual macrorestriction patterns of the 17 AseI-, 6 DraI- and 22 AseI/DraI-digested fragments indicated a chromosome size of about 8 Mb. Linking clones for five contiguous AseI fragments were obtained, covering 32% of the chromosome. The linkage of an additional eight AseI fragments was aided by the finding that the rRNA operons of S. erythraea contain an AseI site within the 16S (rrs) gene. Generation of S. erythraea strains that contain additional DraI sites within selected AseI fragments, followed by PFGE analysis and Southern hybridization to determine specific linkages, facilitated the completion of the AseI map. The entire DraI map was constructed by gene probing and cross-hybridizations. PFGE analysis of agarose-embedded DNA prepared in either the presence or absence of proteinase K suggested that the S. erythraea NRRL 2338 chromosome is linear. A total of 15 genes or gene clusters were mapped to specific AseI and DraI fragments, including the erythromycin-biosynthetic gene cluster and the rRNA operons.

Recombination between the linear plasmid pPZG101 and the linear chromosome of Streptomyces rimosus can lead to exchange of ends

The 387kb linear plasmid pPZG101 of Streptomyces rimosus R6 can integrate into the chromosome or form a prime plasmid carrying the oxytetracycline biosynthesis cluster. The integration of plasmid pPZG101 into the linear chromosome of S. rimosus R6-501 in mutant MV25 was shown to be due to a single cross-over at a 4 bp common sequence. pPZG101 had integrated into a 250 kb DNA sequence that was reiterated at a low level. This sequence includes the oxytetracycline biosynthesis cluster, so that homologous recombination generated a mixed population carrying different copy numbers of the region. The 1 Mb linear plasmid pPZG103 in mutant MV17 had also arisen from a cross-over between pPZG101 and the chromosome, so that one end of pPZG103 consists of c. 850 kb of chromosomal sequence including the oxytetracycline biosynthesis cluster. The plasmid pPZG101 was shown to consist of a unique central region of about 30 kb flanked by terminal inverted repeats of about 180 kb. Analysis of a presumed ancestor plasmid pPZG102 suggested that the long terminal repeats had arisen by a recombination event during the strain development programme.

The telomeres of Streptomyces chromosomes contain conserved palindromic sequences with potential to form complex secondary structures

The chromosomes of the gram-positive soil bacteria Streptomyces are linear DNA molecules, usually of about 8Mb, containing a centrally located origin of replication and covalently bound terminal proteins (which are presumably involved in the completion of replication of the telomeres). The ends of the chromosomes contain inverted repeats of variable lengths. The terminal segments of five Streptomyces chromosomes and plasmids were cloned and sequenced. The sequences showed a high degree of conservation in the first 166-168bp. Beyond the terminal homology, the sequences diverged and did not generally cross-hybridize. The homologous regions contained seven palindromes with a few nucleotide differences. Many of these differences occur in complementary pairs, such that the palindromicity is preserved. Energy-optimized modelling predicted that the 3' strand of the terminal palindromes can form extensive hairpin structures that are similar to the 3' ends of autonomous parvovirus genomes. Most of the putative hairpins have a GCGCAGC sequence at the loop, with the potential to form a stable single C-residue loop closed by a sheared G:A pairing. The similarity between the terminal structures of the Streptomyces replicons and the autonomous parvoviral genomes suggests that they may share some structural and/or replication features.

The terminal structures of linear plasmids from Rhodococcus opacus

The telomers of several linear plasmids of Rhodococcus opacus (formerly Nocardia opaca) were studied. The plasmids pHG201, pHG204 and pHG205 carry proteins bound to their ends, as shown by gel retardation experiments. A sequence hybridizing with the terminal sequence of pHG207, a recombinant linear plasmid consisting of the left part of pHG204 and the right part of pHG205, which was analysed in a previous study by the authors, could be detected in all linear plasmids of the wild-type R. opacus strains MR11 and MR22. However, only pHG204 and pHG206 carry terminal inverted repeats (TIRs) like pHG207. Cloning and sequencing of the terminal fragment of pHG204 revealed a nearly perfect TIR of 1016 bp. In contrast, the termini of pHG201 and pHG205 share little homology. Sequence analysis of the two end fragments of pHG201 revealed a similarity of only 65% within the terminal 34/32 bp and a perfect TIR of only 3 bp. The results support the assumption that long TIRs are not absolutely necessary for replication and maintenance of linear plasmids.

Structural elements of the Streptomyces oriC region and their interactions with the DnaA protein

Streptomycetes differ from other prokaryotic organisms in their mycelial life cycle and in possessing a large, linear, GC-rich chromosome. To deduce structural features of the Streptomyces origin of chromosomal replication, the oriC sequences of three Streptomyces species (S. antibioticus, S. chrysomallus and S. lividans) were compared. In Streptomyces, the oriC region contains 19 DnaA boxes whose location, orientation and spacing are conserved. The consensus sequence of the DnaA box identified within Streptomyces oriC is (T/C)(T/C)(G/A/C)TCCACA (preferred bases underlined). The interactions of DnaA with DNA fragments containing single, two or three DnaA boxes were studied using surface plasmon resonance. The dissociation constant (KD) for specific binding of individual DnaA boxes varied between 12 and 78 nM. Streptomyces oriC does not contain the three AT-rich 13-mer direct repeats present in the 5' part of the Escherichia coli oriC region. However, short AT-rich sequences are distributed among the DnaA boxes of Streptomyces oriC. Repeated attempts to unwind Streptomyces oriC have been unsuccessful. It remains to be elucidated whether DnaA interacts with putative accessory proteins which help in unwinding Streptomyces oriC.

Cloning and physical mapping of the EcoRI fragments of the giant linear plasmid SCP1

A cosmid library was constructed for the 350-kb giant linear plasmid SCP1 and aligned on a successive linear map. Only a 0.8-kb gap has remained uncloned in the terminal inverted repeats close to both ends. Partial digestion of the aligned cosmids with EcoRI and hybridization with the flanking fragments of the vector enabled physical mapping of all of the EcoRI fragments. On this map, the methylenomycin biosynthetic gene cluster, the insertion sequence IS466, and the sapCDE genes coding for spore-associated proteins were localized.

Chromosome geometry and intraspecific genetic polymorphism in Gram-positive bacteria revealed by pulsed-field gel electrophoresis

Pulsed-field gel electrophoresis (PFGE) proved to be a powerful approach to study bacterial genomics. The genome structure and genetic polymorphism of Gram-positive bacteria from the high G+C (Streptomyces) and low G+C (Streptococcus) groups have been studied. PFGE allowed the estimation of the size of their genome at about 8 Mbp and 1.8 Mbp, respectively, and to get an insight into their chromosome geometry. Thus, physical mapping of the genome of wild-type Streptomyces ambofaciens strains revealed the linearity of the 8 Mbp chromosomal DNA and its typical invertron structure, while the 1.8 Mbp chromosome of Streptococcus thermophilus was shown to be circular. These findings disproved the long-standing idea of universality of bacterial chromosome circularity. In addition, strains belonging to the species S. ambofaciens and S. thermophilus allowed us to characterize the genetic polymorphism at the intraspecific level. Within the S. thermophilus species, comparison of the physical maps showed a relative conservation of gene order as well as restriction sites along the chromosome. In contrast, variable loci were characterized that revealed localized genome rearrangements. The most spectacular of these corresponded to horizontal gene transfer events of sequences. In S. ambofaciens, the physical maps of three isolates pointed to the conservation of the genetic organization. However, a strong polymorphism was observed in the terminal regions of the linear chromosomal DNA. Previous PFGE studies in S. ambofaciens gave proof of a high structural instability of a limited region of the chromosome called unstable region (i.e., DNA rearrangements such as deletions and amplifications). These intraclonal rearrangements create an impressive intraspecific polymorphism of genome size and shape (linear or circular). In both organisms, the DNA rearrangements are restricted to particular regions of the chromosome.

Replication of the linear chromosomal DNA from the centrally located oriC of Streptomyces ambofaciens revealed by PFGE gene dosage analysis

From a cosmid clone of Streptomyces ambofaciens containing the dnaA and gyrAB genes, a 2.7-kb self-replicating DNA fragment containing the chromosome replication origin oriC was isolated. This cosmid was previously maped physically to a region near the middle of the 8-Mb linear chromosomal DNA. A pulsed-field gel electrophoresis time-course analysis revealed that sequences flanking oriC were overrepresented relative to the rest of the chromosomal DNA during rapid growth, indicating that this origin is active. In addition, the terminal regions of the chromosomal DNA showed a slight overrepresentation at the onset of stationary phase.

Genetic instability of the Streptomyces chromosome

The Streptomyces wild-type chromosome is linear in all examples studied. The ends of the chromosome or telomeres consist of terminal inverted repeats of various sizes with proteins covalently bound to their 5' ends. The chromosome is very unstable and undergoes very large deletions spontaneously at rates higher than 0.1% of spores. Frequently, the telomeres are included in the deletions. Loss of both telomeres leads to circularization of the chromosome. The wild-type chromosome can also be circularized artificially by targeted recombination. Spontaneously or artificially circularized chromosomes are even more unstable than the linear ones. High-copy-number tandem amplifications of specific chromosomal regions are frequently associated with the deletions. RecA seems to be involved in the amplification mechanism and control of genetic instability.

Genetic instability and its possible evolutionary implications on the chromosomal structure of Streptomyces

Recent progress in the understanding of the chromosomal rearrangements in Streptomyces has allowed us to envisage the possible involvement of genetic instability in the evolution of the chromosomal structure. The characterization of recombinational events in the terminal parts of the S ambofaciens chromosome, as well as the observation by other groups that linear plasmids and chromosomes are able to interact, would provide an explanation for the very high levels of polymorphism seen in the terminal inverted repeats of different strains of Streptomyces.

Occurrence of deletions, associated with genetic instability in Streptomyces ambofaciens, is independent of the linearity of the chromosomal DNA

The chromosomal structures of mutant strains of Streptomyces ambofaciens which have arisen from genetic instability were investigated by using pulsed-field gel electrophoresis and probing with sequences cloned from the unstable region which maps near the ends of the linear chromosomal DNA. The chromosomal structures of seven mutant strains harboring large deletions were classified into three types. (i) Deletions internal to one chromosomal arm were characterized in two of the mutant strains. In these strains, a linear chromosomal structure was retained, as were parts of the terminal inverted repeats sequences (TIRs) and the proteins bound to them. (ii) Four of the mutants presented a deletion including all sequences from the TIRs. A junction fragment homologous to sequences originating from internal region of both arms was characterized. Consequently, the chromosomal DNA of these strains was deduced to be circularized. Furthermore, chromosomal stability was assessed in the progeny of these circular DNA mutants. Additional deletion events were detected in 11 mutants among the 13 strains isolated, demonstrating that circular chromosomes do not correspond to a stabilization of the chromosome structure and that the occurrence of deletion could be independent of the presence of chromosomal ends. (iii) A mutant with DNA amplification was shown to have a linear chromosome with a deletion of all sequences between the amplified region and the end of the chromosome. The other chromosomal arm remained unaffected by deletion and associated with protein.

Two small linear plasmids of Streptomyces jumonjinensis

In a survey of plasmids in a variety of β-lactam antibiotic producing Streptomyces spp., two small linear plasmids (pSJL1 and pSJL2) of approximately 12 and 17.5 kb were detected within Streptomyces jumonjinensis NRRL 5741, in addition to the previously reported giant linear plasmids pSJL3 and pSJL4. Characterization of these plasmids by Southern hybridization indicated that no significant homology exists between the S. jumonjinensis plasmids and plasmids detected in other β-lactam antibiotic producing Streptomyces spp. Single and double restriction endonuclease digestions were performed to generate maps of the two plasmids. The plasmids pSJL1 and pSJL2 have copy numbers of 21–27 and 15–20, respectively.Key words: Streptomyces, linear plasmid, DNA hybridization, DNA homology.

Physical mapping shows that the unstable oxytetracycline gene cluster of Streptomyces rimosus lies close to one end of the linear chromosome

A restriction map of the 8 Mb linear chromosome of Streptomyces rimosus R6-501 was constructed for the enzymes Asel (13 fragments) and Dral (7 fragments). Linking clones for all 12 Asel sites and 5 of the 6 Dral sites were isolated. The chromosome has terminal inverted repeats of 550 kb, which are the longest yet reported for a Streptomyces species. The oxytetracycline gene cluster lies about 600 kb from one end, which might account for its frequent spontaneous amplification and deletion. Several other markers were localized on the chromosome (dnaA and recA, the rrn operons, the attachment site for pSAM2 and prophages RP2 and RP3). Comparison of the conserved markers with the map of Streptomyces coelicolor A3(2) suggested there are differences in genome organization between the two species.

In vitro evolution of terminal protein-containing genomes

A new self-sustained terminal protein-primed DNA amplification system has been used to describe in vitro evolutionary changes affecting maintenance of the genome size of bacteriophage phi29. These changes involve generation and efficient amplification of short palindromic molecules containing an inverted duplication of one of the original DNA ends. A template-switching mechanism is proposed to account for the appearance of these molecules. After their formation, they would replicate by means of hairpin intermediates. Relevant kinetic information about this DNA replication system has been obtained from the competition between the input full-length phi29 DNA and its derived truncated versions. The physiological relevance of these molecules and the mechanisms to control their formation are discussed.