Genome of the bacterium Streptococcus pneumoniae strain R6.

Streptococcus pneumoniae is among the most significant causes of bacterial disease in humans. Here we report the 2,038,615-bp genomic sequence of the gram-positive bacterium S. pneumoniae R6. Because the R6 strain is avirulent and, more importantly, because it is readily transformed with DNA from homologous species and many heterologous species, it is the principal platform for investigation of the biology of this important pathogen. It is also used as a primary vehicle for genomics-based development of antibiotics for gram-positive bacteria. In our analysis of the genome, we identified a large number of new uncharacterized genes predicted to encode proteins that either reside on the surface of the cell or are secreted. Among those proteins there may be new targets for vaccine and antibiotic development.

DNA sequence sampling of the Streptococcus pneumoniae genome to identify novel targets for antibiotic development.

We initiated a survey of the Streptococcus pneumoniae genome by DNA sequence sampling. More than 9,500 random DNA sequences of approximately 500 bases average length were determined. Partial sequences sufficient to identify approximately 95% of the aminoacyl tRNA synthetase genes and ribosomal protein (rps) genes were found by comparing the database of partial sequences to known sequences from other organisms. Many genes involved in DNA replication, repair, and mutagenesis are present in S. pneumoniae. Genes for the major subunits of RNA polymerase are also present, as are genes for two alternative sigma factors, rpoD and rpoN. Many genes necessary for amino acid or cofactor biosynthesis and aerobic energy metabolism in other bacteria appear to be absent from the S. pneumoniae genome. A number of genes involved in cell wall biosynthesis and septation were identified, including six homologs to different penicillin binding proteins. Interestingly, four genes involved in the addition of D-alanine to lipoteicoic acid in other gram positive bacteria were found, even though the lipoteicoic acid in S. pneumoniae has not been shown to contain D-alanine. The S. pneumoniae genome contains a number of chaperonin genes similar to those found in other bacteria, but apparently does not contain genes involved in the type III secretion commonly observed in gram negative pathogens. The G+C content of S. pneumoniae genomic DNA is approximately 43 mole percent and the size of the genome is approximately 2.0 Mb as determined by pulsed-field gel electrophoresis. Many of the genes identified by sequence sampling have been physically mapped to the 19 different SmaI fragments derived from the S. pneumoniae genome. The database of random genome sequence tags (GSTs) provides the starting material for determining the complete genome sequence, gene disruption analysis, and comparative genomics to identify novel targets for antibiotic development.

Molecular cloning and physical mapping of the daptomycin gene cluster from Streptomyces roseosporus.

The daptomycin biosynthetic gene cluster of Streptomyces roseosporus was analyzed by Tn5099 mutagenesis, molecular cloning, partial DNA sequencing, and insertional mutagenesis with cloned segments of DNA. The daptomycin biosynthetic gene cluster spans at least 50 kb and is located about 400 to 500 kb from one end of the approximately 7,100-kb linear chromosome. We identified two peptide synthetase coding regions interrupted by a 10- to 20-kb region that may encode other functions in lipopeptide biosynthesis.

Applications of transposition mutagenesis in antibiotic producing streptomycetes.

Several transposons have been developed from the streptomycete insertion sequence IS493. They have broad host specificity in Streptomyces species and insert relatively randomly into a consensus target sequence of gNCaNTgNNy. Collectively, they have specialized features that facilitate the following: cloning of DNA flanking insertions; physical mapping of insertions; construction of highly stable mutants; and efficient construction of mutant libraries. All of the transposons can be introduced into streptomycetes by conjugation from E. coli, and can be delivered by curing the temperature sensitive delivery plasmid. Tn5099 was used to physically map genes involved in daptomycin and red pigment production in Streptomyces roseosporus, and to clone daptomycin biosynthetic genes. Tn5099 was also used in Streptomyces fradiae to identify and clone a neutral genomic site for the insertion of a second copy of the tylF gene. Recombinants containing two copies of the tylF gene carried out the normally rate limiting conversion of macrocin to tylosin very efficiently, thus causing substantial increases in tylosin yield.

Gene transfer and transposition mutagenesis in Streptomyces roseosporus: mapping of insertions that influence daptomycin or pigment production.

Streptomyces reseosporus, the producer of the cyclic lipopeptide antibiotic daptomycin, was shown to be a suitable host for molecular genetic manipulation. S. roseosporus does not appear to express significant restriction barriers based upon bacteriophage plaque formation studies. Plasmid DNA can be introduced into S. roseosporus by bacteriophage-FP43-mediated transduction and by conjugation from Escherichia coli. The streptomycete transposons Tn5096 and Tn5099, derived from IS493, transpose in S. roseosporus, and Tn5099-induced transposition mutants altered in the production of daptomycin, red pigment or black pigment were identified, and mapped to Dral and Asnl fragments. Three auxotrophic mutations (argB1, ade-1 and metB1) were identified among 100 individual Tn5096 insertions. Alignment and physical mapping of several Tn5099 insertions in Dral-E and Asnl-B fragments was facilitated by the presence of Dral and Asnl cleavage sites in Tn5099.

Transposition of Tn5096 and related transposons in Streptomyces species.

IS493 is an insertion sequence isolated from Streptomyces lividans by a method designed to 'trap' transposable elements. IS493 was converted to functional transposons by cloning antibiotic-resistance-encoding genes between ORF-A and ORF-B of IS493 or near the left-end inverted repeat of the element. Tn5096 transposed relatively randomly in several Streptomyces species. Tn5096 can be introduced into streptomycetes on temperature-sensitive vectors by protoplast transformation, FP43-mediated transduction, or by conjugation from Escherichia coli. We have shown that additional genes can be inserted in Tn5096 without disrupting transposition, and that Tn5096 insertions in a tylosin (Ty)-producing strain of Streptomyces fradiae frequently cause no deleterious effects on Ty production. A promoter probe transposon, Tn5099, containing a promoterless xylE gene, transposed in Streptomyces griseofuscus and S. fradiae, and transcriptional fusions were readily identified.

Transposition of Tn5096 from a temperature-sensitive transducible plasmid in Streptomyces spp.

Transposon Tn5096 was inserted into a derivative of the temperature-sensitive plasmid pMT660 containing the bacteriophage FP43 pac site. The resulting plasmid, pRHB126, was transduced by FP43 into several Streptomyces species. Tn5096 transposed from pRHB126 into different sites in the genomes of Streptomyces ambofaciens, Streptomyces cinnamonensis, Streptomyces coelicolor A3(2), Streptomyces fradiae, Streptomyces griseofuscus, and Streptomyces thermotolerans.

Properties of the streptomycete temperate bacteriophage FP43.

FP43 is a temperate bacteriophage for Streptomyces griseofuscus that forms plaques on many Streptomyces species. FP43 virions contain 56 kb of double-strand DNA that is circularly permuted and terminally redundant, and contains 65% G + C. A physical map of the FP43 genome was constructed, and the origin for headful packaging (pac) was localized to an 8.8-kb region of the genome (hft) that mediates high-frequency transduction by FP43 of plasmid pRHB101. The phage attachment site (attP), a replication origin (rep), a region that inhibits plaque formation (pin), and a 3-kb deletion (rpt) that caused a 100-fold reduction in plasmid transduction were mapped.

Transposition and transduction of plasmid DNA in Streptomyces spp.

To expand the application of molecular genetics to many different streptomycete species, we have been developing two potentially widely applicable methodologies: transposon mutagenesis and plasmid transduction. We constructed three transposons from the Streptomyces lividans insertion sequence IS493. Tn5096 and Tn5097 contain an apramycin resistance gene inserted in different orientations between the two open reading frames of IS493. These transposons transpose from different plasmids into many different sites in the Streptomyces griseofuscus chromosome and into its resident linear plasmids. Tn5099 contains a promoterless xylE gene and a hygromycin-resistance gene inserted in IS493 close to one end. Tn5099 transposes in S. griseofuscus giving operon fusions in some cases that drive expression of the xylE gene product, catechol deoxygenase, giving yellow colonies in the presence of catechol. We have also developed plasmid vectors that can be transduced into many streptomycete species by bacteriophage FP43. We describe the characterization of FP43 and mapping of several bacteriophage functions. The region of cloned FP43 DNA essential for plasmid transduction includes the origin for headful packaging.

Characterization of FP22, a large streptomycete bacteriophage with DNA insensitive to cleavage by many restriction enzymes.

Bacteriophage FP22 has a very broad host range within streptomycetes and appeared to form lysogens of Streptomyces ambofaciens ATCC 15154. FP22 shared strong cross-immunity and antibody cross-reactivity with bacteriophage P23, but not with seven other streptomycete bacteriophages. FP22 particles had a head diameter of 71 nm and a tail length of 307 nm. The FP22 genome was 131 kb, which is the largest bacteriophage genome reported for streptomycetes. The G + C content of the genome was 46 mol% and restriction mapping indicated that FP22 DNA had discrete ends. NaCl- and pyrophosphate-resistant deletion mutants were readily isolated and the extent of the deletions defined at least 23 kb of dispensable DNA in two regions of the genome. The DNA was not cleaved by most restriction endonucleases (or isoschizomers) which have been identified in the streptomycetes, including the tetranucleotide cutter MboI (GATC).

Transduction and transformation of plasmid DNA in Streptomyces fradiae strains that express different levels of restriction.

We constructed nonrestricting strains of Streptomyces fradiae blocked in different steps in tylosin biosynthesis. Plasmid transformation frequencies were 10(3)- to 10(4)-fold higher and bacteriophage plating efficiencies were 10(4)- to 10(8)-fold higher in the nonrestricting strains than in the restricting strains. The efficiencies of transduction of plasmid pRHB101 in S. fradiae strains varied by over 1,000-fold, depending on growth conditions, and optimum transduction frequencies were obtained when cells were grown to mid-exponential phase at 39 degrees C. Under these conditions, restricting and nonrestricting strains were transduced at frequencies that differed by only two- to fivefold.

Transduction of plasmid DNA in Streptomyces spp. and related genera by bacteriophage FP43.

A segment (hft) of bacteriophage FP43 DNA cloned into plasmid pIJ702 mediated high-frequency transduction of the resulting plasmid (pRHB101) by FP43 in Streptomyces griseofuscus. The transducing particles contained linear concatemers of plasmid DNA. Lysates of FP43 prepared on S. griseofuscus containing pRHB101 also transduced many other Streptomyces species, including several that restrict plaque formation by FP43 and at least two that produce restriction endonucleases that cut pRHB101 DNA. Transduction efficiencies in different species were influenced by the addition of anti-FP43 antiserum to the transduction plates, the temperature for cell growth before transduction, the multiplicity of infection, and the host on which the transducing lysate was prepared. FP43 lysates prepared on S. griseofuscus(pRHB101) also transduced species of Streptoverticillium, Chainia, and Saccharopolyspora.

Efficient transformation of Amycolatopsis orientalis (Nocardia orientalis) protoplasts by Streptomyces plasmids.

Conditions for efficient transformation of Amycolatopsis orientalis (Nocardia orientalis) protoplasts by Streptomyces plasmid cloning vectors were identified. Three streptomycete plasmid origins of replication function in A. orientalis, as do the apramycin resistance gene from Escherichia coli, the thiostrepton resistance gene from Streptomyces azureus, and the tyrosinase gene from Streptomyces antibioticus. A. orientalis appears to express some restriction and modification, because highest transformation frequencies (10(6)/micrograms of DNA) were obtained when plasmid pIJ702 was modified by passage in A. orientalis.