Rhamnose biosynthesis pathway supplies precursors for primary and secondary metabolism in Saccharopolyspora spinosa.

Rhamnose is an essential component of the insect control agent spinosad. However, the genes coding for the four enzymes involved in rhamnose biosynthesis in Saccharopolyspora spinosa are located in three different regions of the genome, all unlinked to the cluster of other genes that are required for spinosyn biosynthesis. Disruption of any of the rhamnose genes resulted in mutants with highly fragmented mycelia that could survive only in media supplemented with an osmotic stabilizer. It appears that this single set of genes provides rhamnose for cell wall synthesis as well as for secondary metabolite production. Duplicating the first two genes of the pathway caused a significant improvement in the yield of spinosyn fermentation products.

Cloning and analysis of the spinosad biosynthetic gene cluster of Saccharopolyspora spinosa.

BACKGROUND: Spinosad is a mixture of novel macrolide secondary metabolites produced by Saccharopolyspora spinosa. It is used in agriculture as a potent insect control agent with exceptional safety to non-target organisms. The cloning of the spinosyn biosynthetic gene cluster provides the starting materials for the molecular genetic manipulation of spinosad yields, and for the production of novel derivatives containing alterations in the polyketide core or in the attached sugars. RESULTS: We cloned the spinosad biosynthetic genes by molecular probing, complementation of blocked mutants, and cosmid walking, and sequenced an 80 kb region. We carried out gene disruptions of some of the genes and analyzed the mutants for product formation and for the bioconversion of intermediates in the spinosyn pathway. The spinosyn gene cluster contains five large open reading frames that encode a multifunctional, multi-subunit type I polyketide synthase (PKS). The PKS cluster is flanked on one side by genes involved in the biosynthesis of the amino sugar forosamine, in O-methylations of rhamnose, in sugar attachment to the polyketide, and in polyketide cross-bridging. Genes involved in the early common steps in the biosynthesis of forosamine and rhamnose, and genes dedicated to rhamnose biosynthesis, were not located in the 80 kb cluster. CONCLUSIONS: Most of the S. spinosa genes involved in spinosyn biosynthesis are found in one 74 kb cluster, though it does not contain all of the genes required for the essential deoxysugars. Characterization of the clustered genes suggests that the spinosyns are synthesized largely by mechanisms similar to those used to assemble complex macrolides in other actinomycetes. However, there are several unusual genes in the spinosyn cluster that could encode enzymes that generate the most striking structural feature of these compounds, a tetracyclic polyketide aglycone nucleus.

Genes for the biosynthesis of spinosyns: applications for yield improvement in Saccharopolyspora spinosa.

Spinosyns A and D are the active ingredients in an insect control agent produced by fermentation of Saccharopolyspora spinosa. Spinosyns are macrolides with a 21-carbon, tetracyclic lactone backbone to which the deoxysugars forosamine and tri-O-methylrhamnose are attached. The spinosyn biosynthesis genes, except for the rhamnose genes, are located in a cluster that spans 74 kb of the S. spinosa genome. DNA sequence analysis, targeted gene disruptions and bioconversion studies identified five large genes encoding type I polyketide synthase subunits, and 14 genes involved in sugar biosynthesis, sugar attachment to the polyketide or cross-bridging of the polyketide. Four rhamnose biosynthetic genes, two of which are also necessary for forosamine biosynthesis, are located outside the spinosyn gene cluster. Duplication of the spinosyn genes linked to the polyketide synthase genes stimulated the final step in the biosynthesis--the conversion of the forosamine-less pseudoaglycones to endproducts. Duplication of genes involved in the early steps of deoxysugar biosynthesis increased spinosyn yield significantly.

A cluster of genes for the biosynthesis of spinosyns, novel macrolide insect control agents produced by Saccharopolyspora spinosa.

Spinosyns A and D are the active ingredients in a family of insect control agents produced by fermentation of Saccharopolyspora spinosa. Spinosyns are 21-carbon tetracyclic lactones to which are attached two deoxysugars. Most of the genes involved in spinosyn biosynthesis are clustered in an 74 kb region of the S. spinosa genome. This region has been characterized by DNA sequence analysis and by targeted gene disruptions. The spinosyn biosynthetic gene cluster contains five large genes encoding a type I polyketide synthase, and 14 genes involved in modification of the macrolactone, or in the synthesis, modification and attachment of the deoxysugars. Four genes required for rhamnose biosynthesis (two of which are also required for forosamine biosynthesis) are not present in the cluster. A pathway for the biosynthesis of spinosyns is proposed.

Transformation of maize (Zea mays L.) protoplasts and regeneration of haploid transgenic plants.

Transgenic haploid maize (Zea mays L.) plants were obtained from protoplasts isolated from microspore-derived cell suspension cultures. Protoplasts were electroporated in the presence of plasmid DNA containing the gus A and npt II genes encoding ß-glucuronidase (GUS) and neomycin phosphotransferase II (NPT II), respectively. Transformed calli were selected and continuously maintained on kanamycin containing medium. Stable transformation was confirmed by enzyme assays and DNA. analysis. Stably transformed tissue was transferred to regeneration medium and several plants were obtained. Most plants showed NPT II activity, and some also showed GUS activity. Chromosome examinations performed on representative plants showed that they were haploid. As expected, these plants were infertile.

The development of virus-resistant alfalfa, Medicago sativa L.

We have generated more than 100 transgenic alfalfa plants, via Agrobacterium-mediated gene transfer, from genotypes selected from five alfalfa cultivars. These plants express the genes for kanamycin resistance and for the coat protein of alfalfa mosaic virus (AMV). The strongest expressers accumulated nearly 500 ng coat protein per mg soluble leaf protein. AMV inoculation of protoplasts from these strong expressers indicated that they were resistant to infection by AMV, while protoplasts from plants containing about a hundred-fold less coat protein and from control untransformed plants were not. Transgenic alfalfa plants containing large amounts of coat protein were, likewise, resistant to AMV. These plants did not develop systemic infections following inoculation with up to 50 micrograms/ml AMV, while inoculated control plants developed systemic infections following inoculation with as little as 10 micrograms/ml AMV. These results demonstrate that expression of the AMV coat protein gene confers resistance to AMV infection in transgenic alfalfa plants.

In vitro sodium bisulfite mutagenesis of restriction endonuclease recognition sites.

Sodium bisulfite treatment of single-stranded DNA deaminates exposed cytosine residues to form uracil, resulting in cytosine-to-thymidine transition mutations following DNA replication. We have used this reaction in vitro to destroy the recognition sequences for the restriction endonucleases HindIII and XmaI in the aminoglycoside 3'-phosphotransferase I coding region of plasmid pUC4K. This procedure should be applicable to the mutation of any recognition sequence of restriction endonucleases which generate cytosine-containing single-stranded ends. The possibility of mutagenesis of restriction sites to generate stop codons in coding regions is discussed.

Transformation of cotton (Gossypium hirsutum L.) by Agrobacterium tumefaciens and regeneration of transgenic plants.

Cotton (Gossypium hirsutum L.) cotyledon tissues have been efficiently transformed and plants have been regenerated. Cotyledon pieces from 12-day-old aseptically germinated seedlings were inoculated with Agrobacterium tumefaciens strains containing avirulent Ti (tumor-inducing) plasmids with a chimeric gene encoding kanamycin resistance. After three days cocultivation, the cotyledon pieces were placed on a callus initiation medium containing kanamycin for selection. High frequencies of transformed kanamycin-resistant calli were produced, more than 80% of which were induced to form somatic embryos. Somatic embryos were germinated, and plants were regenerated and transferred to soil. Transformation was confirmed by opine production, kanamycin resistance, immunoassay, and DNA blot hybridization. This process for producing transgenic cotton plants facilitates transfer of genes of economic importance to cotton.

Phaseolin gene from bean is expressed after transfer to sunflower via tumor-inducing plasmid vectors.

Sequences coding for the bean seed protein phaseolin were inserted into transferred DNA regions of tumor-inducing plasmids. Constructions were devised in which the coding region of phaseolin was fused in the correct reading frame with the coding region of octopine synthase and placed under the transcriptional control of the octopine synthase promoter. Other plasmids were prepared to permit expression of the phaseolin-encoding sequences from the flanking phaseolin promoter region. The RNA transcribed in sunflower cells transformed with these constructions was characterized by hybridization procedures, SI nuclease mapping, and by translation in vitro of extracted RNA. These tests showed that the genomic intervening sequences were correctly excised. Immunoreactive phaseolin polypeptides were detected by enzyme-linked immunosorbent assay and by antibody hybridization to electrophoretically separated protein extracts of sunflower tissues isolated from crown gall tumors and of transformed sunflower cells grown in tissue culture. These results demonstrate the expression of a plant gene after transfer to a taxonomically distinct botanical family.

Plasmid DNA of Agrobacterium tumefaciens detected in a presumed habituated tobacco cell line.

'Tabac anergié' tissue has been used by many investigators as a habituated tobacco cell line. In this study, we have found sequences which are homologous to approximately 9 megadaltons of an Agrobacterium octopine-type plasmid in DNA isolated from 'Tabac anergié' tissue. These T-DNA sequences were shown to be the same 'core DNA' sequences found to be present in several other unorganized tumor lines which have been studied in our laboratory. The T-DNA was also shown to be integrated into plant DNA. Thus, the 'Tabac anergié' tissue is a crown gall tumor induced by a strain of Agrobacterium tumefaciens containing an octopine-type plasmid. These results indicate that the plants regenerated from 40 clones of the 'Tabac anergié' line by Sacristán and Melchers (1977) were actually reverted plants obtained from an unorganized crown gall tumor, kept in culture for more than 25 years. It is necessary to re-evaluate observations and conclusions which have been based upon 'Tabac anergié' being a habituated tissue.

The boundaries and copy numbers of Ti plasmid T-DNA vary in crown gall tumors.

The Ti plasmid DNA maintained in octopine-type crown gall tumor lines is variable, but always includes at least part of the Ti plasmid that maps over the region of Hind III fragment 1 of pTiB6-806. The right-hand boundary of transferred DNA (T-DNA) varies considerably among the three independent tumor lines examined; the left boundary was not located definitively. The T-DNA of two sibling clones of the same tumor line, E1 and E9, appears identical. The copy number of T-DNA in E9 tumor DNA appears higher for the right end (about 30 copies) than for the left end (approximately 1 copy).

Plasmids in avirulent strains of Agrobacterium.

Twelve strains of Agrobacterium radiobacter isolated from naturally occurring crown galls or soil were found to be avirulent on sunflower, tomato, Kalanchoe, and carrot. Eleven strains contained plasmids of molecular weights 77 X 10(6) to 182 X 10(6) as determined by electron microscopy. One strain contained only a smaller plasmid (50 X 10(6) daltons). Several strains had both large and small (ca. 11 X 10(6) daltons) plasmids; one strain contained two large plasmids (112 X 10(6) and 136 X 10(6) daltons). Hybridization reactions of virulence plasmids from Agrobacterium tumefaciens strains C58 and A6 with plasmids from each of the A. radiobacter strains revealed that some A. radiobacter plasmids had less than 10% homology to either the C58 or A6 plasmids. Plasmids from some strains had approximately 50% homology with the C58 plasmid, but only one A. radiobacter plasmid contained more than 10% homology to the A6 plasmid. The presence of large plasmids in A. radiobacter strains did not correlate with sensitivity to agrocin 84; however, the utilization of the amino acid derivatives octopine and nopaline was generally correlated to partial base sequence homology to the C58 plasmid. We conclude that all large plasmids found in Agrobacterium strains are not virulence associated, although they may share base sequence homology with a virulence-associated plasmid. Further, plasmids from tumorigenic strains may be more closely related by base sequence homology to plasmids from nonpathogenic strains than to plasmids from other pathogenic strains.

Attempts to Detect Agrobacterium tumefaciens DNA in Crown-Gall Tumor Tissue.

Primary and secondary crown gall tissue cultures were established from sunflower plants (Helianthus annuus, variety Mammoth Russian) wound-inoculated with Agrobacterium tumefaciens (Smith and Townsend) Conn strain B(6). Growth rates of tumor tissues and habituated healthy sunflower stem section tissues on basal medium lacking auxin and cytokinin were compared to those of healthy sunflower stem section tissue grown on the same medium with added phytohormones. No difference was detected in the thermal denaturation midpoints (74.8 C) and melting profiles in 25 mm sodium phosphate (pH 6.8), or the buoyant densities in cesium chloride equilibrium centrifugation (1.687 g cm(-3)), between deoxyribonucleic acids (DNAs) isolated from crude nuclear preparations of the four tissue types. No satellite DNA was observed in equilibrium centrifugation of unsheared plant DNAs.Heterologous DNA renaturation kinetic analyses were performed in 0.14 m sodium phosphate (pH 6.8) at 70 C. Thermal stability measurements of reassociated DNA revealed less than 1% of mismatched base pairs. Reannealing of sheared, denatured, radioactive A. tumefaciens B(6) DNA (molecular weight, 325,000 daltons) in the presence of a 5400-fold excess of sheared calf thymus, healthy tissue, or secondary sunflower crown gall DNA obeyed second order kinetics, with a Cot((1/2)) of 2.8, identical to that observed when B(6) DNA was reannealed in the absence of foreign DNA.Reannealing rates of B(6) DNA in the presence of 5400-fold excesses of DNA from two lines of primary sunflower crown gall were increased 2.24- or 1.47-fold. Digestion of the tumor DNA preparations with pancreatic deoxyribonuclease I until no detectable DNA remained, followed by restoration of solution viscosity by added calf thymus DNA, failed to remove the acceleration effect of the tumor DNA preparations. Reisolation of the reannealed nucleic acid formed in this experiment, and digestion with ribonuclease A or deoxyribonuclease I revealed that the double-stranded fraction was composed entirely of DNA-DNA duplexes, with no detectable DNA-RNA hybrids.The data indicate that tumor, but not healthy tissue DNA preparations contain some factor or factors (not DNA) which accelerate the reannealing of bacterial DNA. Sunflower tumor tissue DNAs, therefore, do not contain integrated A. tumefaciens DNA sequences in amounts greater than a random (1/5) of the bacterial genome per diploid amount of plant DNA, or a complete bacterial genome per five diploid plant cell DNA equivalents. Further, the possibility of the presence of many copies of a specific portion greater than 5% of the bacterial genome is excluded.