Distinguishing bacterial pathogens of potato using a genome-wide microarray approach.

A set of 9676 probes was designed for the most harmful bacterial pathogens of potato and tested in a microarray format. Gene-specific probes could be designed for all genes of Pectobacterium atrosepticum, c. 50% of the genes of Streptomyces scabies and c. 30% of the genes of Clavibacter michiganensis ssp. sepedonicus utilizing the whole-genome sequence information available. For Streptomyces turgidiscabies, 226 probes were designed according to the sequences of a pathogenicity island containing important virulence genes. In addition, probes were designed for the virulence-associated nip (necrosis-inducing protein) genes of P. atrosepticum, P. carotovorum and Dickeya dadantii and for the intergenic spacer (IGS) sequences of the 16S-23S rRNA gene region. Ralstonia solanacearum was not included in the study, because it is a quarantine organism and is not presently found in Finland, but a few probes were also designed for this species. The probes contained on average 40 target-specific nucleotides and were synthesized on the array in situ, organized as eight sub-arrays with an identical set of probes which could be used for hybridization with different samples. All bacteria were readily distinguished using a single channel system for signal detection. Nearly all of the c. 1000 probes designed for C. michiganensis ssp. sepedonicus, c. 50% and 40% of the c. 4000 probes designed for the genes of S. scabies and P. atrosepticum, respectively, and over 100 probes for S. turgidiscabies showed significant signals only with the respective species. P. atrosepticum, P. carotovorum and Dickeya strains were all detected with 110 common probes. By contrast, the strains of these species were found to differ in their signal profiles. Probes targeting the IGS region and nip genes could be used to place strains of Dickeya to two groups, which correlated with differences in virulence. Taken together, the approach of using a custom-designed, genome-wide microarray provided a robust means for distinguishing the bacterial pathogens of potato.

Antimycin A-producing nonphytopathogenic Streptomyces turgidiscabies from potato.

AIM: To detect if substances with mammalian cell toxicity are produced by Streptomyces turgidiscabies and Streptomyces scabiei isolated from potato scab lesions. METHODS AND RESULTS: In vitro cultures of phytopathogenic and nonphytopathogenic strains of S. scabiei and S. turgidiscabies, isolated from scab lesions of potato tubers originating from nine different cultivars from Finland and Sweden, were tested for toxicity using the rapid spermatozoan motility inhibition assay, previously shown useful in the detection of many different Streptomyces toxins and antimicrobial compounds. Purified toxins were used as reference. Three nonphytopathogenic strains of S. turgidiscabies were found to produce antimycin A when cultured on solid medium. CONCLUSIONS: Boar sperm-motility-inhibiting substances are produced by strains of S. turgidiscabies and S. scabiei. The most powerful inhibitory substance, produced by three nonphytopathogenic S. turgidiscabies strains, was identified as antimycin A. The phytotoxic compounds thaxtomin A and concanamycin A did not inhibit sperm motility even at high doses. SIGNIFICANCE AND IMPACT OF THE STUDY: The presence of antimycin A-producing Streptomyces strains, nonpathogenic to potato, was unexpected but important, considering the high mammalian toxicity of this cytochrome bc-blocking antibiotic.

Functional analysis of six ORFs from Saccharomyces cerevisiae chromosome IV: two-spored asci produced by disruptant of YDR027c and strain-dependent DNA heterogeneity around YDR036c.

Six S. cerevisiae FY1679 heterozygous deletion mutants were made by replacing six open reading frames (ORFs) of the chromosome IV right arm with kanMX4 selection marker. Haploid and homozygous diploid deletion mutants were obtained from sporulation, dissection and mating experiments. No essential genes were found. The basic phenotypic analysis showed that the haploid and homozygous deletants for the ORF YDR027c (LUV1, VSP54 or RKI1) grew slowly. The diploid homozygous deletants for this ORF had a low frequency of sporulation. They produced asci with no more than one or two haploid spores and the majority of these spores formed were not viable. The deletion of the other ORFs, YDR022c (CIS1), YDR030c (RAD28), YDR032c (PST2), YDR033w (MRH1) and YDR036c, did not change the phenotypes tested in strain FY1679 or the first four ORFs in strain CEN.PK2. This work showed some differences in the DNA sequences between FY1679 and CEN.PK2: the regions immediately 1 kb upstream from YDR036c in these two strains are too different to hybridize properly, preventing deletion of YDR036c in the CEN.PK2 background by recombination with a disruption cassette designed for FY1679. In addition, there are different sets of transposable elements on the other side of the ORF, the differences starting at about 3.5 kb downstream from YDR036c.