Akane Meguro

An endophytic actinomycete, Streptomyces sp. AOK-30, isolated from mountain laurel and its antifungal activity

To survey endophytic actinomycetes as potential biocontrol agents against fungal diseases of mountain laurel, young plants of mountain laurel (Kalmia latifolia L.) were used as an isolation source. From a total of 73 actinomycetes isolates obtained from leaves, stems and roots of test plants, Streptomyces sp. AOK-30 was selected, because i) it had a broad and intense antimicrobial spectrum against various yeasts and fungal pathogens of Ericaceae, ii) it grew on the multiplication and rooting media for tissue culture for this plant, and iii) the tissue-cultured seedlings that had been treated with this isolate became resistant to Pestalotia disease without any adverse growth effects such as malformation, dwarfing, discolorization and defoliation. This isolate was identified as Streptomyces sp., based on cultural, physiological and morphological characteristics. The present results indicate that isolate AOK-30 is a potential biocontrol agent against diseases of mountain laurel.

Disease resistance induced by nonantagonistic endophytic Streptomyces spp. on tissue-cultured seedlings of rhododendron

Of 82 strains of endophytic actinomycetes isolated from rhododendron plants, 12 were not antagonistic against Pestalotiopsis sydowiana, which is the causal agent of Pestalotia disease. Of these 12, MBR-37 and MBR-38 (identified as Streptomyces spp.) grew on IMA-2 medium. Tissue-cultured seedlings of rhododendron treated with these nonantagonistic strains showed less wilting and/or smaller lesions to P. sydowiana, although the degree of resistance was a little lower than that conferred by antagonistic Streptomyces galbus strain R-5. These seedlings accumulated the anthocyanin(s), suggesting that resistance induced by these strains could depend on activated defense responses associated with the phenylpropanoid pathway rather than with antibiosis.

Release of the extracellular matrix from conidia of Blumeria graminis in relation to germination

The release of extracellular matrix (ECM) and the emergence of germ tubes from conidia ofBlumeria graminis were studied by light microscopy and micromanipulation. More prompt and frequent ECM release was confirmed on an artificial hydrophobic substratum than on an artificial hydrophilic substratum. Conidia initially incubated on the hydrophilic substratum were transferred by micromanipulation to either the hydrophobic or the hydrophilic substrata. Immediately after transfer onto the hydrophobic substratum, 75% of conidia released ECM, whereas only 16% did so upon transfer to the hydrophilic substratum. Conidia transferred onto the hydrophobic substratum produced a primary germ tube (PGT) more promptly and frequently than those transferred to the hydrophilic substratum. Thus, conidia recognize and respond to substratum hydrophobicity perhaps immediately after contact. When inoculated onto either isolated barley cuticle or the hydrophobic artificial substratum, 2/3 of the conidia produced a PGT from their polar regions. By contrast, on the hydrophilic substratum 2/3 of conidia did so from the side region. These results show that substratum hydrophobicity affects the location of PGT emergence from conidia. Furthermore, the study indicates that very rapid recognition of surface hydrophobicity by conidia promotes ECM release and this in turn may influence the location of PGT emergence.

Rapid pregermination and germination responses of Erysiphe pisi conidia to contact and light

In darkness, most Erysiphe pisi conidia responded rapidly to contact with a hydrophobic artificial substratum and released extracellular material (ECM) in the same way as on pea cuticle. On this substratum and barley leaf epidermis, conidia then produced a germ tube that emerged close to the substratum, contacted it, and differentiated an appressorium. By contrast, on a hydrophilic substratum, ECM release and germination were delayed and infrequent, and germ tubes often emerged and faced away from the substratum toward vertical light, thereby failing to make contact and form appressoria. This finding supported the hypothesis that ECM release is involved in both triggering germination and sensing substratum contact. Exposure to white light dramatically affected the germ tube emergence site so most emerged from a site in the conidial wall facing the light. Lateral light did not affect the frequency of germ tubes making substratum contact; but when lit from above, most germ tubes emerged up, facing away from the substratum. The germ tubes formed in light were longer than those formed in darkness, but no phototropism was found for the elongating tubes. Examination of Blumeria graminis indicated that its conidia and germ tubes are insensitive to white light.