Studying the Efficiency of Local Isolates of the Hyperparasite Ampelomyces quisqualis Ces. ex Schlecht in Controlling Some Powdery Mildew Diseases
2022
Shady Hussain Hamzeh
Pycnidial fungi of the genus Ampelomyces are recognized as natural enemies of a wide spectrum of powdery mildews. These mycoparasites are naturally occurring in Syria, but the investigations about the possibility of their investment in biocontrol strategies are limited to ecological studies. For this purpose, field surveillance was performed in 6 governorates of two regions (southern and coastal areas) . A total of 73 plant samples infected with powdery mildews were collected from 10 locations of the southern area in (Damascus, Damascus rural and Sweida governorates) in addition to 20 locations of the coastal area (Lattakia and Tartus governorates). Ampelomyces pycnidia were detected in 5 samples; four of which from coastal area were found parasiting two powdery mildew species; Erysiphe convolvuli on Convolvulus arvensis L. and E. heraclei on Ammi majus. In addition, a new occurrence on Golovinomces neosalviae infecting Salvia officinalis L. was recorded in one sample in Damascus. Ampelomyces pycnidia were successfully isolated from collected samples on PDA medium and their morphological characterization was carried out. As a result, two morphologically distinct isolates were found in one of the five specimens. Mean dimensions of coastal pycnidia and conidia on the natural host were 61.17 x 28.25 and 6.85 x 3.57μm respectively, while same measurements of 152.52 x 132.13 and 8.75 x 3.3μm were recorded on PDA. The southern isolate had mean dimensions of 77.44 x 25.28 and 8.11 x 3.88μm of pycnidia and conidia respectively on natural host, whereas the mean dimensions on PDA were 125.27 x 115.95 and 8.86 x 3.18μm. Nucleotide sequencing of the six isolates using the specific revers primer AQ-R462 revealed 6 sequences officially accessed in GenBank. Phylogenetic analysis using Maximum parsimony and Maximum likelihood criteria revealed that studied isolates were joined to internationally recognized related taxa. Three isolates joined exactly two groups with high similarity of at least 97%. The three other isolates formed independent branch sisters with the three previous isolates in different identity percentages. Based on some morphological differentiations in culture of one coastal isolate (Bah1), no clear relationship could be necessarily obtained between this isolate‟s morphological and molecular versus geographical and physiological characteristics. Although several isolates showed identical nucleotide sequences, they had variable color morphology in culture and these variations did not relate with neither the morphology nor the size of pycnidia and conidia. Artificial infection of the mycoparasite on three powdery mildews was carried out using detached leaf assay in vitro. Treating E. cichorasearum, G. neosalviae and E. necator (the causal agent of powdery mildews on Cucurbita maxima L., S. officinalis and vitisvenifera L. respectively) with isolate NCBT-S.ham82 of Ampelomyces resulted in the higher parasitism intensity means of 205, 151.77 and 61.88 pycnidia/cm2 respectively at the suspension concentration of 5.9 × 10⁷ conidia/ml. Impact of isolate NCBT-Bah1-G1 was only recorded on E. necator with a high intensity mean of 116.25 pycnidia /cm2 at the same previous spore concentration. No impact of this isolate was observed on the other two studied powdery mildews. This study is an attempt for the investment of the mycoparasite Ampelomyces quisqualis in bio-controlling powdery mildews. Also, a new mycoparasite/host plant combination was recorded in southern Syria, for the first time worldwide in the best of our knowledge, and this new isolate showed high performance on two powdery mildews (on cucurbits and Salvia officinalis) and moderate impact on the third one (grapevine).
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Bibliographic information
Publisher
Damascus University . Faculty of agricultural engineering
Other Subjects
تطفل فطري; Mycoparasitism; عدوى اصطناعية
Language
Arabic
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References
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2024-01-16
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