First report of Phaeoacremonium oleae and P. viticola associated with olive trunk diseases in Italy

Over 300 trunk, branch and stem samples with vascular discolouration, necrotic wood and shoot death were collected from olive (Olea europaea) orchards in Lecce, Brindisi, Bari and Foggia provinces (Apulia region, Italy) from October to May from 2013 to 2019. Small chips of symptomatic wood samples were surface sterilised (5% NaOCl, 3 min; 70% ethanol, 30 s), rinsed (sterile distilled water, ×3), and placed onto potato dextrose agar (PDA) plates amended with 500 ppm streptomycin sulphate. After 14 days at 25 °C in the dark, hyphal tips of growing fungi, including different taxa, for instance Phaeoacremonium and Botryosphaeriaceae spp., were transferred to new PDA plates and incubated until sporulation. Monoclonal colonies resembling Phaeoacremonium-like genus (Mostert et al. 2006) were selected for further study, and genomic DNA of 59 representative isolates was extracted (Carlucci et al. 2013). Partial actin and β-tubulin genes were amplified with primers ACT-513F/ACT-783R (Carbone & Kohn 1999), and T1(O’Donnell & Cigelnik 1997) and Bt2b (Glass & Donaldson 1995), respectively. The sequenced amplicons were compared by BLAST algorithms with reference strains of Phaeoacremonium spp. retrieved from GenBank. Forty-four isolates showed 99% to 100% similarity with reference strains P. italicum, P. minimum, P. parasiticum, P. scolyti and P. sicilianum (Carlucci et al. 2015), nine with P. oleae, and six with P. viticola. Actin and β-tubulin sequences of P. oleae (Pm14) and P. viticola (Pm34) were submitted to GenBank (MW714561, MW714563; MZ318697, MZ318696). Microscopy of P. oleae isolates showed: conidiophores branched and unbranched, (18.7–)21.9–57.1(–67.8) × (2.9–)3.3–4.7(–5.2) (mean, 38.9×4.1) μm (n=30); conidia oblong-ellipsoidal to obovoid or subcylindrical 3.4 to 5.5 μm long, and 1.5 to 2.4 (mean, 4.6 × 2.2) μm wide (n=30). Microscopy of P. viticola isolates showed: conidiophores subcylindrical, branched at base (6.7–)8.9–27.2(–29.3) × (2.0–)2.6–3.3(–3.7) (mean, 21.4 × 3.2) μm (n=30); conidia oblong-ellipsoidal to obovoid or subcylindrical 3.3 to 6.8 μm long, and 1.1 to 2.2 (mean, 4.2 × 1.6) μm wide (n=30). In spring 2020, artificial inoculations were carried out with P. oleae (Pm14, Pm46) and P. viticola (Pm34, Pm43) strains on 10 healthy, 2-year-old olive seedlings cultivar ‘Coratina’. Agar plugs (diameter, 0.3–0.5 cm) from 10-day-old cultures grown on water agar at 23 (±2) °C were inserted under the bark of small wounds in the stems (length, 0.4–1.0 cm) made with a sterile scalpel. After inoculation, the wounds were wrapped with wet sterile cotton wool and sealed with Parafilm. Ten control olive seedlings were inoculated with sterile agar plugs. The experiment was replicated three times. All inoculated young olive plants were grown in pots in a greenhouse without temperature control. After 120 days, inoculated plants showed decline symptoms, and when cut longitudinally, brown streaks were observed in the wood. For P. oleae these streaks measured 3.0-5.5 cm long (standard deviation [SD], 0.9 cm, and for P. viticola they were 1.8-3.5 cm (SD, 0.62). Both fungal species were re-isolated from the symptomatic wood from 85% and 80%, respectively, of these inoculated olive seedlings, fulfilling Koch’s postulates. No symptoms were observed from olive seedlings used as control. P. oleae was first described as a fungal pathogen of wild olive (Olea europaea subsp. cuspidate) in South Africa by Spies et al. (2018), and P. viticola as a fungal pathogen of grapevine in France by Dupont et al. (2000). To the best of our knowledge, this is the first report of P. oleae associated with olive trunk disease in Italy, and the first report of P. viticola associated with olive trunk disease worldwide. References: Carbone I. & Kohn L.M. 1999. Mycologia 91:553. Carlucci A. et al. 2015. Eur. J. Plant Pathol. 141:717. Carlucci A. et al. 2013. Phytopathol. Mediterr. 52:517. Dupont et al. 2000. Mycologia 92:499-504. Glass N. L. & Donaldson G. C. 1995. J. Cl. Microbiol. 41: 1332. Mostert L. et al. 2006. Stud. Mycol. 54:1. O’Donnell K. & Cigelnik E. 1997. Mol. Phylogenetics Evol 7:103. Spies et al. 2018. Persoonia 40:26.

Pathogenicity testing of fungal isolates associated with olive trunk diseases in South Africa

A recent olive trunk disease survey performed in the Western Cape Province, South Africa, identified several fungi associated with olive trunk disease symptoms, including species of Basidiomycota, Botryosphaeriaceae, Coniochaetaceae, Calosphaeriaceae, Diaporthaceae, Diatrypaceae, Phaeomoniellaceae, Phaeosphaeriaceae, Symbiotaphrinaceae, Togniniaceae and Valsaceae. Many of the species recovered had not yet been reported from olive trees and therefore the aim of this study was to determine their pathogenicity towards this host. Pathogenicity tests were first conducted on detached shoots to select virulent isolates which were then used in field trials. During field trials, 2-year-old olive branches of 15-year-old trees were inoculated by inserting colonised agar plugs into artificially wounded tissue. Measurements were made of the internal lesions after 8 months. In total, 58 isolates were selected for the field trials. Species that formed lesions significantly larger than the control could be considered as olive trunk pathogens. These include Biscogniauxia rosacearum, Celerioriella umnquma, Coniochaeta velutina, Coniothyrium ferrarisianum, isolates of the Cytospora pruinosa complex, Didymocyrtis banksiae, Diaporthe foeniculina, Eutypa lata, Fomitiporella viticola, Neofusicoccum stellenboschiana, Nm. vitifusiforme, Neophaeomoniella niveniae, Phaeoacremonium africanum, Pm. minimum, Pm. oleae, Pm. parasiticum, Pm. prunicola, Pm. scolyti, Pm. spadicum, Pleurostoma richardsiae, Pseudophaeomoniella globosa, Punctularia atropurpurascens, Vredendaliella oleae, an undescribed Cytospora sp., Geosmithia sp., two undescribed Neofusicoccum spp. and four Xenocylindrosporium spp. Pseudophaeomoniella globosa can be regarded as one of the main olive trunk pathogens in South Africa, due to its high incidence from olive trunk disease symptoms in established orchards and due to its high virulence in pathogenicity trials.

Effect of Abamectin on Fungal Growth and its Efficacy as a Miticide in the Laboratory

Abamectin was tested for use with solid agar media in the laboratory to eliminate or kill the common mold mite Tyrophagus spp. in fungal cultures of Phaeomoniella chlamydospora (Pch) and Phaeoacremonium minimum (Pmin), two important grape pathogens involved in grapevine trunk disease. Abamectin concentrations tested were at or below the recommended dose for abamectin in greenhouse spray applications (≦625ug/mL) to control mites and determine if: a) fungal growth would be inhibited, and b) mites would be killed or their activity suppressed. Abamectin was added either to the media before autoclaving, or filter-sterilized and added after autoclaving, to test the effects of autoclaving on abamectin efficacy. Streptomycin (100µg/mL) was also added to a set of treatments to determine if this commonly-used antibiotic would impact abamectin efficacy against mites, or have an effect on fungal growth when in combination with abamectin. Filter-sterilized abamectin in the range of 62.5 - 312ug/mL, delivered to the media after it had been autoclaved, provided the most effective control of mites while also showing limited inhibition of fungal growth on solid agar media in the absence of streptomycin. The addition of filter-sterilized streptomycin had no significant effect on fungal growth for Pch, while for Pmin a small but significant reduction in growth with streptomycin occurred at abamectin concentrations above 62.5 ug/ml.