Chilean Botrytis cinerea Isolates with Reduced Sensitivity to Fludioxonil Exhibit Low to Null Fitness Penalties.

The main phytosanitary problem for table grape production in Chile is gray mold caused by the fungus Botrytis cinerea. To manage this issue, the primary method utilized is chemical control. Fludioxonil, a phenylpyrrole, is highly effective in controlling B. cinerea and other plant pathogens. Consistently, there have been no field reports of reduced efficacy of fludioxonil; however, subpopulations with reduced sensitivity to fludioxonil are on the rise globally, as per increasing reports. Our study involved a large-scale evaluation of B. cinerea's sensitivity to fludioxonil in the Central Valley of Chile's primary table grape production area during the growing seasons from 2015 to 2018. Out of 2,207 isolates, only 1.04% of the isolates (n = 23) exceeded the sensitivity threshold value of 1 µg/ml. Remarkably, 95.7% are concentrated in a geographic region (Valparaíso Region). Isolates with reduced sensitivity to fludioxonil showed growth comparable with sensitive isolates and even more robust growth under nutritional deficit, temperature, or osmotic stress, suggesting greater environmental adaptation. When table grape detached berries were stored at 0°C, isolates less sensitive to fludioxonil caused larger lesions than sensitive isolates (2.82 mm compared with 1.48 mm). However, the lesions generated by both types of isolates were equivalent at room temperature. This study found no cross-resistance between fludioxonil and fenhexamid, an essential fungicide integrated with fludioxonil in Chilean B. cinerea control programs. All the Chilean isolates with reduced sensitivity to fludioxonil were controlled by the fludioxonil/cyprodinil mixture, a commonly employed form of fludioxonil. The cyprodinil sensitivity in the isolates with reduced sensitivity to fludioxonil explains their low field frequency despite their null fitness penalties. However, the emergence of fludioxonil-resistant isolates inside the Chilean B. cinerea population demands a comprehensive analysis of their genetic bases, accompanied by monitoring tools that allow the permanence of field fludioxonil efficacy.

First Report of canker and branch dieback of sweet cherry trees caused by Calosphaeria pulchella in Chile.

In Chile, the 2019-2020 sweet cherry season yielded 228,548 t, produced on 38,392 hectares and an average annual crop value about US$1.6 billion (http://www.iqonsulting.com/yb/). Between autumn 2019 and summer of 2020, branch and limbs dieback symptoms were observed in two 12-year-old sweet cherry (Prunus avium L.) orchards located in the O'Higgins region (Chile Central Valley). Furthermore, other symptoms such as wilting leaves, cankers, bark cracking, emission of gum exudates and internal wood necrosis were detected on trees of "Bing", "Santina" and "Sweetheart" cultivars (Cainelli et al. 2017). Wood fragments from symptomatic branches were surface sterilized with 95% ethanol, flaming and placed onto potato dextrose agar (PDA) amended with 0.5 g liter-1 of streptomycin sulfate (Berbegal et al. 2014). After 7 days of incubation at 25°C, pink to red colonies with white margins were isolated. Each isolate was characterized by having hyaline and oblong-ellipsoidal conidia of 5.76 ± 0.88 × 1.76 ± 0.36 µm (n=100) (Trouillas et al. 2012). According to these morphological features, the fungus was identified as Calosphaeria pulchella (Pers.: Fr.) J. Schröt (anamorph Calosphaeriosphora pulchella Réblová,L. Mostert, W. Gams & Crous) (Réblová et al. 2004). ITS (Internal Transcribed Spacer region of the rDNA) sequence comparison using BLAST analysis revealed a 99.48% identity and 100% query coverage between C. pulchella sequence HM237297 and the Chilean isolates. Moreover, the Chilean isolates were confirmed by means of phylogenetic analysis using ITS sequences of C. pulchella available in GenBank database. The maximum-parsimony phylogenetic tree supported the cluster analysis of the Chilean C. pulchella isolates with those obtained in other regions of the world with a bootstrap value of 95% (Berbegal et al. 2014; Trouillas et al. 2012). The Chilean ITS sequences were deposited into GenBank (MT378444 to MT378447). Two-year-old sweet cherry trees cv. Bing were inoculated with the Chilean isolates. Six trees were used as replicates. To accomplish this goal, two punctures of 5mm diameter were made in two branches per tree with a cork borer and a plug of mycelium from 7-day-old colonies was laid on the wound mycelium side down. Six trees were inoculated with sterile agar plugs. Every puncture was sealed with petroleum jelly and wrapped with parafilm. Four months after inoculation, the vascular streaking developing from the inoculated wounds was measured. The average lesion lengths on inoculated and non-inoculated shoots were 43.79 and 21.79 mm, respectively, which were significantly different according LSD Fisher test (p<0.05). C. pulchella was recovered from all the inoculated branches. No fungus was isolated from the controls, confirming Koch's postulates (Trouillas et al. 2012). To our knowledge this is the first report of C. pulchella causing canker and branch dieback in sweet cherry trees in Chile. This new disease represents a serious threat to the Chilean cherry industry, and further research on disease control is needed.

Botrytis prunorum Associated to Vitis vinifera Blossom Blight in Chile.

Table grapes are highly susceptible to Botrytis cinerea infections during the bloom period. After reaching the flower development stage, B. cinerea remains quiescent until berry ripening or gives rise to blossom blight under specific climate conditions. A research study was conducted on the Chilean Central Valley during the 2018-2019 growing season. Flowers of Vitis vinifera cv. Thompson Seedless were collected and B. cinerea was isolated together to a second and morphologically different species, characterized by white mycelium and low to no sporulation (11.4% of total isolates). Three randomly selected isolates within this population were genetically examined and identified as Botrytis prunorum based on a phylogenetic multilocus approach using partial regions of genes RPB2, HSP60, and G3PDH or NEP1 and NEP2. Pathogenicity tests showed that B. prunorum infects and causes wilting in healthy table grape flowers. B. prunorum isolates were able to infect Thompson Seedless berries, inducing lesions between 13.11 and 41.53% with respect to the lesion diameter generated by B. cinerea B05.10. The fungicide sensitivity was evaluated. The three genetically characterized isolates were sensitive to boscalid and to cyprodinil/fludioxonil mixture with a mean EC50 value of 5.5 µg/ml and 0.065 µg/ml, respectively. However, loss of sensitivity to fenhexamid was determined, with a mean EC50 value of 5.13 µg/ml. Our understanding about blossom blight in V. vinifera has been limited to B. cinerea. Here we associated B. prunorum as a second causal agent of this disease in Chile. This data represents a first approach to the epidemiological characteristics of B. prunorum associated with blossom blight in table grapes.