ABSTRACT
English walnut (Juglans regia), cv. Chandler is the most cultivated tree nut in Chile, with 43,734 ha. In Maule Region, central Chile, English walnut plantings have expanded over an additional 7,000 ha in the last five years. During a routine orchard survey in 2019, branch and twig dieback symptoms were observed in two commercial orchards located in San Rafael (10 years old) and Longaví (12 years old) in the Maule Region, with an incidence of 45% to 65% of affected trees, respectively. Symptomatic branch samples (n = 15) were collected from the two commercial orchards and transported to the laboratory in a cooler and then surface sterilized in 96% ethanol for 3 s and briefly flamed. Cross-section of symptomatic branches revealed brown to dark-brown wedge-shaped wood cankers. Small (5 mm) pieces of wood from the edge of cankered tissues were placed on Potato Dextrose Agar (PDA, 2%) amended with 0.005% tetracycline, 0.01% streptomycin, and 0.1% Igepal CO-630 (PDAm) (Díaz and Latorre 2014) and incubated at 25°C for five days in the dark. Pure cultures were obtained by transferring a hyphal tip from growing colonies to fresh PDA media. Each fungal isolate was recovered from a single diseased branch (47%). Seven isolates (Dsar-1 to Dsar-7) developed dark to olive-brown fast-growing colonies with scarce aerial mycelium after seven days at 25°C on PDA. These isolates showed a dark-olive color on the reverse side of Petri dishes and developed abundant, aggregated, and dark-brown pycnidia after 15 days at 25°C. Conidia were hyaline and aseptate, dark brown, 1-septate, with a brown wall, ovoid with a broadly rounded apex and truncated base, (17.5-) 19.5 ±1.2 (-22.0) x (7.6-) 8.9 ± 0.6 (-10.1) µm (n = 30). These isolates were tentatively identified morphologically as Dothiorella sp. (Phillips et al. 2005). Molecular identification was performed using ITS1/ITS4 and EF1-728F/EF1-986R primers (White et al. 1990; Dissanayake et al. 2015) of the internal transcribed spacer (ITS1-5.8S-ITS2) region and part of the translation elongation factor (EF1-ï¡) genes, respectively. A MegaBlast search in GenBank showed a 100% similarity to isolate CBS 115038, the ex-type of Dothiorella sarmentorum. The sequences were added to GenBank (OM161950 to OM161956 for ITS; OM177188 to OM177194 for EF1-ï¡). Pathogenicity of two isolates (Dsar-2 and Dsar-7) was tested in the orchard on freshly made pruning wounds on attached branches of 2-year-old-pruned English walnut trees cv. Chandler. A second pathogenicity test was done on freshly made pruning wounds in 1-year-old rooted cuttings (n=15) (40 cm of long) of English walnut cv. Chandler. Each pruning wound was inoculated with 40 µL conidial suspension (105 conidia/mL). Sterile distilled water was used as a control treatment. Both pathogenicity tests were repeated once. After seven months for attached branches and four months for rooted plants, necrotic streaks with a mean length of 81.3 and 44.5 mm were observed below the inoculated pruning wounds, respectively. No necrotic streaks were observed in any of the control wounds. Dothiorella sarmentorum was 100% reisolated from symptomatic tissues of inoculated branches and molecularly identified (EF1-ï¡), thus fulfilling Koch's postulates. Recently, D. sarmentorum has been reported causing English walnut dieback in Spain (López-Moral et al. 2020). To our knowledge, this is the first report of D. sarmentorum causing branch dieback of English walnut in Chile. Further studies are needed to know the impact and extent of canker and branch dieback of walnut in commercial orchards in the Maule Region, central Chile.
ABSTRACT
Apple (Malus × domestica) is an important fruit crop in Chile, with a cultivated area of 32,313 ha concentrated (63%) in Maule Region (35°25' S). Unusual core rot on 'Fuji' apples was observed at harvest in a commercial orchard in Curicó, Maule Region, with an incidence ranged between 22 to 35% in 2018 and 2019. Previously, in 2017, an incidence of 30% was estimated on 'Fuji' fruits destined to the Asian market. Internal decay symptoms consisted of dry, corky light to dark-brown tissue, within the seed locules initially. In moderate to severe cases, the necrotic lesion progresses deeper into the mesoderm. External symptoms were quite subtle, and typically, the disease goes unnoticed. However, infected fruit ripen earlier. Small pieces (2-3 mm) from the internal lesion margin of symptomatic apples (n = 50) were placed on Potato Dextrose Agar (PDA) (2%) and incubated at 20°C for 10 days. Pure cultures (n = 41) were obtained and transferred to Malt Extract Agar (MEA) (2%). Colonies on MEA produced an even to slight undulating buff margin with white woolly aerial mycelium, and immerse ochreous in the center, changing gray to olivaceous aerial mycelium with age. On the underside, colonies were umber and buff in the center and margin, respectively. After 10 days, numerous densely aggregate dark-brown mature pycnidia were observed. Aseptate conidia were subglobose to cylindrical, straight, and sometimes curved with rounded at both ends, that was initially hyaline to pale olive, thin, smooth wall with mean dimensions of (2.9-) 3.4 (-4.4) x (1.5-) 1.8 (2.2) µm (n=50). Based on morphology, the fungus was identified as Kalmusia variispora (Verkley et al. 2014). The internal transcribed space (ITS), portion of ß-tubulin (TUB), and large subunits of the nuclear ribosomal RNA (LSU) loci were used for molecular identification, using primers ITS4/ITS5, Bt2a/Bt2b, and LR0R/LR5 (Ariyawansa et al., 2014). BLAST searches indicated 100% identity with K. variispora (ex-type CBS 121517). The maximum parsimony phylogenetic analysis placed Chilean isolates in the K. variispora clade. Sequences were deposited in GenBank (OL711706 to OL711709, OL739499 to OL739502 and OL711710 to OL711713 for ITS, TUB and LSU, respectively). Pathogenicity tests were conducted using four K. variispora isolates. 'Fuji' apples (n = 20) were surface disinfested (75% ethanol, 30 s) and then wounded and inoculated with conidial suspension (50 ïL of 106 conidia/mL) deposited in the middle and into the core region using a sterile fine-tipped micropipette. Additionally, 20 one-year dormant rooted cuttings 'Fuji' and 'Cripps Pink' were pruned and immediately inoculated on the pruning wound. An equal number of apples and rooted cuttings treated with sterile water were used as controls. The experiments were repeated once. All inoculated fruits developed lateral lesions (22 to 37 mm) and dry core rot (18 to 36 mm) symptoms identical to those described in the original outbreak, after 20 days at 20°C in a commercial packing box. The inoculated cuttings produced canker lesions of 10 to 21 mm in length, and dieback symptoms were observed after 3 months. No symptoms were observed on the negative controls. Koch's postulates were fulfilled by 100% reisolating K. variispora. Previously, Alternaria spp. have been reported as the primary pathogen associated with moldy core and dry core rot of apples worldwide (McLeod et al., 2014) and in Chile (Elfar et al., 2018). However, Kalmusia spp. have been associated with dry core rot in apples (McLeod et al., 2014) and have been isolated from canker symptoms on apples in Chile (Díaz et al. 2021). To our knowledge, this is the first report of a severe outbreak of K. variispora causing dry core rot in apples in Chile and worldwide.
ABSTRACT
Mutualistic symbiosis and eusociality have developed through gradual evolutionary processes at different times in specific lineages. Like some species of termites and ants, ambrosia beetles have independently evolved a mutualistic nutritional symbiosis with fungi, which has been associated with the evolution of complex social behaviors in some members of this group. We sequenced the transcriptomes of two ambrosia complexes (Euwallacea sp. near fornicatusâ»Fusarium euwallaceae and Xyleborus glabratusâ»Raffaelea lauricola) to find evolutionary signatures associated with mutualism and behavior evolution. We identified signatures of positive selection in genes related to nutrient homeostasis; regulation of gene expression; development and function of the nervous system, which may be involved in diet specialization; behavioral changes; and social evolution in this lineage. Finally, we found convergent changes in evolutionary rates of proteins across lineages with phylogenetically independent origins of sociality and mutualism, suggesting a constrained evolution of conserved genes in social species, and an evolutionary rate acceleration related to changes in selective pressures in mutualistic lineages.
ABSTRACT
Plant rhizobacteria have been successfully used as biocontrol agents against fungal phytopathogens. However, their potential to control two important avocado diseases, namely Fusarium dieback (FD) and Phytophthora root rot (PRR), has been poorly studied. FD is an emerging disease triggered by fungi associated with two ambrosia beetle species (Euwallacea fornicatus species complex), while PRR is caused by Phytophthora cinnamomi, a soil-borne oomycete. In the present work, the antifungal activity of bacteria isolated from avocado rhizosphere was tested in dual culture assays against Fusarium euwallaceae, Graphium euwallaceae and Graphium sp., causal agents of FD, and against P. cinnamomi. In 2015, rhizosphere soil samples of FD infested and non-infested avocado trees were collected from a commercial avocado orchard in Escondido, California. In an initial screening, 72 of the 168 assessed bacterial isolates reduced mycelial growth of F. euwallaceae by up to 46%. Eight bacterial isolates showing inhibition percentages larger than 40% were then selected for further antagonism assays against the other fungal pathogens. Five bacterial isolates, determined by 16S rDNA sequencing to belong to the Bacillus subtilis/Bacillus amyloliquefaciens species complex, successfully inhibited the mycelial growth of both Graphium species by up to 30%. The same isolates and an additional isolate identified as Bacillus mycoides, inhibited the growth of P. cinnamomi by up to 25%. This is the first report of avocado rhizobacteria with antifungal activity against pathogens responsible for FD and PRR in avocado.