First report of canker caused by Cytospora sorbicola on Sweet Cherry (Prunus avium) in Chile.

Chile leads cherry exports in the southern hemisphere with a total of 415.315 t exported in the 2022 to 2023 season (IQonsulting, 2023). Cytospora canker, produced by Cytospora spp., causes destructive infections and limit the productivity of sweet cherry orchards (Luo et al. 2019). This study was focused on isolating Cytospora strains to identify and characterize the species present in sweet cherry. During the period 2019-2022, ten samples of stem or branch presenting canker, dieback, gummosis or dead buds, were collected from sweet cherry cultivars 'Skeena', 'Lapins', 'Santina', 'Sweetheart', and 'Regina', in the regions Ñuble and O'Higgins, Chile. Five mm pieces from the necrotic wood margins of the samples were rinsed with sterile deionized water, placed on potato dextrose agar (PDA, Difco) and incubated at 20±2 ºC for 5 days. One isolate was recovered from each sample, resulting in ten Cytospora-like strains. Single hyphal tips were transferred onto PDA plates and all isolates were deposited in the Chilean Collection of Microbial Genetic Resources (CChRGM). Colonies grown on PDA reached 89 mm in diameter in 10 d at 25 °C, showing irregular margin, lacking aerial mycelium, initially off-white to cream that turned greenish gray in the center, which darkens with age. After 20 days of culturing on pine needle agar (Chen et al. 2015), isolates produced conidiomata pycnidial, semi-immersed, black, and subglobose (362)445-555(681)×(357)528-700(1053) µm (n=10), generating amber slimy conidia masses; Conidiophores were phialidic, cylindrical, aseptate, hyaline (6.77)9-10.04(12.88)×(0.82)1.1-1.28(1.99) µm (n = 30); conidia were abundant, allantoid, hyaline to light brown, aseptate (3.39)4.28-4.57(5.36)×(0.69)0.96-1.09(1.47) µm (n = 30) (Supplementary Figure 1). No sexual morph was observed. With the exception of the strain RGM 3390, all the isolates shared morphological characters to the descriptions of Cytospora sorbicola Norphanph., Bulgakov, T. C. Wen & K. D. Hyde (Norphanphoun et al. 2017). Isolates were identified at species level, by sequencing DNA regions described by Pan et al. (2020): ITS1-5.8S-ITS2, LSU; act, tef-1α, and tub2 with the exception of the RBP2, because this region could not be amplified in seven out of ten isolates. The consensus tree included the concatenated sequences of the ten isolates and those of reference Cytospora species reported by Ilyukhin et al. (2023) using a maximum likelihood analysis with the tool IQ-TREE webserver. MLSA confirmed the taxonomic affiliation of nine of the isolates with C. sorbicola and one isolate with Cytospora sp. (RGM 3390), that might represent a novel species (Supplementary Figure 2). The isolates RGM 3399 and RGM 3400, were selected randomly for pathogenicity tests. Inoculations were performed on 2-year-old sweet cherry cv. 'Lapins' grow in pots in a greenhouse at 26±6°C. Seven plants per isolate were cut to about 6-cm length from the main stem, and inoculated onto fresh cuts with 5-mm mycelium PDA plugs of 5-d-old culture and wrapped in moist sterile cotton and parafilm to keep moisture. Six plants were inoculated with non-colonized PDA agar plugs as control. The average canker length 3 months after inoculation was 3.1 and 0.8 cm, for RGM 3389 and RGM 3400, respectively (Supplementary Figure 1). Symptomatic twigs were incubated in moist chambers at 20±2 ºC for 10 d, resulting in the re-isolation of Cytospora strains that produced pycnidia and conidia structures in agreement with C. sorbicola. Both strains were reidentified to fulfill Koch's postulates, control twigs remained asymptomatic and no fungus was isolated from these twigs. This is the first report of C. sorbicola causing canker on sweet cherry in Chile. Our findings suggest that this species could be the most recurrent in cherry in central Chile, coinciding with it found in California where C. sorbicola has been described as the main causal agent of Cytospora canker of stone fruits in California (Lawrence et al. 2018).

Identification and distribution of species of Neofusicoccum that cause blueberry stem blight in Chile.

Stem blight is a destructive woody disease of blueberry (Vaccinium corymbosum) caused by several species of the family Botryosphaeriaceae. A field survey was conducted in the mayor blueberry production area of Chile, comprising latitudes 32°49'S to 40°55'S, to determine the occurrence and distribution of Botryosphaeriaceae in the region. Together, a multilocus analysis, morphological characterization, and phytopathogenicity testing were used to identify 51 Neofusicoccum isolates belonging to N. nonquaesitum (28 strains), N. parvum (22 strains), and N. australe (1 strain). Of these, N. parvum and N. nonquaesitum were the most commonly found, with N. parvum most frequent from latitude 37°40'S to the north and N. nonquaesitum predominantly located from the same latitude toward the south. Morphological traits of the isolates were consistent with the species identified by molecular techniques, despite the overlapping of conidial size of some isolates among species. Pathogenicity trials showed that the three species were pathogenic to blueberry plants and revealed that N. parvum and N. nonquaesitum were the most aggressive species, although variability in virulence was observed among isolates of N. parvum and N. nonquaesitum.

First report of Colletotrichum fioriniae causing anthracnose fruit rot on Vaccinium corymbosum in Chile.

Vaccinium corymbosum L. is the most cultivated blueberry species in Chile. Chilean fruits typically take up to 50 days to reach oversea markets; therefore, controlling post-harvest pathogens is of outmost importance to maintain international food safety and quality standards. In February 2019, the Microbial Genetic Resources Bank at INIA received fruits of V. corymbosum cv. 'Brigitta Blue' from Mariquina (-39.567869, -72.992461), located in the southern Chilean blueberry production zone, for post-harvest disease diagnosis. Asymptomatic fruits were incubated in moist-chambers at 25 °C with light/darkness cycles of 12 h. After 5 d, some fruits showed sunken areas and small surface wounds that exudated orange masses of conidia; under the epidermis, gray acervuli were also detected. After 15d, these fruits became dehydrated, mummified, and covered by mycelia, all characteristic symptoms of anthracnose (Wharton and Schilder 2008). In Chile, Colletotrichum gloeosporioides has, thus far, been the only causal agent of anthracnose reported in blueberry (Lara et al. 2003). Conidia exudated from the diseased fruit were inoculated on potato-dextrose agar (PDA) and incubated at 25 °C for 7 d. The resulting colony was predominantly cottony with gray aerial mycelium, displaying masses of pale orange conidia; on the reverse side, the colony was a pink-reddish color. Under a microscope, conidia were hyaline, fusiform to elliptic in shape, and displaying guttulate of 12.2±1.2 × 4.17±0.3 µm (n=30), characteristics coinciding with those described for Colletotrichum fioriniae (Pennycook 2017; Shivas and Tan 2009) (Supplementary Figure 1). The isolate was deposited in the Chilean Collection of Microbial Genetic Resources (CChRGM) as RGM 3330. Genomic DNA extraction of RGM 3330 and phylogenetic analyses were carried out according to Cisterna-Oyarce et al. (2022). A multi-locus sequencing analysis was carried out using five genetic markers. The internal transcribed spacer (ITS), glyceraldehyde 3-phosphate dehydrogenase (gapdh), actin (act), and chitin synthase 1 (chs-1) were PCR-amplified following Damm et al. (2012) and -tubulin (tub) following Glass and Donaldson (1995). Sequences were deposited in GenBank (ON364141 for ITS and ON369167-70 for tub, act, chs-1, and gapdh, respectively) (Sayers et al. 2021). A BLAST analysis carried out in SequenceServer (Priyam et al. 2019), using a custom database of sequences retrieved from Damm et al. (2012) and Liu et al. (2020), showed that all genetic markers were 100% identical to those of C. fioriniae CBS 128517T (ITS (540/540 identities), gapdh (249/249), act (245/245), and chs-1 (274/274)), except for tub, which shared 99.8% of its identities (416/417) with this species. Maximum likelihood phylogenetic estimation clustered RGM 3330 with C. fioriniae strains CBS 128517T and CBS 126526 with 100% bootstrap support (Supplementary Figure 1). Koch's postulates were carried out with asymptomatic fruits of V. corymbosum cv. 'Brigitta Blue'. Prior to inoculation, fruits were surface-sterilized for 10 s in 70% ethanol, 3 s in 1% NaOCl, 10 s in 70% ethanol, rinsed three times with sterile distilled water, and subsequently placed in moist-chambers. Two groups of three repetitions of 20 fruits each were sprayed with 9 × 106 conidia/mL of RGM 3330 for the first group and with sterile distilled water for the control. After 5 d at 25 °C with light/darkness cycles of 12 h, only fruits sprayed with the conidial solution developed symptoms of anthracnose and the re-isolated fungi were identical in morphology to RGM 3330. This is the first report of C. fioriniae in blueberry in Chile. References Cisterna-Oyarce, V., Carrasco-Fernández, J., Castro, J. F., Santelices, C., Muñoz-Reyes, V., Millas, P., Buddie, A. G., and France, A. 2022. Gnomoniopsis smithogilvyi: identification, characterization and incidence of the main pathogen causing brown rot in postharvest sweet chestnut fruits (Castanea sativa) in Chile. Australasian Plant Disease Notes 17:2. Damm, U., Cannon, P. F., Woudenberg, J. H., and Crous, P. W. 2012. The Colletotrichum acutatum species complex. Stud. Mycol. 73:37-113. Glass, N. L., and Donaldson, G. C. 1995. Development of primer sets designed for use with the PCR to amplify conserved genes from filamentous ascomycetes. Appl. Environ. Microbiol. 61:1323-1330. Lara, O., Velazquez, C. G., and Ascencio, C. 2003. Colletotrichum gloeosporiodes in blueberry fruit. in: XIII Congreso de Fitopatología. Liu, X., Zheng, X., Khaskheli, M. I., Sun, X., Chang, X., and Gong, G. 2020. Identification of Colletotrichum species associated with blueberry anthracnose in Sichuan, China. Pathogens 9:718. Pennycook, S. 2017. Colletotrichum fioriniae comb. & stat. nov., resolving a nomenclatural muddle. Mycotaxon 132:149-152. Priyam, A., Woodcroft, B. J., Rai, V., Moghul, I., Munagala, A., Ter, F., Chowdhary, H., Pieniak, I., Maynard, L. J., Gibbins, M. A., Moon, H., Davis-Richardson, A., Uludag, M., Watson-Haigh, N. S., Challis, R., Nakamura, H., Favreau, E., Gómez, E. A., Pluskal, T., Leonard, G., Rumpf, W., and Wurm, Y. 2019. Sequenceserver: a modern graphical user interface for custom BLAST databases. Mol. Biol. Evol. 36:2922-2924. Sayers, E. W., Cavanaugh, M., Clark, K., Pruitt, K. D., Schoch, C. L., Sherry, S. T., and Karsch-Mizrachi, I. 2021. GenBank. Nucleic Acids Res. 49:D92-D96. Shivas, R. G., and Tan, Y. P. 2009. A taxonomic re-assessment of Colletotrichum acutatum, introducing C. fioriniae comb. et stat. nov. and C. simmondsii sp. nov. Fungal Divers. 39:111-122. Wharton, P., and Schilder, A. 2008. Novel infection strategies of Colletotrichum acutatum on ripe blueberry fruit. Plant Pathol. 57:122-134. Supplementary material Supplementary Figure 1: Isolation and identification of Colletotrichum fioriniae RGM 3330 from blueberry fruits cv. 'Brigitta Blue' from Chile. (A) A fruit showing anthracnose; (B) colony of Colletotrichum fioriniae RGM 3330 growing on PDA; (C) microscopic observation of the conidia (100x magnification; bar=10 µm); (D) phylogenetic tree resulting from a maximum likelihood analysis of combined sequence data from ITS, act, chs-1, gapdh, and tub regions for Colletotrichum acutatum species complex, number in the nodes represent ultrafast bootstrap values.