First report of Trichoderma afroharzianum causing seed rot on maize in Italy

Maize (Zea mays L.) is a cereal crop of great economic importance in Italy; production is currently of 60,602,320 t, covering 588,597 ha (ISTAT 2021). Trichoderma species are widespread filamentous fungi in soil, well known and studied as biological control agents (Vinale et al., 2008). Seeds of a yellow grain hybrid (class FAO 700, 132 days) were collected in September 2020 from an experimental field located in Carmagnola (TO, Italy: GPS: 44°53'11.0"N 7°40'60.0"E) and tested with blotter test (Warham et al., 1996) to assess their phytosanitary condition. Over the 400 seeds tested, more than 50% showed rotting and development of green mycelium typical of the genus Trichoderma. Due to the high and unexpected percentage of decaying kernels, ten colonies were identified by morphological and molecular methods. Single conidia colonies of one Trichoderma (T5.1) strain were cultured on Potato Dextrose Agar (PDA) for pathogenicity tests, and on PDA and Synthetic Nutrient-Poor Agar (SNA) for morphological and molecular identification. The colonies grown on PDA and SNA showed green, abundant, cottony, and radiating aerial mycelium, and yellow pigmentation on the reverse. Colony radius after 72 h at 30°C was of 60-65 mm on PDA and of 50-55 mm on SNA. The isolates produced one cell conidia 2.8 - 3.8 µm long and 2.1 - 3.6 µm wide (n=50) on SNA. Conidiophores and phialides were lageniform to ampulliform and measured 4.5 – 9.7 µm long and 1.6 – 3.6 µm wide (n=50); the base measure 1.5 – 2.9 µm wide and the supporting cell 1.4 – 2.8 µm wide (n=50). The identity of one single-conidia strain was confirmed by sequence comparison of the internal transcribed spacer (ITS), the translation elongation factor-1α (tef-1α), and RNA polymerase II subunit (rpb2) gene fragments (Oskiera et al., 2015). BLASTn searches of GenBank using ITS (OL691534) the partial tef-1α (OL743117) and rpb2 (OL743116) sequences of the representative isolate T5.1, revealed 100% identity for rpb2 to T. afroharzianum TRS835 (KP009149) and 100% identity for tef-1α to T. afroharzianum Z19 (KR911897). Pathogenicity tests were carried out by suspending conidia from a 14-days old culture on PDA in sterile H2O to 1×106 CFU/ml. Twenty-five seeds were sown in pots filled with a steamed mix of white peat and perlite, 80:20 v/v, and maintained at 23°C under a seasonal day/night light cycle. Twenty primary ears were inoculated, by injection into the silk channel, with 1 ml of a conidial suspension of strain T5.1 seven days after silk channel emergence (BBCH 65) (Pfordt et al., 2020). Ears were removed four weeks after inoculation and disease severity, reaching up to 75% of the kernels of the twenty cobs, was assessed visually according to the EPPO guidelines (EPPO, 2015). Five control cobs, inoculated with 1 ml of sterile distilled water were healthy. T. afroharzianum was reisolated from kernels showing a green mold developing on their surface and identified by resequencing of tef-1α gene. T. afroharzianum has been already reported on maize in Germany and France as causal agent of ear rot of maize (Pfordt et al. 2020). Although several species of Trichoderma are known to be beneficial microorganisms, our results support other findings that report Trichoderma spp. causing ear rot on maize in tropical and subtropical areas of the world (Munkvold and White, 2016). The potential production of mycotoxins and the losses that can be caused by the pathogen during post-harvest need to be explored. To our knowledge this is the first report of T. afroharzianum as a pathogen of maize in Italy.

Occurrence of leaf spot caused by Neodeightonia phoenicum on pygmy date plam (Phoenix roebelenii) in China

The pygmy date palm (Phoenix roebelenii) is a popular ornamental plant widely cultivated in tropical regions as well as in China. In June 2018, a new leaf spot symptoms were observed on P. roebelenii in several different parks in Zhanjiang City of China. The early symptoms of infected leaves were presented with small, round, pale brown spots. As the size of these spots increased, they coalesced to form larger irregular necrotic lesions surrounded by dark brown edges, which eventually led to leaf wilted and defoliation. A filamentous fungus was consistently isolated from infected leaf samples. Colonies on PDA at 25°C (12 h light/dark) were initially white with abundant aerial mycelium, which turned fluffy and dark olivaceous after one-week culture. Pycnidial conidiomata were black and globose and formed on pine needles in water agar at 25°C (12 h light/dark) after 21 days. Conidiogenous cells were hyaline, cylindrical, holoblastic. The conidia was ovoid to ellipsoid, thick-walled, which was initially hyaline and aseptate, later turned into dark brown and 1-septate with a striate appearance to conidia, 11.6~25.0 μm×9.6~12.0 μm (av. 20.4 μm×10.1 μm). For molecular identification, the partial sequences of internal transcribed spacer (ITS) regions, translation elongation factor (EF-1α) and β-tubulin (TUB) genes of two representative isolates RYCK-1, RYCK-2 were amplified and sequenced using primer pairs ITS/ITS4 (White et al. 1990), EF-688F/EF-986R (Carbone and Kohn 1999), and Bt2a/Bt2b (Glass and Donaldson 1995), respectively. The sequences of the above three loci of the two isolates (accession nos. ITS, OK329968 and OK329969; EF-1α, OK338067 and OK338068; TUB, OK338069 and OK338070) showed 98.4-100.0 % identity with the existing sequences of ex-type culture CBS 122528 of N. phoenicum. A multilocus phylogenetic analysis of the three loci concatenated sequences using the maximum likelihood method showed the isolates that belongs to N. phoenicum. Based on the morphological characteristics and molecular analysis of the isolates, the fungus was identified as N. phoenicum (Phillips et al. 2008). To confirm pathogenicity, five one-year-old potted plants were used for each isolate (RYCK-1 and RYCK-2) and the plants were inoculated by pricking the epidermis of the leaf with a needle. Five leaves of each plant were sprayed with 100 µl of a conidial suspension (1 × 106 conidia/ml) to the wounded surface for each plant. Sterilized distilled water was used as the control and the experiment was repeated. All the plants were incubated at 26 ± 2°C (12 h light/dark) and covered with plastic bags to maintain constant high humidity. After 14 days, all the inoculated leaves showed the same symptoms as those observed in the original diseased plants, but the control plants remained health. The reisolated fungus was identified as N. phoenicum by morphological and molecular characteristics. N. phoenicum is an important pathogen of Phoenix species plants worldwide, which have been reported to cause shoot blights and stalk rots on P. dactylifera and P. canariensis in Greece (Ligoxigakis et al. 2013) and root rot on P. dactylifera in Qatar (Nishad and Ahmed 2020). To our knowledge, this is first report N. phoenicum causing leaf spot on P. roebelenii in China.

Root Rot of Codonopsis tangshen Caused by Ilyonectria robusta In Chongqing, China

Codonopsis tangshen Oliv. belongs to the Campanulaceae, it is one of the most important economically medicinal materials in China.Which is used in medical and agricultural applications (Wu Q N, et al. 2020). In August 2019, root rot of C. tangshen was firstly observed in Fengjie, Chongqing city, southwest China (30°45′ 59″ N; 109°36′36″ E; ), causing approximately 20% yield loss. At the initial stage of the disease, the above-ground stems and leaves turn yellow, and brown to black spots of different sizes appear at the base or root of the stem. With the further development of the disease, the above-ground leaves gradually turn yellow as the diseased spots rot from bottom to top, so that they die, and the diseased spots on the roots expand and begin to rot. Generally, they gradually rot from the bottom up, but the vascular bundles are occasionally normal. If the symptoms of C.tangshen started too late, and the root has not completely rotted by late autumn (late October to early November), the rest part of C.tangshen root will not continue to rot, and it is called half C.tangshen. In the next spring, the halfC. tangshen can continue to sprout, but it will continue to rot, which will seriously affect the yield and quality. In order to identify the pathogen, 25 samples of diseased plants were collected and symptomatic rhizome tissues were surface disinfected with 0.1% HgCl2 solution for 30s, rinsed in sterilized water 3 times, placed on potato dextrose agar (PDA), and incubated at 25℃±1°C in the dark. On the PDA, after seven days of culture, the center appeared light yellow, the edges were white, and the aerial hyphae were felt-like. The surface of the colony was reddish-brown and the margins were white and regular. The conidiophores were simple, usually born on the lateral or apical sides of aerial mycelium, unbranched, or minimally branched. Conidia were abundant, cylindrical, or rod-shaped, straight or slightly curved, usually with 1–3 septa. Macroconidia varied in size depending on the number of cells as follows: one-septate 15.3–26.3×4.2–7.3 μm（n=50）μm, two-septate 20.5-30.5×4.9-7.8μm (n=50), and three-septate 29.3–38.5×5.5–7.4 μm (n=50), round at both ends. For molecular identification, DNA was extracted from a representative isolate using a fungus genomic DNA extraction kit (Solarbio, Beijing, China). The internal transcribed spacer (ITS)(ITS1/ITS4, White, et al. 1990), beta-tubulin (TUB2)(BT2A/BT2B, O’Donnell and Cigelnik 1997), translation elongation factor 1-a (TEF) （ EF446F/EF1035R, Inderbitzin et al. 2005), DNA-dependent RNA polymerase subunit II gene(RPB2, O'Donnell K., et al. 2010 ) and histone H3(HIS3) (CYLH3F/CYLH3R, Crous, et al. 2004b) were amplified. BLAST results indicated that the ITS, TUB2, TEF, HIS3, and RPB2 sequences (GenBank MW392103, MW386994, MW386995 MW392103, and MW915473) showed 96% to 100% identity with Ilyonectria robusta sequences at NCBI (GenBank KU350726, JF335378, MN833103, MN833113, KM232336). The phylogenetic tree was inferred from the combined datasets (ITS, TEF1, TUB, and HIS3) from members of the I. robusta species complex analyzed in this study (Cabral et al. 2012 ). To complete Koch's postulates, a conidial suspension (106 spores/ml) collected from isolate CQ13 was irrigated onto fifteen annual C.tangshen potted plants. Sterile water was used as a negative control, and the pathogenicity assay was repeated three times. Following inoculation, the plants were cultured for 9 days at 75% relative humidity and 25 ℃. The inoculated plants showed symptoms similar to those observed in the field. In contrast, the negative control plants were healthy and unaffected. I. robusta was re-isolated from the infected tissues and identified by morphological characteristics and DNA sequence analysis. To our knowledge, this is the first report of I. robusta causing root rot disease of C.tangshen in China. Our results may help to take appropriate steps to control the disease in the commercial area of C.tangshen. The authors declare no conflict of interest.

First Report of Seedling Stem Rot on Jinxianlian (Anoectochilus roxburghii) Caused by Fusarium oxysporum in China

Anoectochilus roxburghii is an important Chinese herbal medicine plant belonging to Orchidaceae and known as Jinxianlian. This orchid is cultivated and mostly adopted to treat diabetes and hepatitis. About 2 billion artificially cultivated seedlings of Jinxianlian are required each year and approximately $600 million in fresh A. roxburghii seedlings is produced in China. From 2011, sporadic occurrence of stem rot on Jinxianlian have been observed in greenhouses in Jinhua City (N29°05′, E119°38′), Zhejiang Province. In 2018, nearly 30% of seedlings of Jinxianlian grown in greenhouse conditions were affected by stem rot in Jinhua City. Symptoms initially occurred in the stem at the soil line causing dark discoloration lesions, rotted tissues, wilting, and eventually leading to the death of the plants. A total of 23 diseased seedlings collected from seven different greenhouses were surface sterilized with 1.5% sodium hypochlorite for 3 min, then rinsed in water. Pieces of tissues disinfected from each sample were plated on 2% potato dextrose agar (PDA), and incubated at 25°C in the dark for 5 days (Kirk et al. 2008). A total of 19 isolates were recovered. They developed colonies with purple mycelia and beige or orange colors after 7 days of incubation under 25°C on PDA and carnation leaf agar (CLA) media (Kirk et al. 2008; Zhang et al. 2016). Colonies on PDA had an average radial growth rate of 3.1 to 4.0 mm /d at 25°C. Colony surface was pale vinaceous, floccose with abundant aerial mycelium. On CLA, aerial mycelium was sparse with abundant bright orange sporodochia forming on the carnation leaves. Microconidia were hyaline and oval-ellipsoid to cylindrical (3.7 to 9.3 × 1.3 to 2.9 μm) (n=19). Macroconidia were 3 to 5 septate and fusoid-subulate with a pedicellate base (27.4 to 35.6 × 3.2 to 4.2 μm) (n=19). These morphological features were consistent with Fusarium oxysporum (Sun et al. 2008; Lombard et al., 2019). To confirm the identification based on these morphological features, the internal transcribed spacer region (ITS) and translation elongation factor1 (TEF) were amplified from the DNA of 3 out of 19 isolates chosen at random respectively using the set primer ITS1/ITS4 and EF1/ EF2 (Sun, S., et al. 2018; Lombard et al., 2019). BLAST analysis revealed that the ITS sequences (OK147619, OK147620, OK147621) had 99% identity to that of F. oxysporum isolate JJF2 (GenBank MN626452) and TEF sequence (OK155999, OK156000, OK156001) had 100% identity to that of F. oxysporum isolate gss100 (GenBank MH341210). A multilocus phylogenetic analysis by Bayesian inference (BI) and maximum likelihood (ML) trees based on ITS and TEF indicated that the pathogen grouped consistently with F. oxysporum. Three out of 19 isolates chosen at random were selected to evaluate pathogenicity. Uninfected healthy A. roxburghii seedlings about 40 day-old planted in sterilized substrates were sprayed with distilled water containing 2 x 106 conidia per ml suspensions as inoculums, and plants sprayed with distilled water alone served as controls. Plants were then incubated at 25°C and 85% relative humidity. Ten plants were inoculated for each isolate. After 10 days, all plants inoculated developed stem rot symptoms, while control plants remained healthy. Cultures of Fusarium spp. were re-isolated only from inoculated plants with the frequency of 100% and re-identified by morphological characteristics as F. oxysporum, fulfilling Koch’s postulates. To the best of our knowledge, this is the first report of F. oxysporum causing stem rot on A. roxburghii seedlings. As F. oxysporum is a devastating pathogenic fungus with a broad host range, measures should be taken in advance to manage stem rot of A. roxburghii.

Boeremia exigua Causes Leaf Spot of Walnut Trees (Juglans regia) in China

Walnuts are an important perennial nut crop widely cultivated in China, which are rich in protein, carbohydrate, renieratene, and other beneficial nutrients. China is the largest producer of walnuts in the world, with the largest planting area and output. At the end of April 2020, several unknown necrotic spots on leaves of walnut trees were observed in a Juglans regia field located in Sancha Town, Enshi, China (30°28′N, 109°64′E). Initially, lesions were black, small, sunken, and turning to yellowish-brown, irregular, well surrounded by brown margins. Severely, leaf spots coalesced and resulted in withered and abscised. In order to identify the pathogen, infected leaves were collected. Sections of leaves were aseptically excised from the margins of necrotic spots following surface sterilization and placed on potato dextrose agar (PDA) at 28℃. After 4 days, fungal isolates were obtained and purified by hyphal tip isolation. The isolates looked morphologically similar, producing colonies that appeared hyphae with dark grey, lobed margins, and aerial mycelium with white to light gray. After 15 days of incubation, subglobose, dark brown pycnidia (100-176 μm in wide, 75-95 μm in length) were formed with an orifice in the center, producing conidia. Conidia (3.5 to 9.0 × 1.6 to 4.5 μm) were oval to round, aseptate, occasionally 1-septate. These morphological characteristics lead to the conclusion that the isolates may be identified as Phoma sp. (Boerema et al. 1976). A single isolate was randomly selected and designated for further verification. To confirm the identity, the internal transcribed spacer region (ITS), actin (ACT) and beta-tubulin genes were amplified and sequenced ITS1/ITS4, ACT-512F/ACT-783R, and Bt2a/Bt2b, respectively (White et al. 1990, Groenewald et al. 2013). BLAST analysis of the ITS 505-bp sequence (GenBank accession no. MW282913), actin 269-bp sequence (GenBank accession no. MW201958), and beta-tubulin 347-bp sequence (GenBank accession no. MW273782) showed ≥99% homology with the sequences of B. exigua available in GenBank (GenBank accession no. AB454232, LT158234, and KR010463, respectively). Base on the above results, the strain HTY2 was identified as B. exigua. Pathogenicity was tested. Walnut plants were spray-inoculated with a spore suspension (5 x 105 CFU/mL). Controls were inoculated as described above except that sterile distilled water in the dark at 25 ℃. After seven days, lesions were evident at inoculation points, and equivalent to those observed in field were observed. Control leaves remained symptomless. The pathogenicity test was repeated thrice and the results were the same, fulfilling the Koch’s postulates. The pathogen has been reported on various plants around the world, causing a series of symptoms. Infected plants rarely died, but the presence of lesions decreased their fruit quality and yield. Previous identification of the disease is essential in formulating management strategies.

First Report of Stem Dieback Caused by Lasiodiplodia parva on Styphnolobium japonicum in China

Styphnolobium japonicum (L.) Schott is a variant of Robinia pseudoacacia and is a popular Asian tree widely used in traditional medicine. From March 2019 to 2021, a disease was found on the campus of Nanjing Forestry University and several landscape sites of Xuanwuhu Park, causing dieback. Most of the trees (approximately 40%) have rotted branches. On average, 60% of the branches per individual tree were affected by this disease. The initial round lesions were grayish brown. In the later stage, the whole branch becomes black and produces spherical fruiting bodies . Twenty diseased branches were picked from three random trees. Small tissues (3-4mm²) were surface-sterilized in 75% ethanol for 30 s followed by 1% NaClO for 90 s and placed on potato dextrose agar (PDA), and incubated in the dark at 25°C for three days. Hyphae were visibly emerged from 70% of the samples. Three representative isolates (Lth-soj1, Lth-soj2, and Lth-soj3) were obtained and deposited in China’s Forestry Culture Collection Center (Lth-soj1: cfcc55896, Lth-soj2: cfcc55897, Lth-soj3: cfcc55898). The colonies of three isolates on PDA were fast growing and white, which turned grey to dark grey after 3 days of incubation in the dark at 28°C . Two-weeks old colonies were black and fluffy on PDA, with abundant aerial mycelium, and the reverse side too was black in color. The fungus usually grew well on PDA and produced pycnidia and conidia within 3–4 weeks. Conidia were initially hyaline and aseptate, ellipsoid to ovoid, with granular content, apex broadly rounded, remaining hyaline and later becoming dark brown, one septate, thick walled, base truncate or round and longitudinally striate. The conidia (n=30) of a representative isolate（Lth-soj1）, measured 24.3 ± 0.3 μm in length and 13.3 ± 0.5 μm in width . The morphological characters of the three isolates matched those of Lasiodiplodia parva(Alves et al. 2008). For accurate identification, the DNA of the three isolates was extracted. The internal transcribed spacer region (ITS), translation elongation factor (EF1-α), and β-tubulin 2 (TUB2) genes were amplified using the primer pairs ITS1/ITS4 , EF1-728F/EF1-986R, and Bt2a/Bt2b , respectively. The sequences were deposited in GenBank under accession numbers MZ613154, MZ643245 and MZ643242 for Lth-soj1, MZ613155, MZ643246 and MZ643244 for Lth-soj2, and MZ613157, MZ643247 and MZ643243 for Lth-soj3. The ITS, EF1-α, and TUB2 sequences of isolate Lth-soj1 (GenBank Acc. No. MZ613154, MZ643245, MZ643242) were 100% (519/519 nt), 99.34% (299/301 nt), and 99.77% (436/437 nt) identical to those of MZ182360, EF622063, and MK294119, respectively. Interspecific differences were observed in a maximum-likelihood tree of Lasiodiplodia species using the concatenated dataset. Based on the morphological and molecular evidence, the isolates were identified as L. parva. The pathogenicity of three isolates were tested on potted three-year-old seedlings (100-cm tall) of S. japonicum maintained in a greenhouse. Healthy stems were wounded with a sterile needle then inoculated with 10 µL of conidial suspension. Control plants were treated with ddH2O. In total, 12 seedlings were inoculated including three controls. Three seedlings per isolate and 10 stems per seedling were used for each treatment. The plants were kept inside sealed polythene bags for the first 24 h and sterilized H2O was sprayed into the bags twice a day to maintain humidity and kept in a greenhouse at the day/night temperatures at 25/16°C. Within seven days, all the inoculated points showed lesions similar to those observed in field and the conidiomatas growing on the surface of the branches, whereas controls were asymptomatic . The infection rate of each of the three isolates was 100%. The strain was re-isolated from the lesions and sequenced as L.parva, whereas not from control stems. This is the first report of L. parva causing rotten branches of S. japonicum in China and the worldwide. These data will help to develop effective strategies for managing this newly emerging disease.

First Report of Fusarium culmorum Causing Maize Stalk Rot in China

Maize stalk rot has become one of the most important diseases in maize production in China. From 2017 to 2019, a survey was conducted to determine the population diversity of Fusarium species associated with maize diseases in 18 cities across Henan Province. Maize stalk rot with an incidence of more than 20% that caused yield losses up to 30% was observed on maize variety Zhengdan958, which was grown in two continuous maize fields in Zhumadian City, Henan Province. The stem tissues from the boundary between diseased and healthy pith were chopped into small pieces (3 × 8 mm), disinfected (70% ethanol for 1 min) and then placed onto potato dextrose agar (PDA) amended with L-(+)-Lactic-acid (1 g/L) and incubated at 25°C for 4 days. Colonies on PDA produced fluffy, light yellow aerial mycelium and purple to deep brick red pigment at 25°C (Fig 1A, 1B). On carnation leaf agar (CLA), macroconidia in orange sporodochia formed abundantly, but microconidia were absent. Macroconidia were short and thick-walled, had 3 to 5 septa, a poorly developed foot cell and rounded apical cell (Fig 1C). These characteristics matched the description of Fusarium culmorum (Leslie and Summerell 2006) and isolates DMA268-1-2 and HNZMD-12-7 were selected for further identity confirmation. Species identification was confirmed by partial sequences of three phylogenic loci (EF1-α, RPB1, and RPB2) using the primer pairs EF1/EF2, CULR1F/CULR1R, and CULR2F/CULR2R, respectively (O'Donnell et al., 1998). The consensus sequences from the two isolates were deposited in GenBank (MZ265416 and MZ265417 for TEF, respectively; MZ265412 and MZ265414 for RPB1, respectively; MZ265413 and MZ265415 for RPB2). BLASTn searches indicated that the nucleotide sequences of the three loci of the two isolates revealed 99% to 100% similarity to those of F. culmorum strains deposited in the GenBank, Fusarium-ID, and MLST databases (Supplementary Table 1~3). Pathogenicity test was conducted at the flowering-stage using Zhengdan958 and Xundan20 plants according to previously described method (Zhang et al., 2016; Cao et al., 2021; Zhang et al., 2021). The second or third internodes of thirty flowering plants were drilled to make a wound approximately 8 mm in diameter using an electric drill. Approximately 0.5 mL inoculum (125 mL colonized PDA homogenized with 75 mL sterilized distilled water) was injected into the wound and sealed with Vaseline and Parafilm to maintain moisture and avoid contamination. Sterile PDA slurry was used as a control. Thirty days after inoculation, the dark-brown, soft rot of pith tissues above and below the injection sites were observed, and some plants were severely rotten and lodged (Fig 1D, 1E). These symptoms were similar to those observed in the field. No symptoms were observed on control plants. The same pathogen was re-isolated from the inoculated stalk lesions but not from the control, thereby fulfilling Koch's postulates. To our knowledge, this is the first report of F. culmorum as the causal agent of stalk rot on maize plants in China. Also, this fungus has been reported to cause maize ear rot in China (Duan et al. 2016) and produce mycotoxins such as trichothecenes, nivalenol, and zearalenone that cause toxicosis in animals (Leslie and Summerell 2006). The occurrence of maize stalk rot and ear rot caused by F. culmorum should be monitored due to the potential risk for crop loss and mycotoxin contamination.

First report of Fusarium lateritium causing shoots dieback of Acer negundo in Europe

Box elder (Acer negundo) is a tree native to North America. In Europe it is considered a dangerous invasive species, and assigned to the highest (4th) category of environmental hazard (Tokarska-Guzik et al. 2012). The tree can threaten a wide range of ecosystems and compete with the native flora. The shoot dieback was observed on 20% of boxelder in July 2018 and 2019 in Bryzgiel (N53°59.963' E23°04.324') in NE Poland (Europe). Young trees (10-15 yr. old) with visible symptoms were observed in a small group on the rural roadside. Infected shoots were chlorotic. There were visible shallow cracks on the bark and brown discoloration in sapwood inside infected branches. Symptomatic shoots were collected in sterile envelopes, surface disinfected with 95% ethanol. Twelve fragments of wood were cut from the border of living and dead tissue, and then divided into 3-5 mm pieces, placed on PDA medium and incubated at 21°C. After 10 days ten Fusarium spp. strains were obtained. Pure cultures were derived by monosporic isolation. The identification of the isolates was initially based on morphology and molecular genotyping (Leslie & Summerell 2006). On PDA, strains produced white, dense, floccose aerial mycelium with a pink surface. The underside of the petri dish was brown. Growth of the colony was relatively slow and reached Ø 3.5 cm after two weeks. Microscopic observation revealed the presence of macroconidia located in a few orange sporodochia. Macroconidia were slightly curved, with dimensions of 38-45 µm × 3.2-3,5 µm, 4-5 septate, with well-formed foot cell and beak on the apex. On aerial hyphae, single intercalary chlamydospores were present. Microconidia were not found. Morphological identification was confirmed by sequencing the ITS regions, the TEF-1α and β-tubulin genes for representative isolates. Mycelia were grown on PDB and freeze dried prior to genomic DNA extraction using the CTAB method. Sequences of two isolates were deposited in GenBank as MN186748 and MN588156 for ITS; MZ191070 and MZ191072 for TEF-1α; and MZ191069 and MZ191071 for TEF-1α. BLASTn search in the NCBI database revealed 100, 98 and >99% similarities of ITS, TEF-1α and β-tubulin with F. lateritium isolates LC171689, KT350607 and FN554618 respectively. A pathogenicity test was conducted on five first year Ø 0.6-0.8cm shoots from a 10-year-old tree. Before inoculation their surface was disinfected with 95% ethanol. Then, bark of the twigs was split longitudinally with a sterile blade and pieces of 10-day-old aerial mycelium grown on PDA were applied on the wound sites. Control samples were inoculated with sterile distilled water only. Inoculated areas were covered with parafilm. First sign of infection was observed after three weeks, as a dark lesion in the place of inoculation and chlorosis. Three weeks later the brown ring on the sapwood was marked in the shoot cross-section. Morphologically identical to the original, F. lateritium isolate was reisolated from the infected tissues, thus fulfilling Koch’s postulates. F. lateritium is a species closely associated with trees and shrubs (Leslie & Summerell 2006). However, it has not been recorded on boxelder and this is the first report of F. lateritium causing dieback of boxelder maple. According to the Enemy Release Hypothesis (Elton 1958), new pathogens appearing on alien species can be an indicator of developing environmental resistance to the outlander, which indicate the grade of their domestication. This kind of notification poses a crucial role in invasion monitoring and the search for new biocontrol methods of invasive plant species.

First report of Diplodia seriata, D. mutila, and Dothiorella omnivora associated with apple cankers and dieback in Rio Negro, Argentina

Apple (Malus domestica Borkh.) is an important fruit crop in Río Negro, Argentina. In recent years, the frequency of canker and dieback symptoms have increased affecting different apple cultivars. In September 2014, a higher occurrence of cankers (29%) and dieback (9%) was observed in a commercial orchard of 10-year-old apple trees (n=210) cv ʻItal Redʼ in General Roca, Río Negro, Argentina (39°2'36.73"S – 67°32'44.55"W). Symptoms initially appeared as necrotic bark lesions on tree trunks and branches often associated with pruning wounds. Superficially, papyrus detachment of the bark and cracked bark were observed on the affected area. When the bark was removed, the diseased wood showed dark brown color. Cross sections of diseased branches revealed necrotic lesions that progress to branch death. Samples were collected from different symptomatic trees (n=30) and were superficially disinfected with 70% ethanol. Internal tissues (0.5 cm2) were excised from the advance margin of the necrotic lesions, plated on potato dextrose agar (PDA), and incubated at 22°C. Pycnidia were induced on sterilised pine needles overlaid on 2% water agar under near-UV light. Optimum temperature of culture growth on PDA was studied. According to their morpho-cultural characteristics, three different morphotypes were identified. The first, showed optimum growth at 30°C, had moderately dense white aerial mycelia and turned dark gray after 7 d. Conidia were ovoid, mostly aseptate, 20.8-25.6 × 8-11.4 µm (n=50) and hyaline to brown. The second, exhibited optimum growth from 25 to 30°C, was white to gray, with sparse to moderate aerial mycelium that turned dark olive green. Conidia were ovoid, 1-septate, 17.6-22.4 × 8.1-11.2 µm (n=50) and brown. Finally, the third showed optimum growth at 25°C, mycelium was grey to dark olive green. Conidia were oblong to ovoid with both ends rounded, aseptate and 1-septate at maturity, 20.8-24 × 11.2-14.4 µm (n=50), hyaline turned brown. Genomic DNA was extracted from one representative isolate of each morphotype and the ITS and EF1-α loci were amplified with the primer sets ITS1/ITS4 (White et al., 1990) and EF1-728F/EF1-986R (Carbone and Kohn, 1999), respectively. The nucleotide sequences indicated ≥99% identity to D. seriata (CBS 114796 and CBS 112555), D. mutila (CBS 302.36 and CBS 112553), and D. juglandis (CBS 188.87), reclassified as Dothiorella omnivora (Linaldeddu et al., 2016), for both DNA regions. The sequences were deposited in the GenBank database (MW596418, MW598375; MH665432, MK955889; MH665413, MK937229). To confirm pathogenicity, healthy 1-year-old twigs of adult apple trees were pruned and wounds of attached twigs immediately inoculated with 20 μL of conidial suspension (103 conidia.mL-1, n=9 per isolate) or sterile distilled water (control, n=9), and wrapped with Parafilm. The experimental design was randomized, and the experiment was repeated once. After 90 d, the area of lesion on all twigs inoculated was determined. D. mutila and Do. omnivora produced mean canker areas (65 and 73 mm2, respectively) significantly larger (p < 0.005) than D. seriata (48 mm2). No lesion occurred in the negative controls. Fulfilling Koch’s postulates, fungi were reisolated from all inoculated twigs and no fungus was recovered from controls. To our knowledge, this is the first report of D. seriata, D. mutila, and Do. omnivora associated with apple canker and dieback in Argentina, which shows the need of study the role of these fungi in orchard health.

First Report of Leaf Anthracnose Caused by Colletotrichum karstii of Piper nigrum in Yunnan Province, China

Pepper (Piper nigrum L.) is one of the economically important spice crops of China and mainly grown in the Hainan and Yunnan provinces. In January 2021, the classic anthracnose lesions were observed on pepper leaves at a plantation (24°57’50"N, 98°53’00"E) in Baoshan city, Yunnan, China. Most of the diseased spots occurred at the tips and margins of the old pepper leaves. Lesions were grayish brown or pale white with a slight yellow halo, concentric whorl black dots or scattered black dots were observed on the leaves spots sometimes (Fig. 1). Five symptomatic leaves from different parts of the field were sampled for pathogen isolation. Lesion tissues removed from the border between symptomatic and healthy tissue were surface sterilized in 75% ethanol, then air-dried, plated on potato dextrose agar medium plates (PDA), and incubated in a 12-h photoperiod at 28℃. Similar fungal colonies developed from all plated tissues after 5 days. And five isolates from different leaves (one isolate per leaf) were sub-cultured using the single-spore method. The colonies appeared white, cottony, aerial mycelium dense and slow-growing (mean 1.01 mm day–1) on PDA plates in 6 days. Conidia were short-cylindric, straight, sometimes slightly constricted near the center, ends broadly rounded, measuring 11.05 to 14.43 × 3.78 to 6.08 µm (average = 12.03 × 5.48 µm, n=200). Appressoria were single, subglobose to elliptic, light brown to dark black. Among them, genomic DNA of two isolates (21HJ0301-1 and 21HJ0301-2) were extracted from mycelium and used as a template for molecular identification. The internal transcribed spacer (ITS) region of ribosomal DNA, and partial sequence of chitin synthase (CHS-1), actin (ACT) and glyceraldehydes-3-phosphate dehydrogenase (GAPDH) gene regions were amplified with primer pairs ITS1/ITS4, CHS-79F/CHS-354R, ACT-512F/ACT-783R, GDF/GDR, respectively (Weir et al. 2012). These four gene sequences were deposited in GenBank (Accession No. MZ725047 and MZ725048 for ITS, MZ733415 and MZ733416 for GAPDH, MZ733408 and MZ733409 for ACT, MZ733422 and MZ733423 for CHS-1). A multilocus phylogenetic analysis performed with the reference sequences revealed that both 21HJ0301-1 and 21HJ0301-2 isolates clustered with C. karstii (Fig.2). Based on morphology and molecular results, isolates were confirmed to be C. karstii. Pathogenicity tests were carried out on potted seedlings in the greenhouse, six healthy leaves per isolate were inoculated with six-day-old cultures of C. karstii mycelial discs of 5 mm in diameter after being wounded with a needle or non-wounded. Control leaves were inoculated with PDA agar. Inoculated plants were incubated under high relative humidity at room temperature. Anthracnose symptoms appeared within 5 days using non-wounded or wounded inoculation methods. All control leaves remained asymptomatic. The fungus was re-isolated from inoculated leaves fulfilling Koch’s postulates, but not on controls. C. karstii has a wide range of hosts, such as rubber tree, tea-oil tree, chili, and some other plants belonging to the family Orchidaceae in China (Cai et al. 2016; Jiang and Li 2018; Diao et al. 2017; Yang et al. 2011). To the best of our knowledge, this is the first report of C. karstii on Piper nigrum in China. This report will help us to recognize the anthracnose disease of Piper nigrum and establish a foundation for future studies on C.karstii to address effective management strategies.