First Report of Bayberry Leaf Blight Caused by Pestalotiopsis kenyana in Zhejiang Province, China.

Weizhi Xun and Changwang Wu contributed equally to this work In October 2020, bayberry (Myrica rubra (Lour.) S. et Zucc.) leaves that beginning to wither were collected in Wencheng County (N27°50', E120°03'). In the county, 4,120 ha of bayberry were planted, of which 58% were affected by the disease, and the severity of leaf disease per plant was 5 to25%. Bayberry leaves leaves were intensely green at first, then gradually turned yellow and brown,and completely withered. The leaves did not fall off at the beginning of the symptoms, but did fall after 1 to 2 months. To identify the pathogen, 50 diseased leaves with typical symptoms were collected from 10 diseased trees. Leaves with necrotic-tissue were firstly washed with sterilized water, and then tissue at the disease-/ healthy-tissuejunction removed with sterile surgical scissors. The tissues were soaked in 75% ethanol for 30 s, followed by 5% sodium hypochlorite solution for 3 to 4 min, rinsed with sterilized water 4 times, and placed on sterilized filter paper. The tissue was placed on PDA medium and cultured in an incubator at 25℃ (Nouri et al. 2019). After the colonies grew around the tissue, mycelia with the same morphology was selected and placed on fresh PDA. A pure culture of the pathogen was obtained after repeating the last process several times. The isolatedcolonies were white, with a round edge and a light-yellow back. Conidia were straight or slightly curved, with 3 to 4 septations. The internal transcribed spacer (ITS) regin translation elongation factor 1-α gene (TEF1-α), and beta-tubulin gene (ß-TUB)(Chaiwan et al. 2020; Li et al. 2021; Chen et al. 2020; Chen et al. 2018) of the two strains were amplified and sequenced, and the sequences were uploaded to Gen bank (GenBank accession number.ACCC 35162: ITS OP891011, TEF1-α OP903533, ß-TUB OP903531; ACCC 35163: ITS OP891012, ß-TUB OP903534, TEF1-α OP903532). BLAST alignment indicated that the ITS sequence of strain ACCC 35162 had 100% identity with NR_147549.1, the TEF sequence had 100% identity with MT552449.1, and the TUB sequence had 99.87% identity with KX895323.1; the ITS sequence of strain ACCC 35163 had 100% identity with NR_147549.1, the TEF sequence had 100% identity with MT552449.1, and the TUB sequence had 99.86% identity with KX895323.1. A Phylogenetic tree using maximum likelihood/rapid bootstrapping run on XSEDE based on the above three sequences inferred that the two strains were identical to P. kenyana (Miller et al. 2010). The strain was preserved in the Agricultural Culture Collection of China (Preservation numbers: ACCC 35162, ACCC 35163). Following Koch's rule, six healthy plants leaves were inoculated with conidial suspensions (106 conidia mL-1) and mycelial plugs (5 mm)，and then placed in an artificial climate chamber (25℃, 90% humidity, 16-h light), sterile PDA and sterile water were used as blank controls. The same treatment was applied to fresh bayberry leaves under laboratory conditions, and brown spots were observed after three days. There were no symptoms in the control group. The experimental symptoms were similar to those in the field. Using the previous method, the same fungus was reisolated from the diseased leaves and again identified as P. kenyana. As far as we know, this is the first report causing disease on P. kenyana infecting bayberry in China, this disease seriously affected the yield and quality of bayberry and caused economic losses to farmers.

First Report of Alternaria alternata Causing White Leaf Spot on Allium tuberosum in China.

Puding County is the major Allium tuberosum growing area in Guizhou Province of China. In 2019, white leaf spots were observed on Allium tuberosum in Puding County (26.31°N, 105.64°E). The white spots, ranging from elliptic to irregular in shape, first appeared on leaf tips. With disease aggravation, spots gradually coalesced, forming necrotic patches with yellow margins causing leaf necrosis; sometimes there was gray mold on dead leaves. The incidence of the diseased leaf rate was estimated to be 27-48%. To identify the pathogenic agent, 150 leaf tissues (5 mm × 5 mm) were obtained from disease-healthy junctions of 50 diseased leaves. Leaf tissues were disinfected in 75% ethanol for 30 s, soaked in 0.5% sodium hypochlorite for 5 min, and flushed three times with sterile water, before being placed on potato dextrose agar (PDA) in the dark at 25 °C. When colonies appeared, the mycelial tips were picked and placed on new PDA. Purified fungus was obtained after repeating this last step several times. The colonies were grayish-green with white round margins. Conidiophores (2.7-4.5 µm × 27-81 µm) were brown, straight, or flexuous with branches and septa. Conidia (8-34 µm × 5-16 µm) were brown, with 0-5 transverse septa and 0-4 longitudinal septa. The 18S nuclear ribosomal DNA (nrDNA; SSU), 28S nrDNA (LSU), RNA polymerase II second largest subunit (RPB2), internal transcribed spacer (ITS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and translation elongation factor 1-alpha (TEF-α) (Woudenberg et al. 2013) were amplified and sequenced. The sequences were deposited in GenBank (ITS: OP703616, LSU: OP860684, SSU: OP860685, GAPDH: OP902372, RPB2: OP902373, TEF1-α: OP902374). According to BLAST analysis, the ITS, LSU, GAPDH, RPB2, SSU, and TEF1-α of the straishowed 100% (689 of 731 base pairs; bp), 100% (916 of 938 bp), 100% (579 of 600 bp), 100% (946 of 985 bp), 100% (1093 of 1134 bp), and 100% (240 of 240 bp) sequence identity to those of Alternaria alternata (ITS: LC440581.1, LSU: KX609781.1, GAPDH: MT109295.1, RPB2: MK605900.1, SSU: ON055699.1 and TEF1-α: OM220081.1). A phylogenetic tree was constructed using PAUP4 and the maximum parsimony method with 1000 replicas of bootstrapping for all datasets. According to morphological characteristics and phylogenetic analysis, FJ-1 was identified as Alternaria alternata (Simmons 2007, Woudenberg et al. 2015). The strain was preserved in the Agricultural Culture Collection of China (preservation number: ACC39969). To determine the pathogenicity of Alternaria alternata against Allium tuberosum, wounded healthy leaves were inoculated with a conidial suspension (106 conidial/mL) and round mycelial plugs (4mm). Sterile agar PDA plugs with no mycelium or sterile water were inoculated as negative controls. Three days later, white spots appeared on the wounded leaves inoculated with mycelial plugs or conidial suspension. However, the symptoms caused by conidial suspensions were weaker than those caused by mycelial plugs. No symptoms were observed in the control group. The experimental symptoms were consistent with the phenomena observed in the field. The same fungus was reisolated from necrotic lesions and identified as Alternaria alternata using the method described above. To our knowledge, this is the first report of Alternaria alternata causing white leaf spots on Allium tuberosum in China, a disease seriously affected the yield and quality of Allium tuberosum and caused economic losses to farmers. Reference: Simmons EG (2007) Alternaria: an identification manual. CBS Fungal Biodiversity Centre, Utrecht, the Netherlands. Woudenberg JHC, Groenewald JZ, Binder M, Crous PW ( 2013) Alternaria redefined. Stud Mycol, 75: 171-212. https://doi.org/10.3114/sim0015. Woudenberg JHC, Seidl MF, Groenewald JZ, Vries M de, Stielow JB, Thomma BPHJ, Crous PW (2015) Alternaria section Alternaria: Species, formae speciales or pathotypes? Stud Mycol, 82:1-21. https://doi.org/10.1016/j.simyco.2015.07.001.

Antifungal Mechanism of Phenazine-1-Carboxylic Acid against Pestalotiopsis kenyana.

Pestalotiopsis sp. is an important class of plant pathogenic fungi that can infect a variety of crops. We have proved the pathogenicity of P. kenyana on bayberry leaves and caused bayberry blight. Phenazine-1-carboxylic acid (PCA) has the characteristics of high efficiency, low toxicity, and environmental friendliness, which can prevent fungal diseases on a variety of crops. In this study, the effect of PCA on the morphological, physiological, and molecular characteristics of P. kenyana has been investigated, and the potential antifungal mechanism of PCA against P. kenyana was also explored. We applied PCA on P. kenyana in vitro and in vivo to determine its inhibitory effect on PCA. It was found that PCA was highly efficient against P. kenyana, with EC50 around 2.32 µg/mL, and the in vivo effect was 57% at 14 µg/mL. The mechanism of PCA was preliminarily explored by transcriptomics technology. The results showed that after the treatment of PCA, 3613 differential genes were found, focusing on redox processes and various metabolic pathways. In addition, it can also cause mycelial development malformation, damage cell membranes, reduce mitochondrial membrane potential, and increase ROS levels. This result expanded the potential agricultural application of PCA and revealed the possible mechanism against P. kenyana.

Field Control Effect and Initial Mechanism: A Study of Isobavachalcone against Blister Blight Disease.

Blister blight (BB) disease is caused by the obligate biotrophic fungal pathogen Exobasidium vexans Massee and seriously affects the yield and quality of Camellia sinensis. The use of chemical pesticides on tea leaves substantially increases the toxic risks of tea consumption. Botanic fungicide isobavachalcone (IBC) has the potential to control fungal diseases on many crops but has not been used on tea plants. In this study, the field control effects of IBC were evaluated by comparison and in combination with natural elicitor chitosan oligosaccharides (COSs) and the chemical pesticide pyraclostrobin (Py), and the preliminary action mode of IBC was also investigated. The bioassay results for IBC or its combination with COSs showed a remarkable control effect against BB (61.72% and 70.46%). IBC, like COSs, could improve the disease resistance of tea plants by enhancing the activity of tea-plant-related defense enzymes, including polyphenol oxidase (PPO), catalase (CAT), phenylalanine aminolase (PAL), peroxidase (POD), superoxide dismutase (SOD), ß-1,3-glucanase (Glu), and chitinase enzymes. The fungal community structure and diversity of the diseased tea leaves were examined using Illumina MiSeq sequencing of the internal transcribed spacer (ITS) region of the ribosomal rDNA genes. It was obvious that IBC could significantly alter the species' richness and the diversity of the fungal community in affected plant sites. This study broadens the application range of IBC and provides an important strategy for the control of BB disease.