Heliconia subulata, a New Host of Colletotrichum tropicale Causing Anthracnose in China.

Heliconia subulata is a common ornamental plant, it has been widely planted in southern China for greening parks, roads, and residential areas. H. subulata plants with spots on their leaves were observed in East Coast Wetland Park (18°16'53.37″N, 109°30'19.36″E), Sanya City, Hainan Province, China on Aug. 31, 2023. The symptoms of the leaves are irregular gray-white, spots, that develop into brown and black, with yellow halos at the disease-health junction. Following an on-the-spot investigation, it was found that the incidence of the disease was 40 to 50%. The leaves were disinfected with 70% ethanol for 1 min, rinsed with sterile water 3 times, disinfected for 1 min with 0.1% HgCl2, rinsed with sterile water 3 times, dried, put on potato dextrose agar (PDA) and incubated at 28℃ for 7 days. The red conidia pile was selected from the culture, dispersed in sterile water and diluted to 20 µL containing 1 to 2 conidia. After absorbing 20 µL spore suspension for many times and inoculating it on the new PDA plate, five pure cultures of single spore, J-1-1 to J-1-5, were obtained. After 7 days of growth, the colonies were grayish aerial mycelium on the front and light orange conidia on the reverse. The white aerial mycelia, conidia, acervulus, and appressorium were observed (Supplementary Fig. S1). The morphological characteristics showed that the isolate had the same characteristics as the previously described Colletotrichum spp. (Wang et al. 2021). The genomic DNA of isolates J-1-1 and J-1-5 were extracted by Fungal DNA Kit (OMEGA bio-tek, Guangzhou, China). The internal transcribed spacer (ITS), glyceraldehyde-3-phosphate dehydrogenase (GADPH), and ß-tubulin 2 genes (TUB2) were amplified by primers ITS1/ITS4, GDF/GDR, and Bt2a/Bt2b, respectively (Weir et al. 2012). Based on sequencing and gene sequence alignment analysis, it was found that the consistency between the ITS sequences of isolates J-1-1 and J-1-5 was 99.82%. The consistency between GADPH and TUB2 sequences was 100%. The gene sequences of isolates J-1-1 and J-1-5 were submitted to GenBank with accession numbers PP455510/PP455511 (ITS), PP510210/PP510211 (GADPH) and PP510212/PP510213 (TUB2) respectively. Based on the BLAST analysis, the three sequences were more than 99% identical to those of the C. tropicale strain FC1 (ITS: MT192648, GAPDH: MT155819, TUB2: MT199874; Duan et al. 2022). A phylogenetic tree was constructed by MEGA 11 based on the ITS, GADPH, and TUB2 gene sequence by the maximum-likelihood method. The results showed that the isolates J-1-1 and J-1-5 were clustered with C. tropicale CBS:124949 (Supplementary Fig. S2). Based on morphological and molecular biological analysis, two isolates were identified as C. tropicale. To further test the pathogenicity of isolates J-1-1 and J-1-5, spore suspensions (1×106 conidia/mL) were prepared and 20 µL spore suspensions were inoculated on the leaves of healthy H. subulata potted plants stabbed with sterile toothpicks. Three leaves were inoculated in each treatment, and sterile water was inoculated as a control. The treated plants were placed in an incubator with a temperature of 28℃, relative humidity of 90%, and light/dark (12h/12h). After 15 days, the spore suspension treatment showed the same symptoms as the naturally diseased H. subulata plants in the field, but the leaves treated with sterile water were not infected (Supplementary Fig. S1). The morphology of the isolates obtained from diseased leaves was the same as that of isolates J-1-1 and J-1-5 on the PDA plate. To our knowledge, this is the first report of H. subulata, a new host of C. tropicale causing anthracnose in China.

First Report of 16SrII Group Related Phytoplasma Associated with Witches'-broom Disease on Cowpea (Vigna unguiculata) in Hainan Province, China.

Cowpea (Vigna unguiculata L.), a significant vegetable crop in China, holds particular prominence in the tropical island of Hainan. This region serves as the primary production area for the winter cultivation of cowpea. Phytoplasmas are an idiopathic parasitic pathogen and cannot be cultured in vitro. It is mainly transmitted by the insect vectors with the piercing and sucking mouthparts, such as leafhoppers, plant hoppers, and psyllids. (Kumari et al. 2019). On September 11, 2023, typical characteristics of phytoplasma diseases on cowpeas were observed in the experimental base of Hainan Academy of Agricultural Sciences (20°0'38.6964″N, 110°21'35.4024″E, Haikou City, Hainan Province, China), including reduced leaf size, chlorosis, and the development of broom-like branch deformities reminiscent, as depicted in Figure 1. At the same time, we found a large number of leafhoppers near the diseased plants, and we speculated that leafhoppers are the insect carriers that spread the disease. Following an on-site investigation, it was determined that the disease incidence ranges from 10% to 15%, leading to a consequential decrease of about 10% in yield, which is a potential disease that seriously threatens the cowpea industry in Hainan. Ten disease and healthy samples were meticulously collected and subsequently preserved at -80°C within the laboratory refrigerator. Three disease samples denoted as HNNKY-1, HNNKY-2, and HNNKY-3, were randomly chosen, and total DNA extraction was carried out employing the NuClean Plant Genomic DNA Kit (CWBIO, Taizhou, China), while three healthy samples were randomly selected as control. The 16S rRNA gene was amplified by PCR using the primer pairs P1/P7 (Schneider et al. 1995) and R16F2n / R16R2 (Lee et al. 1993) and the secA gene was amplified by PCR using the primer pairs secAfor1/secArev3 (Hodgetts et al. 2008). After agarose gel electrophoresis analysis, no DNA fragments were observed in the healthy leaf samples, whereas all three disease samples yielded amplification products. The PCR products were subsequently sequenced by Hainan Nanshan Biotech Co., Ltd., Haikou, China. After sequence analysis, it was found that the 16S rRNA gene and secA gene sequences HNNKY-1, HNNKY-2, and HNNKY-3 were identical to each other. We selected two gene sequences of strain HNNKY-3 to submission to the GenBank database, The length of the 16S rRNA gene sequence is 1193 base pairs, identified by the accession number OR666421, while the secA gene sequence is 825 base pairs in length, associated with the accession number OR661282. The phytoplasma strain HNNKY-3 was named 'Vigna unguiculata' witches'-broom phytoplasma. A BLAST analysis of the 16S rRNA gene revealed that strain HNNKY-3 displayed a 100% sequence match with 'Emilia sonchifolia' witches'-broom phytoplasma (MT420682), Peanut witches'-broom phytoplasma (OR239773), and 'Raphanus sativus' witches'-broom phytoplasma (OK491387). All of these phytoplasmas were classified within the 16SrII group. Based on the BLAST analysis of partial secA gene sequences, it was discerned that sequence homogeneity ranged from 99.27% to 99.74% among the studied sequences. These sequences were collectively classified as members of the 16SrII group. In addition, a phylogenetic tree was constructed by MEGA 11 (version 11.0.13) based on the 16Sr RNA gene and secA gene by the neighbor-joining method (Tamura et al. 2004). The results demonstrated the clustering of HNNKY-3 phytoplasma strains within the 16SrII group, as illustrated in Figures 2 and 3. A virtual RFLP analysis based on the 16S rRNA gene fragment of HNNKY-3 was conducted using the interactive online phytoplasma classification tool, iPhyClassifier (Zhao et al. 2009). The results indicated that the phytoplasma strain was the same as the reference pattern of the onion yellows phytoplasma of 16SrII-A (GenBank accession: L33765), and the similarity coefficient was 1.00. To best of our knowledge, this is the inaugural documentation of 16SrII Group-related phytoplasma infecting cowpea in Hainan, China, and lays the groundwork for further research on the dissemination of cowpea phytoplasma disease within China.

First Report of Leaf Spot Caused by Phyllosticta capitalensis on Alpinia oxyphylla Miq. in China.

Alpinia oxyphylla Miq. is mainly distributed in Hainan, Guangdong and Guangxi provinces of China. Between July and August 2021, a leaf spot disease was observed in Ledong, Hainan Province, China (18°70'20.50″ N, 109°25'25.47″E) on A.oxyphylla. The incidence of infected leaves ranged from 8% to 10%, and the incidence rate of infected plants was about 50%. Symptoms appeared as primary yellow-brown withered spots on the diseased leaves, which further developed into irregular red-brown spots. The center of the lesions was gray-black, and the tissue was irregularly necrotic, ruptured or perforated, and there were yellow chlorotic halos around the edges of the lesions (Figure 1A). Tissues 5 mm in diameter were taken from the junction of diseased and healthy tissue for pathogen isolation, Successively, a total of 8 isolates were obtained from the affected leaves. Three single spore isolates (YZ-HN-001, YZ-HN-043 and YZ-HN-051) were obtained and confirmed to be identical based on morphological characteristics. Therefore, the representative isolate YZ-HN-001 was selected for morphological and molecular identification. On Potato Dextrose Agar(PDA), the colony was gray-white at first and gradually turned dark green to dark brown with lead gray on the back, growth was slow, and mycelium was short and dense (Figure 1B and Figure 1C). Pycnidia were epiphyllous, globose, brown (about 120-140 µm in diameter), and conidia were elliptical, colorless, single celled and smooth (8-12×4-7 µm) (Figure 1D). Molecular identification was performed by partially sequencing the internal transcribed spacer gene (ITS), 18S rRNA gene and the actin gene (ACT) by using the primers ITS1/ITS4 (White et al. 1990), EF4/Fungi5 (Khodaparase et al. 2005) and ACT-512F/ACT-783R (Carbone and Kohn. 1999). The sequences of the amplified fragments were deposited in GenBank, the ITS sequence (ON005130, 616 bp) showed 100% identity with Phyllosticta capitalensis strain CGMCC3.14345 (JN791605.1), the 18S rRNA sequence (ON005129, 541 bp) showed 99% identity with P. capitalensis isolate MUCC0029 (AB454185.1) and the ACT sequence (ON049348, 251 bp) showed 100% identity with P. capitalensis strain DZSN202005-2 (MW533248.1). A phylogenetic analysis was conducted in MEGA X using the neighbor-joining method and showed that isolate YZ-HN-001 clustered together with P. capitalensis (Figure 2). Based on the above morphological and molecular characteristics, the isolate was determined to be P. capitalensis. Pathogenicity tests were conducted in three replicates by inoculating surface-sterilized leaves of A. oxyphylla. The leaves were wounded and inoculated with colonized PDA plugs (5×5 mm) from 15-day-old cultures. Control leaves wounded in the same way and were inoculated with sterile PDA plugs (5×5 mm). Leaves were moisturized by spraying with sterile water every three days. After 20 days at room temperature (23 to 28℃), similar symptoms were observed in the inoculated leaves as in the field (Figure 1E), but no symptoms were observed on the control leaves (Figure 1F). The same P. capitalensis was reisolated in the inoculated leaves, confirming Koch's postulates. Phyllosticta capitalensis has been reported to cause leaf spots or black spots on various host plants around the world (Wikee et al. 2013), including on oil palm (Nasehi et al. 2020), tea plant (Cheng et al. 2019 ), and castor (Tang et al. 2020). Nevertheless, to our knowledge, this is the first report of leaf spot caused by P. capitalensis on A. oxyphylla worldwide.

Fosthiazate inhibits root-knot disease and alters rhizosphere microbiome of Cucumis melo var. saccharinus.

Root-knot nematodes especially Meloidogyne spp. are considered as most destructive obligate parasites that substantially reduce crop yield and quality. Fosthiazate is an efficient organothiophosphate chemical with nematicidal activity against Meloidogyne spp. The present study aimed to analyze the efficacy of fosthiazate against root-knot disease in Cucumis melo var. saccharinus and its potential effects on rhizosphere microbiome and metabolites. The fosthiazate (40%) was applied two times by spraying on the day of transplanting and during the pollination period (after 31 days). Samples from treatment (fosthiazate 40%: MF) and control groups (untreated plants; MCK) were analysed through metagenomic and metabolomic profiling of rhizospheres. Results revealed that root-knot index of the MF group (9.26 ± 1.28) was significantly (p < 0.05) lower than the MCK group (22.06 ± 0.71) with a control effect of 57.85% after 31 days of the first spray, whereas fosthiazate efficacy reduced to 31.87% after 38 days of second application with significantly (p < 0.05) different root-knot index values (MF: 56 ± 1.43 and; MCK: 82.26 ± 3.87). However, Cucumis melo var. saccharinus fruit yield in both groups (MCK: 21.1 ± 0.9 and MF: 21.53 ± 0.85) showed no differences (p > 0.05). Metagenomic profiling revealed Proteobacteria, Acidobacteriota, and Firmicutes as predominant phyla and Bacillus, Sphingomonas, and Acidibacter as predominant genera in rhizosphere soil samples of both MF and MCK groups. Further, a t-test revealed higher differential enrichment of Firmicutes at phylum level and Bacillus at genus level in MF than MCK. Metabolomic profiling of rhizospheric soil revealed a total of six differential metabolites (p < 0.05), four of them (Sucrose, Hexaonic acid 1, (Z)-9-Octadecenamide 1, and Hexadecanamide) were up-regulated in MF group, whereas two of them (2,3,4-Trihydroxy-3-(Hydroxymethyl) Butanol and Sulfurous acid, 2, ethylhexylundecyl ester) were down-regulated in CK group. Our study concluded that fosthiazate exhibits a better control over the rook-knot disease in the short term and resulted in trackable changes in rhizosphere microbiome and metabolome.

Quorum-sensing contributes to virulence, twitching motility, seed attachment and biofilm formation in the wild type strain Aac-5 of Acidovorax citrulli.

Acidovorax citrulli is a seed-borne pathogen causing bacterial fruit blotch of cucurbits including melon and watermelon. We investigated the roles of quorum sensing in the wild-type group II strain Aac-5 of A. citrulli by generating aacR and aacI knockout mutants and their complementation strains. We found that twitching motility and virulence were reduced, but biofilm formation and seed attachment were increased significantly in the two mutants as compared to the wild type strain. Deletion of aacR and aacI, however, had no effect on swimming motility and polar flagella formation of Aac-5. Furthermore, deletion of aacR resulted in reduced gene expression of hrpE, hrcN and pilT, while deletion of aacI affected only the expression of hrpE and pilT, not hrcN.