First Report of Rugonectria rugulosa Causing Dieback of Prunus salicina "Banbianhong" in China.

Banbianhong (Prunus salicina) is a valuable fruit crop cultivated in the southwestern regions of China for its high quality fruit and substantial economic benefits (Wang et al. 2021). In July 2023, dieback disease was observed in Banbianhong in Suijiang County, Zhaotong, Yunnan Province, with an incidence of up to 10%. The disease caused brownish nodules in the cortex of the infected plant, leading to dry cracking, and exposing grayish-brown xylem, which caused the plant to wither and die. Upon longitudinal cutting of twigs, lesions were evident and characterized by browning and necrosis of the cauline bundle and pith within the tissue. The diseased tissues were sectioned into 2 mm2 pieces and surface disinfected with 70% ethanol and 1% NaClO and rinsed with double distilled water. The tissue fragments were plated onto potato dextrose agar (PDA), and incubated for 7 days at 28°C. A total of six isolates were obtained, and two isolates (WG2-1 and WG2-3) were selected for morphological, molecular identification and pathogenicity testing. On PDA, the colony diameter of WG2-1 and WG2-3 were recorded as 5.50±0.56 mm/day and 6.08±0.37 mm/day, respectively. The microconidia of both isolates were zero-septate, smooth, greenish, subglobose to ellipsoidal, and measured 5 to 10 × 1.5 to 3 µm (n = 50) in size. However, macroconidia were not observed. The internal transcribed spacer rDNA (ITS) and ß-tubulin 2 (TUB2) genes were amplified using the primer pairs ITS1/4 (White et al. 1989) and Bt2a/2b (Glass and Donaldson 1995). BLAST analysis of the obtained ITS sequences (accession Nos. PP581792) and TUB2 sequences (accession Nos. PP2815212) sequences showed 100% identity with Rugonectria rugulosa (accession nos. MG991753 for ITS and KM232007 for TUB2). Based on these characteristics, the isolates have been identified as R. rugulosa and have been deposited in the Agricultural Environment and Resource Research Institute plant pathogen lab at Yunnan Academy of Agricultural Sciences. In this study, Pathogenicity tests were conducted on one-year-old Prunus salicina "Banbianhong" twigs to complete Koch's postulates. The twigs were wounded using a 1-mm sterile corking borer and 14-day-old mycelium plugs of isolate (WG2-1) were inoculated and covered with sealing films. Sterile PDA plugs were placed into the wounds of control twigs. Eighteen healthy twigs were inoculated with isolates or PDA plugs (n = 6 twigs/treatment, the size of the twigs: 8 cm length and diameter about 0.7 cm, with three replications) and were placed in a closed sterile tray with the wet filter papers in a thermostatic incubator (type, HYC-260) at 28°C, respectively. The twigs inoculated with the isolates exhibited brown lesions site of inoculation, whereas the controls remained asymptomatic. R. rugulosa was successfully reisolated from the lesions but not from these control wounds and was identified by the methods described above. R. rugulosa has been reported to be associated with the die-back disease of Falcataria moluccana in China (Wang et al. 2019). The occurrence and spread of R. rugulosa in growing areas of Prunus salicina "Banbianhong" in Suijiang county have caused severe economic losses. To our knowledge, this is the first report of the die-back disease of Prunus salicina "Banbianhong" caused by R. rugulosa. These results confirm the pathogenicity of R. rugulosa in Prunus salicina "Banbianhong" and provide valuable insights for developing disease management and prevention strategies.

Identification of two novel poleroviruses and the occurrence of Tobacco bushy top disease causal agents in natural plants.

Tobacco bushy top disease (TBTD) is a devastating tobacco disease in the southwestern region of China. TBTD in the Yunnan Province is often caused by co-infections of several plant viruses: tobacco bushy top virus (TBTV), tobacco vein distorting virus (TVDV), tobacco bushy top virus satellite RNA (TBTVsatRNA) and tobacco vein distorting virus-associated RNA (TVDVaRNA). Through this study, two new poleroviruses were identified in two TBTD symptomatic tobacco plants and these two novel viruses are tentatively named as tobacco polerovirus 1 (TPV1) and tobacco polerovirus 2 (TPV2), respectively. Analyses of 244 tobacco samples collected from tobacco fields in the Yunnan Province through RT-PCR showed that a total of 80 samples were infected with TPV1 and/or TPV2, and the infection rates of TPV1 and TPV2 were 8.61% and 29.51%, respectively. Thirty-three TPV1 and/or TPV2-infected tobacco samples were selected for further test for TBTV, TVDV, TBTVsatRNA and TVDVaRNA infections. The results showed that many TPV1 and/or TPV2-infected plants were also infected with two or more other assayed viruses. In this study, we also surveyed TBTV, TVDV, TBTVsatRNA and TVDVaRNA infections in a total of 1713 leaf samples collected from field plants belonging to 29 plant species in 13 plant families and from 11 provinces/autonomous regions in China. TVDV had the highest infection rates of 37.5%, while TVDVaRNA, TBTV and TBTVsatRNA were found to be at 23.0%, 12.4% and 8.1%, respectively. In addition, TVDV, TBTV, TBTVsatRNA and TVDVaRNA were firstly detected of co-infection on 10 plants such as broad bean, pea, oilseed rape, pumpkin, tomato, crofton weed etc., and 1 to 4 of the TBTD causal agents were present in the samples collected from Guizhou, Hainan, Henan, Liaoning, Inner mongolia and Tibet autonomous regions. The results indicated that TBTD causal agents are expanding its host range and posing a risk to other crop in the field.

The occurrence of Pea enation mosaic virus 1 and Pea enation mosaic virus 2 from disease-affected pea fields in China.

Pea (Pisum sativum L.) is an economically important legume crop that is commonly used as dry beans, fresh peas, pods and shoots (Guo et al. 2009). Pea enation mosaic is an important virus disease of pea caused by two viruses in an obligate symbiosis, pea enation mosaic virus 1 (PEMV-1, Enamovirus, Luteoviridae) and pea enation mosaic virus 2 (PEMV-2, Umbravirus, Tombusviridae) (Hema et al. 2014). In November 2019, foliar yellow mosaic and vein enations symptoms were observed from pea plants in five fields of Honghe autonomous prefecture, Yunnan province, China. Incidence of symptomatic plants ranged from 20 to 40% and was distributed in both small and large fields. Leaves with typical virus-like symptoms were collected from five symptomatic pea plants in two fields and used for total RNA extraction. The five extracts of equimolar quantities were pooled into a sample and subjected to High Throughput Sequencing (HTS) by Illumina HiSeq system. Analyses of raw RNA reads were performed using CLC Genomics Workbench 12 (Qiagen). A total of 60,009,746 RNA reads were obtained from the sample, and de novo assembly of the reads using the CLC Genomics generated 88,105 contigs. BLASTN searches revealed the presence of contigs with high similarities to PEMV-1, PEMV-2, Pea seed-borne mosaic virus, and Bean yellow mosaic virus. To confirm the presence of PEMV-1 and PEMV-2 in the samples, two virus-specific primer pairs were designed based on the contig sequences obtained by HTS in this study. Primer pairs PEMV-1F/PEMV-1R (5'-ATGCCGACTAGATCGAAATC-3'/5'-TCAGAGGGAGGCATTCATTA-3') that flank the cp gene of PEMV-1 and PEMV-2F/PEMV-2R (5'-ATGACGATAATCATTAATG-3'/5'-TCACCCGTAGTGAGAGGCA-3') that target the ORF3 region of PEMV-2 were used to amplify the two viruses in RT-PCR. DNA fragments of the expected sizes (PEMV-1, 570 bp; PEMV-2, 693 bp) were amplified from all five samples. The RT-PCR products were cloned and sequenced. Sequence analysis showed that the 570-bp amplicon (MT481989) shared the highest nucleotide sequence identity of 98.95% with PEMV-1 (Z48507), while the 693-bp fragment (MT481990) had the highest nucleotide sequence identity of 97.4% with PEMV-2 isolate JKI (MK948534). One gram of the symptomatic leaves from each of the five plants was homogenized with 5 mL of 0.01 M phosphate-buffered saline (PBS buffer), pH 7.0. Each of the resulted saps was used to inoculate onto five healthy pea seedlings. A total of 25 healthy pea seedlings were inoculated, and 16 inoculated plants developed yellowing and mottling at 10 days post inoculation (dpi); no symptoms were observed on control plants inoculated only with PBS buffer. The formation of the typical enation was observed along the veins of lower side of the symptomatic leaves of the inoculated plants at 30 dpi. PEMV-1 and PEMV-2 infection were confirmed by RT-PCR assays using the specific primer pairs described above. Although the presence of the pea enation mosaic virus complex was suspected in China based on symptomatology (Brunt et al. 1997), to our knowledge, this is the first molecular confirmation of PEMV-1 and PEMV-2 occurrence in China. The co-infection of PEMV-1 and PEMV-2 usually cause severe yield losses; therefore, integration of detection and control measures is important in pea production regions where the two viruses occurred.