Your search keyword '"Qiao-Juan Lai"' showing total 4 results

1. Application-oriented deep learning model for early warning of rice blast in Taiwan

Author

Jie-Hao Ou, Chang-Hsin Kuo, Yea-Fang Wu, Guo-Cih Lin, Miin-Huey Lee, Rong-Kuen Chen, Hau-Ping Chou, Hsin-Yuh Wu, Sheng-Chi Chu, Qiao-Juan Lai, Yi-Chen Tsai, Chun-Chi Lin, Chien-Chih Kuo, Chung-Ta Liao, Yi-Nian Chen, Yen-Wei Chu, and Chi-Yu Chen

Subjects

Computational Theory and Mathematics, Ecology, Applied Mathematics, Ecological Modeling, Modeling and Simulation, Ecology, Evolution, Behavior and Systematics, Computer Science Applications

Published

2023

2. Soil Is Not a Reservoir for Phellinus noxius

Author

Zong-Chi Wu, Shean-Shong Tzean, Heng-An Lin, Isheng J. Tsai, Qiao-Juan Lai, Chia-Lin Chung, Ya-Yun Chang, and Ruey-Fen Liou

Subjects

0106 biological sciences, 0301 basic medicine, Phellinus noxius, Rhizosphere, Host (biology), Plant Science, Biology, 01 natural sciences, 03 medical and health sciences, medicine.drug_formulation_ingredient, 030104 developmental biology, Botany, medicine, Root rot, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Phellinus noxius causes brown root rot (BRR) of diverse trees. Basidiospores and diseased host tissues have been recognized as important sources of P. noxius inoculum. This study aimed to understand whether P. noxius could occur or survive in soil without host tissues in the natural environment. Soil was sampled before and after the removal of diseased trees at eight BRR infection sites (total of 44 samples). No P. noxius colonies were recovered in soil plating assays, suggesting that no or little viable P. noxius resided in the soil. To know whether P. noxius could disseminate from decayed roots to the surrounding soil, rhizosphere and non-rhizosphere soils were sampled from another two infection sites. Although P. noxius DNA was detectable with specific primers, no P. noxius could be isolated, even from the rhizosphere soils around decayed roots covered with P. noxius mycelial mats. The association between viable P. noxius and the presence of its DNA was also investigated using field soil mixed with P. noxius arthrospores. After P. noxius was exterminated by flooding or fumigation treatment, its DNA remained detectable for a few weeks. The potential of onsite soil as an inoculum was tested using the highly susceptible loquat (Eriobotrya japonica). Loquats replanted in an infection site that had been cleaned up by simply removing the diseased stump and visible residual roots remained healthy for a year. Taken together, P. noxius is not a soilborne pathogen, and diseased host tissues should be the focus of field sanitation and detection for BRR.

Published

2020

3. Soil Is Not a Reservoir for

Author

Zong-Chi, Wu, Ya-Yun, Chang, Qiao-Juan, Lai, Heng-An, Lin, Shean-Shong, Tzean, Ruey-Fen, Liou, Isheng J, Tsai, and Chia-Lin, Chung

Subjects

Soil, Basidiomycota, Rhizosphere, Plant Diseases, Trees

Published

2019

4. First Report of Xanthomonas fragariae Causing Angular Leaf Spot on Strawberry (Fragaria × ananassa) in Taiwan

Author

Hung-Yi Wu, Nai-Chun Lin, Pei-Che Chung, Qiao-Juan Lai, Yi-Mei Wu, and Chia-Lin Chung

Subjects

Horticulture, Bacterial disease, biology, Spots, Inoculation, Leaf spot, Plant Science, PEST analysis, Cultivar, biology.organism_classification, Fragaria, Agronomy and Crop Science, Xanthomonas fragariae

Abstract

Angular leaf spot of strawberry, considered an A2 quarantine pest by the European and Mediterranean Plant Protection Organization (EPPO 2019), is an important bacterial disease in many regions. Since 2017, symptoms similar to angular leaf spot were observed in several strawberry cultivars including 'Taoyuan No. 1' and 'Xiang-Shui'. Early symptoms were angular, water-soaked lesions on the abaxial leaf surface, and later, reddish-brown irregular spots and coalesced lesions developed on the adaxial surface. In the humid conditions, sticky bacterial ooze exuding from lesions was observed. To isolate the causal agent, leaves showing water-soaked lesions were surface sterilized, cut into small pieces and soaked in 5 ml sterile water for at least 15 min. The supernatant from the cut-up pieces was serially diluted followed by spreading on sucrose peptone agar (SPA) (Hayward 1960). After incubating at 20°C for 4-5 days, single colonies grown on SPA were transferred to a new SPA plate and cultured at 20°C until colonies appeared. The yellow, glossy and mucoid colonies, which resembled the colony morphology of Xanthomonas fragariae, were selected as candidates for further confirmation. First, bacterial DNA of four candidate isolates, B001, B003 and B005 from Miaoli County and B004 from Taoyuan City, was PCR amplified with X. fragariae-specific primers: XF9/XF12 (Roberts et al. 1996) and 245A/B and 295A/B (Pooler et al. 1996). All four isolates could be detected by XF9/XF12 primer. Furthermore, isolates B003 and B004 could be detected by both 245A/B and 295A/B primers, while B001 and B005 could be detected by 295A/B only. Next, DNA gyrase subunit B (gyrB) was PCR amplified with the primers XgyrB1F/XgyrB1R (Young et al. 2008). The gyrB sequences of these four isolates were deposited in GenBank with accession numbers MT754942 to MT754945. The gyrB phylogenetic tree was constructed based on Bayesian inference analysis and maximum likelihood analysis. The gyrB sequences of the four isolates from Taiwan clustered in the clade containing the type strain of X. fragariae ICMP5715, indicating that they belong to X. fragariae. B001 and B005 formed a sub-group separated from B003 and B004, suggesting genetic differences between these isolates. To fulfill Koch's postulates, the abaxial surface of strawberry leaves were syringe infiltrated (KJP Silva et al., 2017) or wounded inoculated (Wang et al., 2017) with bacterial suspensions (final OD600 = 1.0-2.0) prepared from colonies of B001 and B003 washed from SPA plates. Inoculated plants were enclosed in a plastic bag (> 90% RH) at 25/20°C (day/night) under a 12-h/12-h photoperiod. After 7-14 days, water-soaked lesions similar to those observed in the field were developed on all inoculated leaves. The bacteria were successfully re-isolated from lesions of inoculated leaves and confirmed by specific primers XF9/XF12, 245A/B and 295A/B. We also found that the disease commonly occurs in the strawberry fields/nurseries with sprinkler irrigation during winter or early spring, and was particularly serious in the windward side or near riverside. To our knowledge, this is the first report of X. fragariae causing angular leaf spot on strawberry in Taiwan. Currently, the disease only occurs severely in certain regions, but establishment of effective management strategies will be needed to prevent spreading of this disease and potential economic loss in the future.

Published

2021