Your search keyword '"Xue, Taiqiang"' showing total 2 results

1. The use of mutant and engineered microbial agents for biological control of plant diseases caused by Pythium: Achievements versus challenges.

Author

Chen, Siqiao, Daly, Paul, Zhou, Dongmei, Li, Jingjing, Wang, Xiaoyu, Deng, Sheng, Feng, Hui, Wang, Chunting, Sheikh, Taha Majid Mahmood, Chen, Yifan, Xue, Taiqiang, Cai, Feng, Kubicek, Christian P., Wei, Lihui, and Druzhinina, Irina S.

Abstract

Pythium species are devasting pathogens causing major crop losses, e.g., damping-off in sugar beet caused by Pythium ultimum and root-rot of tomato caused by Pythium aphanidermatum. The use of natural antagonistic microorganisms is a promising environment-friendly approach to control Pythium -caused plant diseases. There are several examples of biocontrol of diseases caused by Pythium species but the application of bioeffectors (biological control agents) is limited for various reasons, including the restricted amount of gene-modification based biotechnological progress. The regulations in many countries prevent genetically modified bioeffectors from being routinely deployed in field conditions. Our two connected aims in this review are (1) to compile and assess achievements in genetic modification of bioeffectors which have been tested for parasitism or antagonism towards a Pythium plant pathogen or biocontrol of a plant disease caused by a Pythium species, and (2) discuss how a better performing bioeffector could be engineered to improve biocontrol of Pythium -caused plant diseases. We focus on the role of seven key mechanisms: cellulases, carbon catabolite de-repression, glycosylation, reactive oxygen species, chitin re-modelling, proteases, and toxic secondary metabolites. Genetic modifications of bioeffectors include gene deletion and overexpression, as well as the replacement of promoter elements to tune the gene expression to the presence of the pathogen. Gene-modifications are limited to fungal and bacterial bioeffectors due to the difficulty of gene modification in oomycete bioeffectors such as Pythium oligandrum. We assess how previous gene modifications could be combined and what other gene modification techniques could be introduced to make improved bioeffectors for Pythium -caused plant diseases. The broad host-range of Pythium spp. suggests engineering improved antagonistic traits of a bioeffector could be more effective than engineering plant-mediated traits i.e. , engineer a bioeffector to antagonise a plant pathogen in common with multiple plant hosts rather than prime each unique plant host. • Bioeffectors of Pythium -caused diseases reviewed in an ecological context. • Seven important mechanisms of biocontrol of Pythium -caused diseases reviewed. • Mechanisms include offensive e.g., cellulases and defensive e.g., wall remodeling. • Several potential routes to stack these mechanisms to engineer a super-bioeffector. [ABSTRACT FROM AUTHOR]

Published

2022

2. Dual-Transcriptomic, Microscopic, and Biocontrol Analyses of the Interaction Between the Bioeffector Pythium oligandrum and the Pythium Soft-Rot of Ginger Pathogen Pythium myriotylum.

Author

Daly, Paul, Chen, Siqiao, Xue, Taiqiang, Li, Jingjing, Sheikh, Taha Majid Mahmood, Zhang, Qimeng, Wang, Xuehai, Zhang, Jinfeng, Fitzpatrick, David A., McGowan, Jamie, Shi, Xiujuan, Deng, Sheng, Jiu, Min, Zhou, Dongmei, Druzhinina, Irina S., and Wei, Lihui

Subjects

PYTHIUM, DOUBLE-strand DNA breaks, GINGER, PHYTOPATHOGENIC microorganisms, DNA repair, BIOLOGICAL pest control agents

Abstract

Biological control is a promising approach to suppress diseases caused by Pythium spp. such as Pythium soft rot of ginger caused by P. myriotylum. Unusually for a single genus, it also includes species that can antagonize Pythium plant pathogens, such as Pythium oligandrum. We investigated if a new isolate of P. oligandrum could antagonize P. myriotylum , what changes occurred in gene expression when P. oligandrum (antagonist) and P. myriotylum (host) interacted, and whether P. oligandrum could control soft-rot of ginger caused by P. myriotylum. An isolate of P. oligandrum , GAQ1, recovered from soil could antagonize P. myriotylum in a plate-based confrontation assay whereby P. myriotylum became non-viable. The loss of viability of P. myriotylum coupled with how P. oligandrum hyphae could coil around and penetrate the hyphae of P. myriotylum , indicated a predatory interaction. We investigated the transcriptional responses of P. myriotylum and P. oligandrum using dual-RNAseq at a stage in the confrontation where similar levels of total transcripts were measured from each species. As part of the transcriptional response of P. myriotylum to the presence of P. oligandrum , genes including a subset of putative Kazal-type protease inhibitors were strongly upregulated along with cellulases, elicitin-like proteins and genes involved in the repair of DNA double-strand breaks. In P. oligandrum , proteases, cellulases, and peroxidases featured prominently in the upregulated genes. The upregulation along with constitutive expression of P. oligandrum proteases appeared to be responded to by the upregulation of putative protease inhibitors from P. myriotylum , suggesting a P. myriotylum defensive strategy. Notwithstanding this P. myriotylum defensive strategy, P. oligandrum had a strong disease control effect on soft-rot of ginger caused by P. myriotylum. The newly isolated strain of P. oligandrum is a promising biocontrol agent for suppressing the soft-rot of ginger. The dual-RNAseq approach highlights responses of P. myriotylum that suggests features of a defensive strategy, and are perhaps another factor that may contribute to the variable success and durability of biological attempts to control diseases caused by Pythium spp. [ABSTRACT FROM AUTHOR]

Published

2021