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Academic Salon (XVI)

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SPEAKER:  Yingnan Hou

Tenure-track Associate Professor, PI

Department of Plant Science, SAB

 

【Selected Publications】

 

  1. Hou, Y., and Ma, W. Natural Host-Induced Gene Silencing Offers New Opportunities to Engineer Disease Resistance. Trends in microbiology (2020).
  2. Hudzik, C., Hou, Y., Ma, W., and Axtell, M.J. Exchange of small regulatory RNAs between plants and their pests. Plant physiology (2020).
  3. Hou, Y., Zhai, Y., Feng, L., Karimi, H.Z., Rutter, B.D., Zeng, L., Choi, D.S., Zhang, B., Gu, W., and Chen, X. A Phytophthora effector suppresses trans-kingdom RNAi to promote disease susceptibility. Cell host & microbe (2019).
  4. Cai, Q., Liang, C., Wang, S., Hou, Y., Gao, L., Liu, L., He, W., Ma, W., Mo, B., and Chen, X. The disease resistance protein SNC1 represses the biogenesis of microRNAs and phased siRNAs. Nature communications (2018).
  5. Hou, Y., and Ma, W. Small RNA and mRNA profiling of Arabidopsis in response to Phytophthora infection and PAMP treatment. Plant Pattern Recognition Receptors (Springer), (2017).
  6. Hou, Y., Guo, X., Cyprys, P., Zhang, Y., Bleckmann, A., Cai, L., Huang, Q., Luo, Y., Gu, H., and Dresselhaus, T. Maternal ENODLs are required for pollen tube reception in Arabidopsis. Current Biology (2016).

 

 

 

TIME 12:40-14:00 May 26, 2021 (Wednesday)

VENUERoom 104, Building B, School of Agriculture and Biology

ORGANIZER:Office of Discipline and Science & Technology, SAB; Young Teachers Association, SAB

 

 

TITTLE:   Trans-species RNAi and Plant Immunity

ABSTRACT: 

Filamentous eukaryotic pathogens, including fungi and oomycetes, are major threats of economically important crops. Most filamentous plant pathogens are biotrophic or hemibiotrophic, engaged in a continuous battle with plant hosts by exchanging active materials to manipulate each other. Oomycetes, such as Phytophthora, are known for secreting a large number of effectors to modulate host immune responses, and accumulating evidence suggests that plant sRNAs can move across species and function as antimicrobial agents against non-viral pathogens. We discovered that plant secondary siRNAs were induced by Phytophthora infection and move into interacting Phytophthora cells. This movement of siRNAs results in decreased expression of Phytophthora transcripts through trans-species RNA interference, thus enhancing plant defense. Therefore, exploiting sRNA transfer mechanisms and engineering siRNA-producing loci could be a useful strategy to engineer crops with improved disease resistance.

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