Awards Nomination 20+ Million Readerbase
Indexed In
  • Open J Gate
  • Genamics JournalSeek
  • Academic Keys
  • JournalTOCs
  • CiteFactor
  • Ulrich's Periodicals Directory
  • Access to Global Online Research in Agriculture (AGORA)
  • Electronic Journals Library
  • Centre for Agriculture and Biosciences International (CABI)
  • RefSeek
  • Directory of Research Journal Indexing (DRJI)
  • Hamdard University
  • EBSCO A-Z
  • OCLC- WorldCat
  • Scholarsteer
  • SWB online catalog
  • Virtual Library of Biology (vifabio)
  • Publons
  • Geneva Foundation for Medical Education and Research
  • Euro Pub
  • Google Scholar
Share This Page
Journal Flyer
Journal of Plant Pathology & Microbiology
Functional identification of homeodomain leucine zipper 1 (AtHLZ1) as a regulator of abscisic acid signaling pathway in Arabidopsis thaliana
8th World Congress on Plant Genomics and Plant Science
August 10-11, 2018 Osaka, Japan

Ga Yun Jeong

Chonnam National University, South Korea

Posters & Accepted Abstracts: J Plant Pathol Microbiol

Abstract:

The phytohormone Abscisic Acid (ABA) is the major component of abiotic stress tolerance in plants and coordinates a complex regulatory network enabling plants to cope with the stress. The precise roles of the homeodomain leucine zipper family of transcription regulator in plant stress are largely unclear. Here, we characterize the biological function of the AtHLZ1 Arabidopsis thaliana homeodomain leucine zipper-type: In ABA and dehydration responses. The expression of AtHLZ1 was strongly induced by ABA and osmotic stress. AtHLZ1 RNAi lines resulted in increased sensitivity to ABA and dehydration stress during seed germination and the cotyledon greening process. In contrast, The AtHLZ1-overexpressing transgenic plants were less sensitive to ABA and osmotic stress compared to Wild Type (WT). Interestingly, in the presence of ABA, the transcript levels of ABA receptor Pyrabactin Resistance-like 4 (PYL4) and PYL7 genes were enhanced reduction in AtHLZ1- overexpressing transgenic plants rather than in the WT and AtHLZ1 mutant. Thus, AtHLZ1 is involved in ABA and osmotic stress response through the ABA-dependent signaling pathway. The data show that AtHLZ1 is an important regulator in response to both ABA and dehydration stress in Arabidopsis.

Biography :

Ga Yun Jeong is fourth year student in Department of Applied biology, Chonnam National University of South Korea. She is studying in plant biotechnology research at the Cheol Soo Kim’s lab. She is interested in ABA and dehydration stress in Arabidopsis.

E-mail: gayun0331@naver.com