Poplar Allene Oxide Synthase 1 Gene Promoter Drives Rapid and Localized Expression by Wounding

Liang, Haiying and Carlson, John E. and Herr, Joshua R. and Xu, Tao and J. Frost, Christopher and Lei, Bin (2021) Poplar Allene Oxide Synthase 1 Gene Promoter Drives Rapid and Localized Expression by Wounding. Biotechnology Journal International, 25 (5). pp. 16-28. ISSN 2456-7051

[thumbnail of 21-Article Text-39-1-10-20220902.pdf] Text
21-Article Text-39-1-10-20220902.pdf - Published Version

Download (494kB)

Abstract

Promoters play critical roles in controlling the transcription of genes and are important as tools to drive heterologous expression for biotechnological applications. In addition to core transcription factor-binding motifs that assist in the binding of RNA polymerases, there are specific nucleotide sequences in a promoter region to allow regulation of gene expression. The allene oxide synthase (AOS) gene family are cytochrome P450s that are responsive to a variety of environmental stress, making them good candidates for the discovery of inducible promoters. Populus AOS homologs separate phylogenetically into two clades. Based on the 19 promoter motifs with significant abundance differences between the two clades, Clade I AOS genes are likely more responsive to hormones, salt, and pathogen, whereas clade II homologs are likely inducible by water stress. In this study, an upstream promoter from a Clade I poplar AOS encoding gene (AOS1) was cloned and used to drive the expression of a ß-glucuronidase (GUS) gene in Arabidopsis. AOS is an essential enzyme in the lipoxygenase pathway that is responsible for the production of many non-volatile oxylipins in plants, including the jasmonates, which are regulatory phytohormones coordinating a variety of biological and stress response functions. Consistent with AOS transcript expression patterns, we found that the poplar AOS1 promoter drives rapid and localized expression by wounding. The study provides insight on the responsive elements in the poplar AOS promoters, but more importantly identifies a strong wound-inducible and localized promoter for future applications.

Item Type: Article
Subjects: STM Library > Biological Science
Depositing User: Managing Editor
Date Deposited: 25 Mar 2023 12:41
Last Modified: 17 Feb 2024 04:00
URI: http://open.journal4submit.com/id/eprint/196

Actions (login required)

View Item
View Item