Os04g0473900
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Contents
Annotated Information
Function
This gene is regarded as DWA1.Putative DWA1 plays important roles in drought resistance.The DWA1 is composed of seven exons(Fig.1) The open reading fame (7,176 bp) encodes a protein consisting of 2,391 aa in japonica rice, Nipponbare, which is one of the 30 megaproteins (>2,300 aa) predicted in the rice genome[1].
Mutation
(1)There is an insertion of T-DNA in the sixth exon of DWA1 (Fig.1A).
(2)RT-qPCR analysis of DWA1 in WT and mutant tissues(leaf and panicle) indicate that dwa1 is a loss of-function mutant because of no transcript found in the mutant(Fig.1B).
(3)During the course of drought treatment, the mutant wilted and exhibited leaf rolling earlier than the WT.After severe drought treatment followed by rewatering, more than 90% of the WT plants survive, whereas the dwa1 mutant plants are almost dead(Fig.1C and D).
(4)Water loss rate of mutant is faster than WT(Fig.1E).
(5)DWA1-functional complementation(DWA1-FC)lines which is inserted the full-length genomic fragment of DWA1 into the dwa1 mutant restore drought resistance(Fig.1F and G).
(6)Plant height at the reproductive stage are also restored in the DWA1-FC lines(Fig.1H).
Expression
(1)qRCR results show that DWA1 expression level is very low and undetectable at the vegetative stages but is relatively high at the reproductive stages(Fig.2A).
(2)Using a GUS reporter gene driven by a DWA1 promoter detects that DWA1 expression is mainly in the mature organs, such as in mature leaves (Fig.2B 1-2), axillary bud (Fig.2B3), young panicle (Fig.2B4),spikelet (Fig.2B5), stem (Fig.2B6), young panicle (Fig.2B7), pistil (Fig.2B8), stamen (Fig.2B9), young embryo (Fig.2B10), SEM picture of rice leaf cuticle (Fig.2B11), cross-sections of stem (Fig.2B12) and leaf (Fig.2B13),and semithin sections of leaf (Fig.2B14-15).In addition,SEM observation shows that the GUS staining in leaves is mainly distributed along the silica-cork cell lines in the cuticle.Cross-sections and semithin sections indicate that DWA1 is expressed mainly in vascular tissues and epidermal cell layers.
(3)What's more,after various phytohormones treatment,DWA1 expresses higher,such as abscisic acid, jasmonic acid, indole-3-acetic acid, and
gibberellic acid (Fig.2C).
(4)Under drought treatment,GUS staining shows thatDWA1 is induced.For example,in Fig.3B,GUS staining in leaf before (1 and 3) and after (2 and 4) drought stress is shown.
Evolution
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At present,DWA1,likely to a megaenzyme,has five domains at least. The N terminus of DWA1 is an oxidoreductase-like domain,and closely followed by the AMP-binding domain(A domain)Then,two repeats of a phosphopantetheine-binding subdomain follow the A domain and feature a thiolation domain (T domain).An allene oxide synthase (AOS)-like domain is located between the second and third repeats of the left-handed β-helix (LbH) domain at the C-terminal region[1](Fig.2).What's more,homologous sequences with DWA1are all from microorganisms.Nonribosomal peptide synthetase(NRPS),a megaenzyme needed for nonribosomal peptides synthesis in bacteria and filamentous fungi[2],is a major branch of the AMP-binding enzyme superfamily.More importantly,both these homologous sequences and DWA1 have an NRPS module, including adenylation domain, followed by a thiolation domain catalyzing the activation and thiolation reaction of an amino acid instead of a carboxyl substrate for acyl-CoA synthetase.These features suggest that DWA1 and its plant homologs may be derived from a prokaryotic NRPS rather than the acyl-CoA synthetase family, which possesses only the A domain[1].
Labs working on this gene
- National Key Laboratory of Crop Genetic Improvement, National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, Wuhan,China
References
<references> [1]
[2]- ↑ 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 Xiaoyi Zhu, Lizhong Xiong.(2013)Putative megaenzyme DWA1 plays essential roles in drought resistance by regulating stress-induced wax deposition in rice.PANS 110(44): 17790-17795.
- ↑ 2.0 2.1 Marahiel MA, Stachelhaus T, Mootz HD.(1997) Modular peptide synthetases involved in nonribosomal peptide synthesis.Chem Rev 97(7):2651–2674.
