The APETALA 2/Ethylene-responsive element binding factor (AP2/ERF) transcription factor gene family is widely involved in the biotic and abiotic stress regulation. Haynaldia villosa (VV, 2n = 14), a wild species of wheat, is a potential gene pool for wheat improvement. H. villosa confers high resistance to several wheat diseases and high tolerance to some abiotic stress. In this study, ERF1-V, an ethylene-responsive element-binding factor gene of the AP2/ERF transcription factor gene family from wild H. villosa, was cloned and characterized. Sequence and phylogenetic analysis showed that ERF1-V is a deduced B2 type ERF gene. ERF1-V was first identified as a Blumeria graminis f. sp. tritici (Bgt) up-regulated gene, and later found to be induced by drought, salt and cold stresses. In responses to hormones, ERF1-V was up-regulated by ethylene and abscisic acid, but down-regulated by salicylic acid and jasmonic acid. Over expression of ERF1-V in wheat could improve resistance to powdery mildew, salt and drought stress. Chlorophyll content, malondialdehyde content, superoxide dismutase and peroxidase activity were significantly differences between the recipient Yangmai158 and the transgenic plants following salt treatment. Furthermore, the expression levels of some stress responsive genes were differences after drought or salt treatments. Although ERF1-V was activated by the constitutive promoter, the agronomic traits, including flowering time, plant height, effective tiller number, spikelet number per spike and grain size, did not changed significantly. ERF1-V is a valuable gene for wheat improvement by genetic engineering.
Wheat powdery mildew caused by Blumeria graminisb f. sp. tritici is one of the most destructive diseases all over the world. Pm21, transferred from the wild Haynaldia villosa to wheat, confers broad spectrum resistance throughout the whole stage, and this gene has been widely used in wheat production for more than 20 years. Cloning the candidate gene of Pm21 is the prerequisite for elucidating the resistance mechanism, and is a valuable attempt to clone the target genes from the evolutionarily distant wild species. In this study, an innovative approach, which combined cytogenetic stocks development, mutagenesis, RenSeq and PacBio, was tried successfully to clone an NBS-LRR type gene NLR1-V from the Pm21 locus. Firstly, a powdery mildew resistant cryptic alien introgression line HP33 involved very small 6VS segment was developed, and 6 independent susceptible mutants of T6VS· 6AL was identified. Then, the transcriptome of H. villosa was obtained by NGS and the full-length NBS-LRR gene database was constructed by RenSeq-PacBio. In the following study, two expressed NLR genes were located to the Pm21 locus using the HP33 as the mapping material, and only NLR1-V showed polymorphism between the wild T6VS· 6AL and its six mutants. The functional analysis indicated that silencing of NLR1-V could compromise the resistance of T6VS· 6AL completely, and could also decrease the resistance of T6VS· 6DL dramatically. Moreover, NLR1-V could recover the resistance of the susceptible mutant and increase the resistance in the susceptible wheat. The study implied that NLR1-V, a CC-NBS-LRR encoding gene, is a potential candidate gene of the powdery mildew resistance gene Pm21.
MADS-box transcription factors (TFs) are involved in a variety of processes in flowering plants ranging from root growth to flower and fruit development. However, studies of the tolerance-related functions of MADS-box genes are very limited, and to date no such studies have been conducted on Camellia sinensis. To gain insight into the functions of genes of this family and to elucidate the role they may play in tissue development and Al and F response, we identified 45 MADS-box genes through transcriptomic analysis of C. sinensis. Phylogenetic analysis of these CsMADS-box genes, along with their homologues in Arabidopsis thaliana, enabled us to classify them into distinct groups, including: M-type (Mα), MIKC* and MIKC c (which contains the SOC1, AGL12, AGL32, SEP, ANR1, SVP, and FLC subgroups). Conserved motif analysis of the CsMADS-box proteins revealed diverse motif compositions indicating a complex evolutionary relationship. Finally, we examined the expression patterns of CsMADS-box genes in various tissues and under different Al and F concentration treatments. Our qPCR results showed that these CsMADS-box genes were involved in Al and F accumulation and root growth in C. sinensis. These findings lay the foundation for future research on the function of CsMADS-box genes and their role in response to Al and F accumulation in root tissues.
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