SNARE proteins mediate eukaryotic cell membrane/transport vesicle fusion and act in plant resistance to fungi. Herein, 173 SNARE proteins were identified in wheat and divided into 5 subfamilies and 21 classes. The number of the SYP1 class type was largest in TaSNAREs. Phylogenetic tree analysis revealed that most of the SNAREs were distributed in 21 classes. Analysis of the genetic structure revealed large differences among the 21 classes, and the structures in the same group were similar, except across individual genes. Excluding the first homoeologous group, the number in the other homoeologous groups was similar. The 2,000 bp promoter region of the TaSNARE genes were analyzed, and many W-box, MYB and disease-related cis-acting elements were identified. The qRT-PCR-based analysis of the SNARE genes revealed similar expression patterns of the same subfamily in one wheat variety. The expression patterns of the same gene in resistant/sensitive varieties largely differed at 6 h after infection, suggesting that SNARE proteins play an important role in early pathogen infection. Here, the identification and expression analysis of SNARE proteins provide a theoretical basis for studies of SNARE protein function and wheat resistance to powdery mildew.
SNARE (Soluble N - ethylmaleimide - sensitive - factor attachment protein receptor) proteins are mainly mediated eukaryotic cell membrane fusion of vesicles transportation, also play an important role in plant resistance to fungal infection. In this study, 1342 SNARE proteins were identified in 18 plants. According to the reported research, it was splited into 5 subfamilies (Qa, Qb, Qc, Qb+Qc and R) and 21 classes. The number of SYP1 small classes in Qa is the largest (227), and Qb+Qc is the smallest (67). Secondly, through the analysis of phylogenetic trees, it was shown that the most SNAREs of 18 plants were distributed in 21 classes. Further analysis of the genetic structure showed that there was a large difference of 21 classes, and the structure of the same group was similar except for individual genes. In wheat, 173 SNARE proteins were identified, except for the first homologous group (14), and the number of others homologous groups were similar. The 2000bp promoter region upstream of wheat SNARE gene was analyzed, and a large number of W-box, MYB and disease-related cis-acting elements were found. The qRT-PCR results of the SNARE gene showed that the expression patterns of the same subfamily were similar in one wheat varieties. The expression patterns of the same gene in resistant/sensitive varieties were largely different at 6h after infection. This results might indicate that early stages of the SNARE protein in pathogen infection play an important role. In this study, the identification and expression analysis of the SNARE protein provides a theoretical basis for future studies on the function of the SNARE protein and wheat resistance to powdery mildew.
SNARE (Soluble N - ethylmaleimide - sensitive - factor attachment protein receptor) proteins are mainly mediated eukaryotic cell membrane fusion of vesicles transportation, also play an important role in plant resistance to fungal infection. In this study, 1342 SNARE proteins were identified in 18 plants. According to the reported research, it was splited into 5 subfamilies (Qa, Qb, Qc, Qb+Qc and R) and 21 classes. The number of SYP1 small classes in Qa is the largest (227), and Qb+Qc is the smallest (67). Secondly, through the analysis of phylogenetic trees, it was shown that the most SNAREs of 18 plants were distributed in 21 classes. Further analysis of the genetic structure showed that there was a large difference of 21 classes, and the structure of the same group was similar except for individual genes. In wheat, 173 SNARE proteins were identified, except for the first homologous group (14), and the number of others homologous groups were similar. The 2000bp promoter region upstream of wheat SNARE gene was analyzed, and a large number of W-box, MYB and disease-related cis-acting elements were found. The qRT-PCR results of the SNARE gene showed that the expression patterns of the same subfamily were similar in one wheat varieties. The expression patterns of the same gene in resistant/sensitive varieties were largely different at 6h after infection. This results might indicate that early stages of the SNARE protein in pathogen infection play an important role. In this study, the identification and expression analysis of the SNARE protein provides a theoretical basis for future studies on the function of the SNARE protein and wheat resistance to powdery mildew.
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