Genome-wide identification and expression analysis of the invertase gene family in common wheat (Triticum aestivum L.)

Abstract

AbstractBackgroundThe degradation of sucrose plays an important role in the process of crop biomass allocation and yield formation. Invertase (INV) irreversibly catalyzes the conversion of sucrose into glucose and fructose, which doomed its’ important role in plant development and stress tolerance. However, the functions of INV genes in wheat, one of the most important crops, were less studied due to the polyploidy.ResultsHere, we systematically analyzed the INV gene family based on the latest published wheat reference genomic information. A total of 126 TaINV genes were identified and classified into three classes based on the phylogenetic relationship and their gene structure. Of which, 11 and 83 gene pairs were identified as tandem and segmental duplication genes respectively, while the Ka/Ks ratios of tandem and segmental duplication TaINV genes were less than 1. Expression profile analysis shows that 18 TaINV genes have tissue-specific expression, and 54 TaINV genes were involved in stress response. Furthermore, RNA-seq showed that 35 genes are differentially expressed in grain weight NILs N0910-81L/N0910-81S, in which 9 TaINVs were stably detected by qRT-PCR at three time-points, 4, 7 and 10 DPA. Four of them (TaCWI47, TaCWI48, TaCWI50 and TaVI27) different expressed between the NILs resided in 4 QTL segments (QTGW.nwafu-5DL.1, QTGW.nwafu-5DL.2, QTGW.nwafu-7AS.1 and QTGW.nwafu-7AS.2). These findings facilitate function investigations of the wheat INV gene family and provide new insights into the grain development mechanism in wheat.ConclusionsOur results showed that allopolyploid events were the main reason for the expansion of the TaINV gene family in hexaploid wheat, and duplication genes might undergo purifying selection. The expression profiling of TaINV genes implied that they are likely to play an important role in wheat growth and development and adaption to stressful environments. And TaCWI47, TaCWI48, TaCWI50 and TaVI27 may have more important roles in grain developments. Our study lay a base for further dissecting the functional characterization of TaINV family members.