Novel mutant alleles of the starch synthesis gene TaSSIVb-D result in the reduction of starch granule number per chloroplast in wheat

Huijun Guo,Huijun Guo,Xiao Li,Xiao Li,Yongdun Xie,Zhihui Yan,Jiayu Gu,Yunchuan Liu,Yunchuan Liu,Linshu Zhao,Hongchun Xiong,Luxiang Liu,Luxiang Liu,Shirong Zhao,Shirong Zhao

doi:10.1186/s12864-017-3724-4

Huijun Guo, Huijun Guo + Show 13 more

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https://doi.org/10.1186/s12864-017-3724-4

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Abstract

BackgroundTransient starch provides carbon and energy for plant growth, and its synthesis is regulated by the joint action of a series of enzymes. Starch synthesis IV (SSIV) is one of the important starch synthase isoforms, but its impact on wheat starch synthesis has not yet been reported due to the lack of mutant lines.ResultsUsing the TILLING approach, we identified 54 mutations in the wheat gene TaSSIVb-D, with a mutation density of 1/165 Kb. Among these, three missense mutations and one nonsense mutation were predicted to have severe impacts on protein function. In the mutants, TaSSIVb-D was significantly down-regulated without compensatory increases in the homoeologous genes TaSSIVb-A and TaSSIVb-B. Altered expression of TaSSIVb-D affected granule number per chloroplast; compared with wild type, the number of chloroplasts containing 0–2 granules was significantly increased, while the number containing 3–4 granules was decreased. Photosynthesis was affected accordingly; the maximum quantum yield and yield of PSII were significantly reduced in the nonsense mutant at the heading stage.ConclusionsThese results indicate that TaSSIVb-D plays an important role in the formation of transient starch granules in wheat, which in turn impact the efficiency of photosynthesis. The mutagenized population created in this study allows the efficient identification of novel alleles of target genes and could be used as a resource for wheat functional genomics.

Highlights

Transient starch provides carbon and energy for plant growth, and its synthesis is regulated by the joint action of a series of enzymes
ADP-glucose pyrophosphorylases (AGPase) is the first and rate-limiting enzyme in the biosynthesis of starch, it catalyzes the synthesis of ADPglucose, which is the substrate of amylose starch, and over expression of the AGPase gene enhances the rate of starch biosynthesis [2,3,4]
Novel alleles of TaSSIVb-D in a mutagenized population Three primer sets corresponding to TaSSIVb-D were designed for allele mining (Table 1), and their specificities were validated using nullisomic-tetrasomic lines (Fig. 1a)

Summary

Introduction

Transient starch provides carbon and energy for plant growth, and its synthesis is regulated by the joint action of a series of enzymes. Some starch granules are stored for long periods in reserve tissues as storage starch. This type of starch is an important source of carbohydrates for human beings. Other types of starch are stored temporarily as transient starch to provide carbon and energy for plant growth. AGPase is the first and rate-limiting enzyme in the biosynthesis of starch, it catalyzes the synthesis of ADPglucose, which is the substrate of amylose starch, and over expression of the AGPase gene enhances the rate of starch biosynthesis [2,3,4].

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