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Abstract
 
Vol 48 No. 2: 161-173 [PDF] [Full Text]
 
Proteomic analysis of heterosis in the leaves of sorghum�Csudangrass hybrids
 
Pingan Han1,†,

Xiaoping Lu1,†,*,

Fugui Mi2,

Jing Dong1,

Chunlei Xue1,

Jianke Li3,

Bin Han3 and

Xiaoyu Zhang1

1Agricultural College, Inner Mongolia Agricultural University, Hohhot 010019, China

2College of Ecology and Environmental Science, Inner Mongolia Agricultural University, Hohhot 010019, China

3Chinese Academy of Agricultural Science, Institute of Apicultural Research, Beijing 100093, China

† These authors contributed equally to this work.

 

Abstract  Sorghum�Csudangrass hybrids are widely used for forage and silage in the animal husbandry industry due to their hardiness. The heterozygous first generation of sorghum�Csudangrass hybrids displays performance superior to their homozygous, parental inbred lines. In order to study the molecular details underlying its heterosis, the leaves of sorghum�Csudangrass hybrids and their parents were compared using mass spectrometry-based proteomics. Results showed that among the 996 proteins that were identified, 32 proteins showed ‘additive accumulation expression patterns’, indicating that the protein abundance in sorghum�Csudangrass hybrids showed no significant difference from the average of their parents. Additionally, 74 proteins showed ‘nonadditive accumulation expression patterns’ (the proteins abundance in the hybrids showed significant difference from the average of their parents). Both additive and nonadditive proteins were mainly involved in photosynthesis and carbohydrate metabolism. More upregulated additive and nonadditive proteins were in the hybrids than in their parents, suggesting that additive and nonadditive proteins are essential to the vigor of sorghum�Csudangrass hybrids. The nonadditive proteins were enriched in photosynthesis, carbohydrate metabolism, and protein oligomerization, but the additive proteins were not enriched in any pathway, which indicated that the nonadditive proteins could be greater contributors to heterosis than additive proteins. Furthermore, the highly activated photosynthetic pathway in nonadditive proteins implies that photosynthesis in hybrids is heightened to assimilate more organic matter, resulting in an increased yield. Our results provide a proof-of-concept that reveals the molecular components of heterosis in sorghum�Csudangrass hybrid leaves and serves as an important step for future genetic manipulation of specific proteins to improve the performance of hybrids.

 

Keywords   sorghum�Csudangrass hybrids; heterosis; proteomics; label-free LC�CMS

 

Received   2015-8-18  

Accepted  2015-10-8

 

Funding  This work was supported by a grant from the National Natural Science Foundation of China (No. 31460375).

 

* Correspondence address  Tel/Fax: +86-0471-4318396; E-mail: [email protected]

 
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