Baoyun Li

Differential effects of a post-anthesis heat stress on wheat ( Triticum aestivum L.) grain proteome determined by iTRAQ

Heat stress, a major abiotic stressor of wheat (Triticum aestivum L.), often results in reduced yield and decreased quality. In this study, a proteomic method, Tags for Relative and Absolute Quantitation Isobaric (iTRAQ), was adopted to analyze the protein expression profile changes among wheat cultivar Jing411 under heat stress. Results indicated that there were 256 different proteins expressed in Jing411 under heat stress. According to the result of gene annotation and functional classification, 239 proteins were annotated by 856 GO function entries, including growth and metabolism proteins, energy metabolism proteins, processing and storage proteins, defense-related proteins, signal transduction, unknown function proteins and hypothetical proteins. GO enrichment analysis suggested that the differentially expressed proteins in Jing411 under heat stress were mainly involved in stimulus response (67), abiotic stress response (26) and stress response (58), kinase activity (12), and transferase activity (12). Among the differentially expressed proteins in Jing411, 115 were attributed to 119 KEGG signaling/metabolic pathways. KEGG pathway enrichment analysis in Jing411 showed that heat stress mainly affected the starch and sucrose metabolism as well as protein synthesis pathway in the endoplasmic reticulum. The protein interaction network indicated that there were 8 differentially expressed proteins that could form an interaction network in Jing411.

Silencing of a lipase maturation factor 2-like gene by wheat-mediated RNAi reduces the survivability and reproductive capacity of the grain aphid, Sitobion avenae

Lipase maturation factor (LMF) family proteins are required for the maturation and transport of active lipoprotein lipases. However, the specific roles of LMF2 remain unknown. In this study, a grain aphid lmf2-like gene fragment was cloned and was highly similar in sequence to a homologous gene in the pea aphid, Acyrthosiphon pisum. An RNAi vector was constructed with this fragment and used for wheat transformation. The expression of the lmf2-like gene in aphid, as well as the growth and reproduction of the aphids, was analyzed after feeding on the transgenic wheat. There were no significant differences in the expression of the lmf2-like gene over development. The expression of the lmf2-like gene was significantly reduced by 27.6% on the fifth day, and 57.6% on the 10th day after feeding. The total number of aphids produced on the transgenic plants was less than the number produced on control plants, and the difference became significant or after 2 weeks. The molting numbers were also reduced in the aphids reared on the transgenic plants. Our findings indicate that lmf2-like genes may have potential as a target gene for the control of grain aphids and show that feeding aphids with wheat expressing lmf2-like RNAi resulted in significant reductions in survival and reproduction.

Plant-mediated RNAi of grain aphid CHS1 gene confers common wheat resistance against aphids: RNAi of grain aphid CHS1

BACKGROUND Chitin is an important component of the insect exoskeleton and peritrophic membrane. Chitin synthase 1 (CHS1) is a key enzyme in the chitin synthesis pathway, and has a role in insect molting and growth. Plant-mediated RNA interference (RNAi) has been used as a more target-specific and environmentally safe approach to prevent and control agricultural insects. The aims of this study were to use grain aphid (Sitobion avanae) CHS1 as the target gene and to produce transgenic wheat lines for aphid control via plant-mediated RNAi. RESULTS Expression levels of CHS1 changed at different developmental stages. After feeding on the representative T3 transgenic lines Tb5-2 and Tb10-3, CHS1 expression levels in grain aphid decreased by 50.29% and 45.32%, respectively; and total and molting aphid numbers reduced significantly, compared with controls. Consistent with this, aphid numbers in mixed natural populations reduced significantly in the respective T4 and T5 transgenic lines under field conditions, and T5 transgenic lines had higher grain weight compared with the unsprayed insecticide wild-type and insecticide-sprayed wild-type. CONCLUSION These results indicate that plant-mediated RNAi of the grain aphid CHS1 gene confers common wheat resistance against aphids.

Expression of Pinellia pedatisecta Lectin Gene in Transgenic Wheat Enhances Resistance to Wheat Aphids

Wheat aphids are major pests during the seed filling stage of wheat. Plant lectins are toxic to sap-sucking pests such as wheat aphids. In this study, Pinellia pedatisecta agglutinin (ppa), a gene encoding mannose binding lectin, was cloned, and it shared 92.69% nucleotide similarity and 94% amino acid similarity with Pinellia ternata agglutinin (pta). The ppa gene, driven by the constitutive and phloem-specific ribulose bisphosphate carboxylase small subunit gene (rbcs) promoter in pBAC-rbcs-ppa expression vector, was transferred into the wheat cultivar Baofeng104 (BF104) by particle bombardment transformation. Fifty-four T0 transgenic plants were generated. The inheritance and expression of the ppa gene were confirmed by PCR and RT-PCR analysis respectively, and seven homozygous transgenic lines were obtained. An aphid bioassay on detached leaf segments revealed that seven ppa transgenic wheat lines had lower aphid growth rates and higher inhibition rates than BF104. Furthermore, two-year aphid bioassays in isolated fields showed that aphid numbers per tiller of transgenic lines were significantly decreased, compared with wild type BF104. Therefore, ppa could be a strong biotechnological candidate to produce aphid-resistant wheat.

Ectopic expression of the Vigna eylindrica ferritin gene enhanced heat tolerance in transgenic wheat (Triticum aestivum L.)

The Ferritins are the iron storage proteins which regulate intracellular iron content via the absorption and release of iron, and related to plant oxidative stress and pathogens. However, the possible role of FER in heat stress responses remains unknown. In this study, the black rice (Vigna eylindrica) ferritin gene, VeFER, was cloned and integrated into the genome of wheat cultivar ZY9507 via biolistic transformation. Expression analysis of T3 transgenic plants subjected to heat treatment showed significantly increased VeFER expression in the transgenic lines as compared to the untransformed plants. The MDA content of the transgenic lines was significantly lower than that in the cultivar. Further, the transgenic lines had similar relative electrical conductivities to the heat resistant variety TAM107, but were significantly lower than the untransformed control cultivar and the heat-sensitive variety CS. These results indicate that the VeFER gene plays a crucial role in improving the heat tolerance of transgenic wheat plants, likely by promoting the thermal stability of cell membranes.