基因枪法转化基因在小麦条锈菌中的瞬时表达

以小麦条锈菌(Puccinia striiformis f.sp.tritici)野生毒性菌株为转化受体,以含有gus报告基因的质粒(pGUS6L20)和潮霉素抗性基因的质粒(pKLHyg14)为载体,应用基因枪法研究了小麦条锈菌夏孢子遗传转化的瞬时表达特征。结果表明,在金粉直径为0.6μm、射程6cm、载体DNA5μL、可裂膜压力为900Psi或1100Psi时,gus基因和潮霉素抗性基因的瞬时表达率相对较高。     

Biological Control of Take-all Disease of Wheat Caused by Gaeumannomyces graminis var. tritici Under Field Conditions Using a Phialophora sp.

A Phialophora sp. (isolate I-52), originally isolated from soil in a wheat field exhibiting suppression of take-all disease caused by Gaeumannomyces graminis var. tritici , was tested under field conditions for its ability to suppress this disease in winter and spring wheat. I-52 was grown on a variety of autoclaved organic substrates, including oat, millet and canola seed. All of these gave significant disease control when added to the seed furrow with inoculum of the take-all fungus. W hole seed of I-52 substrate was as effective as particles < 0.5 mm in diameter. Placing I-52 in powdered form directly on to wheat seed was ineffective in controlling take-all. Rates as low as 2 g of I-52/3.3 m of row added with the seed provided some control of take-all, and nearly complete control in winter wheat was obtained using 15 g/3.3 m. The winter wheat host cultivar did not influence the degree of control of take-all by I-52.     

Isolation and characterisation of cDNA encoding a wheat heavy metal‐associated isoprenylated protein involved in stress responses

In cells, metallochaperones are important proteins that safely transport metal ions. Heavy metal‐associated isoprenylated plant proteins (HIPPs) are metallochaperones that contain a metal binding domain and a CaaX isoprenylation motif at the carboxy‐terminal end. To investigate the roles of wheat heavy metal‐associated isoprenylated plant protein (TaHIPP) genes in plant development and in stress responses, we isolated cDNA encoding the wheat TaHIPP1 gene, which contains a heavy metal‐associated domain, nuclear localisation signals and an isoprenylation motif (CaaX motif). Quantitative real‐time PCR analysis indicated that the TaHIPP1 gene was differentially expressed under biotic and abiotic stresses. Specifically, TaHIPP1 expression was up‐regulated by ABA exposure or wounding. Additionally, TaHIPP1 over‐expression in yeast (Schizosaccharomyces pombe) significantly increased the cell growth rate under Cu²⁺ and high salinity stresses. The nuclear localisation of the protein was confirmed with confocal laser scanning microscopy of epidermal onion cells after particle bombardment with chimeric TaHIPP1‐GFP constructs. In addition, TaHIPP1 was shown to enhance the susceptibility of wheat to Pst as determined by virus‐induced gene silencing. These data indicate that TaHIPP1 is an important component in defence signalling pathways and may play a crucial role in the defence response of wheat to biotic and certain abiotic stresses.     

A polysaccharide deacetylase from Puccinia striiformis f. sp. tritici is an important pathogenicity gene that suppresses plant immunity

The cell wall of filamentous fungi, comprised of chitin, polysaccharide and glycoproteins, maintains the integrity of hyphae and protect them from defence responses by potential host plants. Here, we report that one polysaccharide deacetylase of Puccinia striiformis f. sp. tritici (Pst), Pst_13661, suppresses Bax‐induced cell death in plants and Pst_13661 is highly induced during early stages of the interaction between wheat and Pst. Importantly, the transgenic wheat expressing the RNA interference (RNAi) construct of Pst_13661 exhibits high resistance to major Pst epidemic races CYR31, CYR32 and CYR33 by inhibiting growth and development of Pst, indicating that Pst_13661 is an available pathogenicity factor and is a potential target for generating broad‐spectrum resistance breeding material of wheat. It forms a homo‐polymer and has high affinity for chitin and germ tubes of Pst compared with the control. Besides, Pst_13661 suppresses chitin‐induced plant defence in plants. Hence, we infer that Pst_13661 may modify the fungal cell wall to prevent recognition by apoplastic surveillance systems in plants. This study opens new approaches for developing durable disease‐resistant germplasm by disturbing the growth and development of fungi and develops novel strategies to control crop diseases.