条锈菌侵染过程中小麦叶片水分关系的变化

以条绣茵29号小种(CY-29)及其弱毒突变菌系(CY29-mut     

Interaction between Rice stripe virus Disease- Specific Protein and Host PsbP Enhances Virus Symptoms

Rice stripe virus （RSV） causes severe diseases in Oryza sativa （rice） in many Eastern Asian countries. Diseasespecific protein （SP） of RSV is a non-structural protein and its accumulation level in rice plant was shown to determine the severity of RSV symptoms. Here, we present evidence that expression of RSV SP alone in rice or Nicotiana benthamiana did not produce visible symptoms. Expression of SP in these two plants, however, enhanced RSV- or Potato virus X （PVX）- induced symptoms. Through yeast two-hybrid screening, GST pull-down, and bimolecular fluorescence complementation assays, we demonstrated that RSV SP interacted with PsbP, a 23-kDa oxygen-evolving complex protein, in both rice and N. benthamiana. Furthermore, our investigation showed that silencing of PsbP expression in both plants increased disease symptom severity and virus accumulation. Confocal microscopy using N, benthamiana protoplast showed that PsbP accu- mulated predominantly in chloroplast in wild-type N. benthamiana cells. In the presence of RSV SP, most PsbP was recruited into cytoplasm of the assayed cells. In addition, accumulation of SP during RSV infection resulted in alterations of chloroplast structure and function. Our findings shed light on the molecular mechanism underlying RSV disease symptom development.     

A large‐scale genomic association analysis identifies the candidate causal genes conferring stripe rust resistance under multiple field environments

The incorporation of resistance genes into wheat commercial varieties is the ideal strategy to combat stripe or yellow rust (YR). In a search for novel resistance genes, we performed a large‐scale genomic association analysis with high‐density 660K single nucleotide polymorphism (SNP) arrays to determine the genetic components of YR resistance in 411 spring wheat lines. Following quality control, 371 972 SNPs were screened, covering over 50% of the high‐confidence annotated gene space. Nineteen stable genomic regions harbouring 292 significant SNPs were associated with adult‐plant YR resistance across nine environments. Of these, 14 SNPs were localized in the proximity of known loci widely used in breeding. Obvious candidate SNP variants were identified in certain confidence intervals, such as the cloned gene Yr18 and the major locus on chromosome 2BL, despite a large extent of linkage disequilibrium. The number of causal SNP variants was refined using an independent validation panel and consideration of the estimated functional importance of each nucleotide polymorphism. Interestingly, four natural polymorphisms causing amino acid changes in the gene TraesCS2B01G513100 that encodes a serine/threonine protein kinase (STPK) were significantly involved in YR responses. Gene expression and mutation analysis confirmed that STPK played an important role in YR resistance. PCR markers were developed to identify the favourable TraesCS2B01G513100 haplotype for marker‐assisted breeding. These results demonstrate that high‐resolution SNP‐based GWAS enables the rapid identification of putative resistance genes and can be used to improve the efficiency of marker‐assisted selection in wheat disease resistance breeding.     

Structural features of split and unsplit βαβ-units

In this study, 1064 nonhomologous “unsplit”, “one-strand split” and “two-strand split” right-handed βαβ-units having standard α-helices and loops up to seven residues in length have been analyzed. It was found that the α-helices in these kinds of βαβ-units have different distributions of the hydrophobic and hydrophilic amino acid residues along the chain. In the unsplit βαβ-units, most α-helices have hydrophobic residues in positions N4-N7-N8-N11 or N6-N7-N10, where N1 is the first N-terminal residue. In the one-strand split βαβ-units, most α-helices have hydrophobic residues in positions N4-N7-N8-N11 and those in two-strand split βαβ-units in positions N4-N5-N8-N12. On the other hand, in all kinds of βαβ-units, there are commonly occurring hydrophobic stripes of type C4-C7-C8 at the C-terminal parts of the α-helices. As a rule, the C- and N-terminal hydrophobic stripes overlap and the extent of their overlapping determine the length of α-helices.     

Inheritance and Mechanism of Resistance to Rice Stripe Disease in cv. Zhendao 88, a Chinese Rice Cultivar

Mechanisms of resistance to rice stripe disease in a Chinese rice cultivar (Oryza sativa L., cv. Zhendao 88) were determined, and molecular markers for the resistance gene were identified. Single tillers at the seedling stage were inoculated with Rice stripe virus (RSV) and its vector, the small brown planthopper (SBPH) Laodelphax striatellus Fallen, to test for non‐preference and antibiosis. The inheritance of resistance in the F₂ and F_{2 : 3} lines from the cross cvs Zhendao 88× Wuyujing No. 3 was also examined by single‐tiller inoculation. Cv. Zhendao 88 was highly resistant to RSV and weakly resistant to SBPH. The resistance gene was mapped by SSR and RAPD analyses to rice chromosome 11 within 4.7 cm of a SSR marker RM229 and a RAPD marker OPO11. Data and inheritance analysis indicated that rice stripe disease resistance in cv. Zhendao 88 was derived principally from resistance to RSV and controlled by a single dominant gene. Breeding for rice stripe resistance could be accelerated by using cv. Zhendao 88 as a resistant parent if the linked marker for virus resistance were used in a marker‐assisted progeny selection programme.     

A Simple Technique for Determining the Reaction of Barley Genotypes to Pyrenophora graminea

An in vitro technique was used to determine the reaction of 10 barley genotypes to Pyrenophora graminea, the seed‐borne pathogen causing barley leaf stripe disease. Determination was based on the percentage of inoculated seeds that produced fungal hyphae when cultured on potato dextrose agar. The technique allows low, intermediate and absolute levels of resistance to leaf stripe to be determined. Genotypes CI‐5791 and Banteng were resistant, Thibaut, Igri and PK (30‐531) were moderately resistant, Gollf was moderately susceptible, and WI2291, Arabi Abiad, Furat 1 and Arrivate were susceptible. The in vitro and in field assessments were significant (correlation coefficient r=0.96), results indicating that repeated measurements for infected seeds by this in vitro method were very similar to those of field assessments.     

Surface display of rice stripe virus NSvc2 and analysis of its membrane fusion activity

Rice stripe virus (RSV) infects rice and is transmitted in a propagative manner by the small brown planthopper.How RSV enters an insect cell to initiate the infection cycle is poorly understood.Sequenc...     

粗山羊草抗条锈病新基因YrY206遗传分析和微卫星 标记

从小麦野生近缘属——粗山羊草中挖掘小麦条锈病抗病基因, 拓展小麦抗病性的遗传基础。利用抗小麦条锈病与感小麦条锈病的粗山羊草间杂交, 从粗山羊草[Aegilops tauschii (Coss.) Schmal] Y206中鉴定出1个显性抗小麦条锈病基因, 暂定名为YrY206。应用分离群体分组法(Bulked segregant analysis, BSA)筛选到Wmc11a、Xgwm71c、Xgwm161和Xgwm183标记, 与该基因之间的遗传距离分别为4.0、3.3、1.5和9.3 cM。根据连锁标记所在小麦微卫星图谱的位置, YrY206被定位在3DS染色体上。分析基因所在染色体的位置、抗病性特征, 认为YrY206是一个新的抗小麦条锈病基因。