Inheritance of Resistance to Septoria Blotch in Common Wheat Sample MN81330

Wheat samples described in literature as resistant to septoria glume blotch were assessed for their response to inoculation with Septoria nodorum Berk. Three days after inoculation with the causal agent, samples Klein Titan (k-41772), Mian Jang (k-61568), Walter (k-54585), Reisler (k-59505), Rempart (k-59493), PIN/BOW (k-62838), MN81330 (k-60785), Frondoso (k-46736), Sokrates (k-58179) were classified as resistant to infection. Seven days after inoculation, only samples Reisler and Mian Jang were regarded as resistant. The genetic control of glume blotch resistance was studied by hybridological analysis in sample MN81330. Resistance of this sample manifested in a longer latent period of the disease is controlled by two dominant complementary genes not linked to the gene Lr24 responsible for resistance to leaf rust, to the genes responsible for coleoptile coloration, and to minor genes that increase expression of the major ones.     

Identification of Sorghum genes responsible for resistance to Green bug

Genes responsible for resistance to greenbug (Schizaphis graminum Rond.) were identified in sorghum. The dominant (Sgr1) and recessive (Sgr2) genes for resistance were revealed in sample k-457 (PI264453, United States). The samples i-589430 (PI264453, Spain) and k-3852 (Sarvasi, Hungary) carry gene Sgr1. These accessions are assumed to also have gene Sgr2. The samples k-9921 (Shallu, United States) and k-9922 (KS-30, United States) have incompletely dominant resistance gene Sgr3. A symbol Sgr4 was assigned to the dominant gene from sample k-6694 (Deer, United States). The dominant Sgr5 and recessive Sgr6 genes were revealed in the samples k-1362 (Durra Belaya, Syria) and k-1240 (Dzhugara Belaya, China). The cultivar Sorgogradskoe (k-9436, Rostovskaya oblast) has gene Sgr5. The samples k-10092 (Odesskii 360, Ukraine) and k-5091 (Cherhata, Marocco) are assumed to have genes Sgr5 and Sgr6. Sample k-924 (Dzhugara Belaya, China) is protected by the dominant gene Srg7 and recessive gene Sgr8. Sample k-923 (Dzhugara Belaya, China) has at least one of these genes. Two dominant complementary genes for resistance (Sgr9 and Sgr10) were revealed in sample k-930 (Dzhugara Belaya, China). One of two dominant genes of sample k-1237 (Dzhugara Belaya, China) was assigned the symbol Sgr11. Genes Sgr5-Sgr11 responsible for resistance to greenbug are new and were not previously used in breeding.     

Detection of QTLs for Stagonospora glume blotch resistance in Swiss winter wheat

Stagonospora nodorum is the causal agent of the Stagonospora glume blotch disease in hexaploid wheat. The Swiss winter bread wheat cv. 'Arina' has a highly effective, durable and quantitative glume blotch resistance. We studied 240 single seed descent (SSD)-derived lines of an 'Arina × Forno' F_5:7 population to identify and map quantitative trait loci (QTLs) for glume blotch resistance under natural infestation. Using composite interval mapping (CIM) and LOD>4.5, we detected two chromosomal regions on chromosome arms 3BS and 4BL which were specifically associated with glume blotch resistance. These identified QTLs were designated QSng.sfr-3BS and QSng.sfr-4BL, respectively. QSng.sfr-3BS peaked at the locus Xgwm389 in the telomeric region of the short arm of chromosome 3B and explained 31.2% of the observed phenotypic variance for the resistance within the population. The responsible QSng.sfr-3BS allele originated from the resistant parent 'Arina'. The QTL QSng.sfr-4BL (19.1%) mapped to chromosome arm 4BL ('Forno' allele) very close to two known genes, TaMlo and a catalase (Cat). Both QTL alleles combined could enhance the resistance level by about 50%. Additionally, they showed significant epistatic effects (4.4%). We found PCR-based microsatellite markers closely linked to QSng.sfr-3BS (gwm389) and QSng.sfr-4BL (gwm251) which make marker-assisted selection (MAS) for Stagonospora glume blotch resistance feasible. We also found one resistance QTL, QSng.sfr-5BL, on the long arm of chromosome 5B which overlapped with QTLs for plant height as well as heading time.Communicated by H. C. Becker     

Inheritance of field resistance to Stagonospora nodorum leaf and glume blotch and correlations with other morphological traits in hexaploid wheat (Triticum aestivum L.)

Breeding for wheat varieties resistant to Stagonospora nodorum blotch (SNB) is the most sustainable strategy for controlling the disease. In order to map quantitative trait loci (QTLs) for SNB resistance we analysed 204 recombinant inbred lines of the cross between the winter wheat (Triticum aestivum L.) variety Forno and the winter spelt (Triticum spelta L.) variety Oberkulmer. We determined the level of resistance of adult plants to leaf blotch (SNL) and glume blotch (SNG) as well as morphological traits for 2 years after artificial inoculation with S. nodorum. Using composite interval mapping and LOD > 3.7, we detected ten QTLs for SNG blotch resistance (six inherited from the susceptible parent Forno) and 11 QTLs for SNL resistance (four inherited from Forno) across 2 years. Both resistance traits were moderately correlated (r = 0.52) and had only one common QTL. For SNL resistance, seven QTLs were not associated with QTLs for morphological traits. Among them, QSnl.eth-2D, QSnl.eth-4B and QSnl.eth-7B3 had major effects (R(2) > 13%) and were potential candidates for marker-assisted selection. For SNG, the major QTL on chromosome 5A, explaining 36% of the phenotypic variance for resistance, was associated with the q locus conferring the spelt morphology (long lax ear, long culm and hard glumes). Only QSng.eth-1BS, which explained 7% of the variance for resistance to SNG blotch, was not associated with QTLs for morphological traits. The consequences for breeding programmes are discussed.     

Inheritance of resistance to leaf and glume blotch caused by Septoria nodorum Berk. in winter wheat

Sixteen crosses between eight winter wheat cultivars were screened for resistance to Septoria nodorum leaf and glume blotch in the F₁ and F₄ generations using artificial inoculation in the field. The F₁ of most crosses showed dominance for susceptibility on both ear and leaf. The effects of general combining ability were of similar magnitude as the effects for specific combining ability. On the basis of the phenotypic difference of the parents, no prediction was possible about the amount and the direction of genetic variance in the segregating populations. The variation observed in this study both within and among the segregating populations suggests a quantitative inheritance pattern influencing the expression of the two traits. The components of variance between F₂ families within a population were as high as (for S. nodorum blotch on the ear) or higher (for S. nodorum blotch on the leaf) than those between populations. Therefore, strong selection within a few populations may be as effective to obtain new resistant genotypes as selection in a large number of populations. In almost all crosses, progenies were found that were more resistant than the better parent. Thus transgression breeding may be a tool to breed for higher levels of resistance to S. nodorum blotch. Highly resistant genotypes were found even in combination with two susceptible parents. The genetic source for Septoria resistance is probably broader than is generally assumed and could be used to improve S. nodorum resistance by combination breeding followed by strong selection in large populations. Received: 18 January / Accepted: 30 April 1999     

Inheritance of greenbug resistance in several forms of grain sorghum and sudangrass

The inheritance of resistance against the Krasnodar population of common greenbug Schizaphis graminum Rond. was analyzed in nine accessions of grain sorghum and sudangrass. The dominant gene of cultivar Capbam (k-455, United States) was effective against some greenbug clones and differed from the Sgr1-Sgr11 resistance genes. The gene was designated as Sgr12. The cultivar Capbam was proposed for use as a differentiator in population genetic studies in S. graminum. The cultivar Sarvasi (k-3852, Hungary) contains not only the dominant Sgr1 gene, but also a recessive gene (most likely Sgr2), which is effective against some greenbug clones. Grain sorghum accessions k-928 and k-929 (Gugara Belaya, western China) each carry two highly effective dominant resistance genes, which differ from Sgr1-Sgr4, Sgr6, Sgr9, and Sgr10. In addition, the resistance genes of accession k-929 differ from the Sgr5 gene. Accession k-928 proved to contain an additional dominant resistance gene, which is expressed in response to some greenbug clones. The gene was designated as Sgr13. Sudangrass accessions k-100 and k-122 (Ukraine) each carry two dominant resistance genes. Accessions k-62, k-99 (Ukraine), and k-96 (Russia) each carry one dominant and one recessive resistance gene. The dominant resistance genes that are expressed in the cultivar Odesskaya 25 (k-122) in response to infestation with some clones from the natural greenbug population were designated as Sgr14 and Sgr15.     

Prospects for exploitation of disease resistance from Hordeum chilense in cultivated cereals

Hordeum chilense is a South American wild barley with high potential for cereal breeding given its high crossability with other members of the Triticeae. In the present paper we consider the resistance of H. chilense to several fungal diseases and the prospects for its transference to cultivated cereals. All H. chilense accessions studied are resistant to the barley, wheat and rye brown rusts, the powdery mildews of wheat, barley, rye and oat, to Septoria leaf blotch, common bunt and to loose smuts, which suggests that H. chilense is a non-host of these diseases. There are also lines resistant to wheat and barley yellow rust, stem rust and to Agropyron leaf rust, as well as lines giving moderate levels of resistance to Septoria glume blotch, tan spot and Fusarium head blight. Some H. chilense lines display pre-appressorial avoidance to brown rust. Lines differ in the degree of haustorium formation by rust and mildew fungi they permit, and in the degree to which a hypersensitive response occurs after haustoria are formed. Unfortunately, resistance of H. chilense to rust fungi is not expressed in tritordeum hybrids, nor in chromosome addition lines in wheat. In tritordeum, H. chilense contributes quantitative resistance to wheat powdery mildew, tan spot and loose smut. The resistance to mildew, expressed as a reduced disease severity, is not associated with macroscopically visible necrosis. Hexaploid tritordeums are immune to Septoria leaf blotch and to common bunt although resistance to both is slightly diluted in octoploid tritordeums. Studies with addition lines in wheat indicate that the resistance of H. chilense to powdery mildew, Septoria leaf blotch and common bunt is of broad genetic basis, conferred by genes present on various chromosomes.     

Sources and donors of resistance to wheat spot blotch caused by Bipolaris sorokiniana Shoem. (Cochliobolus sativus Drechs. ex Dastur)

The resistance of wheat lines and cultivars from the Institute of Crop Breeding (Harbin, China) and synthetic, hexaploid wheat lines derived from T. durum and T. tauschii (CIMMYT) were screened for resistance to spot blotch Bipolaris sorokiniana Shoem. using field and laboratory tests. The highly and moderately resistant wheat samples were determined. The satisfactory coincidence of data obtained from evaluation of type reaction of seedlings and disease severity in adult plant stage was demonstrated. The genetics of resistance in Chinese lines Long 98-4554, Long 98-4546, Long mai 24, Long mai 23 and Canadian line 181-5 was studied using hybridological analysis. The resistance in these lines was inherited as quantitative traits and was conditioned by a few (one or two) genes. The absence of susceptible plants in F₂ in crosses of resistant lines Long 98-4554, Long 98-4546, Long mai 24 and 181-5 can testify to the presence of a common gene of resistance. Our data reveals the poor genetic diversity for spot blotch resistance in studying wheat genotypes.     

Genetic control of effective juvenile resistance to leaf rust in collection samples of Triticum aestivum L.

Of 153 samples reported to be resistant to leaf rust (Puccinia recondita Rob. ex. Desm.), only 70 were not affected by a complex P. recondita population. According to phytopathological tests (inoculation with test clones), 14 samples possessed the Lr19 gene; 36, the Lr24 gene; 1, the Lr41 gene; and 19 presumably had the Lr9 gene. The presence of these genes for resistance was confirmed by hybridological analysis for 26 samples. Of 28 samples reported to carry new effective genes for resistance other than the known genes, 23 were susceptible to the P. recondita population. In four of the other five samples, resistance proved to be controlled by known genes. Possible causes of false identification of new effective genes for leaf rust resistance in wheat are discussed.     

Inheritance of greenbug resistance in several forms of grain sorghum and sudangrass

The inheritance of resistance against the Krasnodar population of common greenbug Schizaphis graminum Rond. was analyzed in nine accessions of grain sorghum and sudangrass. The dominant gene of cultivar Capbam (k-455, United States) was effective against some greenbug clones and differed from the Sgr1–Sgr11 resistance genes. The gene was designated as Sgr12. The cultivar Capbam was proposed for use as a differentiator in population genetic studies in S. graminum. The cultivar Sarvasi (k-3852, Hungary) contains not only the dominant Sgr1 gene, but also a recessive gene (most likely Sgr2), which is effective against some greenbug clones. Grain sorghum accessions k-928 and k-929 (Gugara Belaya, western China) each carry two highly effective dominant resistance genes, which differ from Sgr1–Sgr4, Sgr6, Sgr9, and Sgr10. In addition, the resistance genes of accession k-929 differ from the Sgr5 gene. Accession k-928 proved to contain an additional dominant resistance gene, which is expressed in response to some greenbug clones. The gene was designated as Sgr13. Sudangrass accessions k-100 and k-122 (Ukraine) each carry two dominant resistance genes. Accessions k-62, k-99 (Ukraine), and k-96 (Russia) each carry one dominant and one recessive resistance gene. The dominant resistance genes that are expressed in the cultivar Odesskaya 25 (k-122) in response to infestation with some clones from the natural greenbug population were designated as Sgr14 and Sgr15.     

大麦主栽品种亲缘系数和对叶斑病的抗性分析

为明确我国大麦主栽品种的遗传多样性及其对叶斑病的抗性来源,采用亲缘系数(COP,coefficient of parentage)分析方法对155个主栽大麦品种的遗传系谱进行聚类分析,同时对其中79个供试大麦品种在苗期和成株期分别接种2个强毒性菌株进行抗性鉴定。结果显示,155个品种聚为6个类群,有亲缘关系的品种占全部品种14.77%。在品种间组成的11935个组合中,1763个组合间存在亲缘关系,其COP值变化范围在0~0.7500之间,亲缘系数总和为157.5867,平均值为0.0132。根据系谱分析发现了不同育种单位所育品种的核心亲本,并追溯其主要的祖先亲本。此外,通过对叶斑病的抗性鉴定,发现大多数供试的大麦品种感叶斑病,高抗品种主要集中在垦啤麦系列品种和蒙啤麦3号,部分华大麦和驻大麦系列的品种在苗期或成株期中抗叶斑病。系谱分析及抗性鉴定结果揭示了我国大麦叶斑病抗性基因存在不同来源,分析结果有利于提高抗叶斑病基因筛选效率和缩小筛选范围,也将促进抗叶斑病新基因资源的发掘和利用。     

Comparative genetic analysis of diploid naked wheat Triticum sinskajae and the progenitor T. monococcum accession

The inheritance of several morphological and biochemical traits was studied in diploid (2n = 2x = 14) naked wheat Triticum sinskajae. The electrophoretic pattern of storage proteins (gliadins) of T. sinskajae differed only in two components from the pattern of T. monococcum accession k-20970, in a population of which T. sinskajae had been discovered. Analysis of biochemical polymorphisms revealed a difference between T. monococcum k-20970 and T. sinskajae in a slow 6-phosphogluconate dehydrogenase region but not in the other eight enzyme systems examined. Nucleotide sequence analysis of the nuclear Acc-1 (acetyl-CoA carboxylase) gene revealed a 46-bp deletion from intron 11 in T. monococcum k-20970 but not in T. sinskajae. This difference was not regarded as species-specific in view of the intraspecific polymorphism of the Acc-1 locus in T. monococcum. A monogenic control was demonstrated for the spring growth habit of T. sinskajae, and the monogenic control of the specific T. sinskajae ear shape was verified. The T. sinskajae ear shape is controlled by a recessive gene, while the T. monococcum ear shape is controlled by a dominant gene. The T. sinskajae ear shape, nakedness, soft glume, aristate glume, and the oblique brachium of the outer glume proved to be linked. The set of E. sin-skajae diagnostic characters is determined by a single (possibly, regulatory) gene or a set of closely linked genes. The two other genes specific to T. sinskajae-awnS, determining the awnlessness, and fig, determining the nonfissile inner (flower) glume--are, respectively, 1.35 +/- 0.98 and 3.34 +/- 1.54% of crossing over away from the mom gene, which determines the T. sinskajae ear shape.     

A developmentally regulated lipocalin-like gene is overexpressed in Tomato yellow leaf curl virus-resistant tomato plants upon virus inoculation, and its silencing abolishes resistance

To discover genes involved in tomato resistance to Tomato yellow leaf curl virus (TYLCV), we previously compared cDNA libraries from susceptible (S) and resistant (R) tomato lines. Among the genes preferentially expressed in R plants and upregulated by TYLCV infection was a gene encoding a lipocalin-like protein. This gene was termed Solanum lycopersicum virus resistant/susceptible lipocalin (SlVRSLip). The SlVRSLip structural gene sequence of R and S plants was identical. SlVRSLip was expressed in leaves during a 15-day window starting about 40?days after sowing (20?days after planting). SlVRSLip was upregulated by Bemisia tabaci (the TYLCV vector) feeding on R plant leaves, and even more strongly upregulated following whitefly-mediated TYLCV inoculation. Silencing of SlVRSLip in R plants led to the collapse of resistance upon TYLCV inoculation and to a necrotic response along the stem and petioles accompanied by ROS production. Contrary to previously identified tomato lipocalin gene DQ222981, SlVRSLip was not regulated by cold, nor was it regulated by heat or salt. The expression of SlVRSLip was inhibited in R plants in which the hexose transporter gene LeHT1 was silenced. In contrast, the expression of LeHT1 was not inhibited in SlVRSLip-silenced R plants. Hence, in the hierarchy of the gene network conferring TYLCV resistance, SlVRSLip is downstream of LeHT1. Silencing of another gene involved in resistance, a Permease-I like protein, did not affect the expression of SlVRSLip and LeHT1; expression of the Permease was not affected by silencing SlVRSLip or LeHT1, suggesting that it does not belong to the same network. The triple co-silencing of SlVRSLip, LeHT1 and Permease provoked an immediate cessation of growth of R plants upon infection and the accumulation of large amounts of virus. SlVRSLip is the first lipocalin-like gene shown to be involved in resistance to a plant virus.     

甘蓝种质资源根肿病抗性鉴定及CRa、Crr1a同源基因分析

利用来源于湖北长阳、陕西太白、河南新野3个地方的根肿病菌对22份不同甘蓝材料进行抗病性鉴定。采用同源比对的方法,对甘蓝基因组中的大白菜抗根肿病同源基因CRa和Crr1a进行分析;同时对不同抗、感根肿病甘蓝材料中的CRa和Crr1a同源基因序列进行了扩增、测序和比对分析。结果表明:供试22份甘蓝材料对3份根肿病菌存在较大的抗感差异,推测来源于3个地区的菌种可能不是同一个生理小种;筛选出的抗性品种BDH3、Chou hybride Tekila、SW-110、CGL-8、先正达品种、SW-109将来可用作根肿病抗源和抗性基因挖掘;在甘蓝7号染色体上存在3个预测基因为CRa的同源基因,分别是Bo7g107710、Bo7g107730和Bo7g107740,其中,Bo7g107730基因在抗病材料SW-110存在较大的序列变异,推测可能与根肿病抗性相关;在甘蓝3号染色体上存在1个预测基因Bo3g164040为Crr1a的同源基因,所分析的抗、感病材料中Bo3g164040基因序列一致性极高,没有发现与抗根肿病有关的位点,说明甘蓝中Bo3g164040基因可能没有根肿病抗性功能。     

Screening for Barley yellow dwarf virus-Resistant Barley Genotypes by Assessment of Virus Content in Inoculated Seedlings

The content of Barley yellow dwarf virus (BYDV) in roots and leaves of barley seedling plants differing in their level of resistance was assessed by quantitative ELISA 1–42 days after inoculation with the strain of BYDV (PAV). High virus accumulation in roots and low concentration in leaves was characteristic of the period 9–15 days after inoculation. In leaves, the differences in virus content between resistant and susceptible genotypes became significant after 15 days and resistance to virus accumulation was better expressed 30–39 days after inoculation. Roots of resistant materials exhibited evident retardation of virus accumulation and the greatest difference in virus content between resistant and susceptible plants was detected 9 days after inoculation. By these criteria, the selected winter and spring barley cultivars and lines (in total 44 materials) fell in to five groups according to field reactions and the presence or absence of the Yd2 resistance gene. There were highly significant and positive relations between ELISA values and 5‐year field data on symptomatic reactions and grain‐yield reductions due to infection. Using the described method, resistant and moderately resistant genotypes (both Yd2 and non‐Yd2) were significantly differentiated from susceptible genotypes. The possible use of this method in screening for BYDV resistance is discussed.     

Application of PCR based diagnostics in the exploration of Parastagonospora nodorum prevalence in wheat growing regions of Himachal Pradesh

Stagonospora leaf and glume blotch (SLGB) of wheat caused by Parastagonospora nodorum (formerly Stagonospora nodorum) has recently emerged as a major problem in changing climatic conditions of Himachal Pradesh (HP), especially during delayed winter rains. In the present studies symptomatology, morpho-cultural as well as molecular marker based identification showed the prevalence of disease in the state and conclusively proved that leaf and glume blotch of wheat is caused by P. nodorum. The test pathogen showed 100% homology with other reported P. nodorum isolates by rDNA (ribosomal DNA) analysis. In addition, the amplification of rDNA region of 36 P. nodorum isolates representing various agro-ecological areas of HP and one infected wheat leaf sample generated an amplicon of ~ 449-bp with JB433 (5′-ACACTCAGTAGTTTACTACT-3′) and JB434 (5′-TGTGCTGCGCTTCAATA-3′) P. nodorum specific primer pair whereas no amplification was observed with the genomic DNA of Septoria titici, Stemphylium vesicarium and healthy wheat leaf sample. This study on integration of morpho-cultural and microscopic methods along with PCR based technique could form basis for routine diagnosis of the SLGB in wheat samples during early growth stages of crop in the seed production fields.