Comparing single- vs. mixed-genotype infections of Mycosphaerella graminicola on wheat: effects on pathogen virulence and host tolerance

Mixed-genotype infections (infections of a host by more than one pathogen genotype) are common in plant-pathogen systems. However their impact on the course of the infection and especially on pathogen virulence and host response to infection is poorly understood. We investigated the effects of mixed-genotype infections on several parameters: host resistance and tolerance, as well as pathogen aggressiveness and virulence. For these purposes, we inoculated three wheat lines with three Mycosphaerella graminicola genotypes, alone or in mixtures, in a greenhouse experiment. For some of the mixtures, disease severity and virulence were lower than expected from infection by the same genotypes alone, suggesting that competition between genotypes was reducing their aggressiveness and virulence. One host line was fully resistant, but there were differences in resistance in the other lines. The two host lines that became infected differed slightly in tolerance, but mixed-genotype infections had no effect on host tolerance.     

Plasmon analysis in wheat alloplasmic lines using morphological and chloroplast microsatellite markers

Inheritance of plant traits mainly depends upon nuclear genes, cytoplasmic factors and their interactions. In the present study, 32 alloplasmic lines accompanied by a euplasmic parental line (control) were evaluated using molecular (chloroplast microsatellite) and morpho-physiological traits during 2010–2011 and 2011–2012. The results of combined analysis of variance showed the significant effect of growing seasons on most of the studied traits as well as the significant effect of cytoplasm on plant height, leaf net CO₂ assimilation rate and grain yield per plant. Results of cluster analysis divided the six plasmons based on their phenotypic effects into three groups: (1) R and S^v type, D (Aegilops typica and Ae. ventricosa) and D² type, as well as B-type plasmon (euplasmic line); (2) a single plasmon of M type and three plasmons of B type; (3) all other B-type and a single D-type plasmon (Aegilops cylindrica). Molecular analysis showed that 20 primer pairs out of 26 chloroplastic microsatellite markers (cpSSR) produced polymorphic bands in the alloplasmic lines. A total of 50 alleles were identified with an average of 2.5 alleles per locus. In this study, polymorphism information content (PIC) ranged from 0.05 (WCt17 primer) to 0.49 (WCt9 primer). Cluster analysis of molecular data revealed that the alloplasmic lines belong to two major clusters, in which differentiation of cytoplasmic types belonging to the genus Triticum and Aegilops has been evident. Likewise, analysis of molecular variance showed significant differences between two studied groups (F _ST = 0.67, P < 0.001). Overall, our findings indicated that the cpSSR markers can be valuable resources of polymorphic markers for the analysis of cytoplasm of Triticeae species, with the potential for clear differentiation in close species and genera of this tribe.     

Synthetic hexaploid wheat enhances variation and adaptive evolution of bread wheat in breeding processes

Synthetic hexaploid wheat (SHW) that combines novel and elite genes from the tetraploid wheat Triticum turgidum L. and wild ancestor Aegilops tauschii Coss., has been used to genetically improve hexaploid common wheat. The abundant genetic diversity in SHW can effectively make breakthroughs in wheat genetic improvement through the inclusion of increased variation. In this paper, we reviewed the current advances in research and utilization of the primary SHW lines and SHW-derived wheat varieties that have enhanced evolution of modern wheat under conditions of natural and artificial selection in southwestern China. Using primary SHW lines, four high-yielding wheat varieties have been developed. In addition, using the SHW-derived varieties as breeding parents, 12 new wheat varieties were also developed. Results of genotype–phenotype and fingerprint analysis showed that the introgressed alleles from SHW lines have contributed a great number of elite characters to the new wheat varieties, and these elite characters include disease resistance, more spikes per plant, more grains per spike, larger grains, and higher grain-yield potential. We found that the primary SHW lines and SHW-derived varieties have identifiable effects to enhance genetic variation and adaptive evolution of modern hexaploid wheat, which significantly increased the grain yields of hexaploid wheat in recent years. These findings have significant implications in the breeding of high-yielding wheat varieties resistant to biotic and abiotic stresses using SHW as genetic resources.     

Tests for the presence of gametoclonal variation in barley and wheat doubled haploids produced using the Hordeum bulbosum system

Summary To investigate whether the Hordeum bulbosum system of doubled haploid production generates gametoclonal variation, populations of second generation doubled haploid lines were developed from first generation doubled haploid lines of two barley varieties and three wheat genotypes. In barley, no variation between doubled haploids from doubled haploids was detected for a range of quantitative characters, suggesting the absence of any gametoclonal effects. However, the original selfed-seed stocks were shown to contain cryptic allelic variation for some of the characters investigated. In wheat, gametoclonal variation was detected for ear emergence time, plant height and yield, and its components for two out of the three genotypes investigated. The type and range of variation was similar to that reported from studies of somaclonal variation from immature embryos and gametoclonal variation from anther culture. Generally, the effects appeared to reduce the yield performance of individual lines. The difference in response between the two species and the consequences for the use of the doubled haploid system in breeding programmes are discussed.     

The effect of wheat cytoplasm on the synthesis of wheat x rye hybrids

Summary Four nuclear genotypes of Triticum aestivum L., each substituted into the cytoplasm of T. timococcum Kostoff, Aegilops ventricosa Tausch and T. timopheevi Zhuk., were crossed with four homozygous Secale cereale L. inbred lines to produce 48 alloplasmic octoploid primary triticales. Crossability, embryo differentiation, amphihaploid plantlet recovery in vitro, and response to colchicine treatment were investigated. It was found that in general the effects of the wheat cytoplasm on the characteristics studied were of equal importance as those of the wheat and the rye nuclear genotypes. Cytoplasm can be regarded as an additional source of variation in the synthesis of primary triticales. Cross-compatibility in wheat x rye hybrids appeared to be determined by specific parental genotypes and their nucleo-cytoplasmic interactions rather than by any general compatibility of particular nuclear genotypes and/or cytoplasms.     

基因型与生态环境对小麦籽粒品质与蛋白质组分的影响

通过2年3点试验,研究了40个小麦(Triticum aestivum)品种(品系)籽粒品质性状和蛋白质组分含量的变异。结果表明,籽粒品质和蛋白质组分在基因型间存在较大的差异;根据小麦籽粒品质的综合性状,可将40个小麦品种(品系)分为6组不同的品质类型,在本试验点的生态环境条件下。基本以中筋及弱筋小麦为主;生态环境对小麦籽粒的容重、沉降值、湿面筋含量、蛋白质含量、赖氨酸含量与蛋白质组分含量均有极显著的影响,而面筋指数、淀粉含量和直链淀粉含量对环境反应不敏感,适宜的生态环境条件有利于形成合理的谷蛋白／醇溶蛋白比。面粉面筋质量好,基因型与生态环境的互作对小麦籽粒品质。谷蛋白与醇溶蛋白及两者的比值有显著影响,对球蛋白影响不大,而面粉蛋白质含量、面筋含量、沉降值及千粒重主要受基因的表达和环境的独立影响,蛋白质组分含量在基因型间和环境间的变化与小麦籽粒烘烤品质密切相关。     

Induction of small-segment-translocation between wheat and rye chromosomes

A new approach to produce wheat-rye translocation, based on the genetic instability caused by monosomic addition of rye chromosome in wheat, is described. 1 283 plants from the selfed progenies of monosomic addition lines with single chromosome of inbred rye line R12 and complete chromosome complement of wheat cultivar Mianyang 11 were cytologically analyzed on a plant-by-plant basis by the improved C-banding technique. 63 of the plants, with 2n = 42, were found containing wheat-rye translocation or substitution, with a frequency of 4. 91% . Compared with the wheat parent, other 32 plants with 2n = 42 exhibited obvious phenotypic variation, but their com-ponent of rye chromosome could not be detected using the C-banding technique. In situ hybridization with a biotin-la-beled DNA probe was used to detect rye chromatin and to determine the insertion sites of rye segments in the wheat chromosomes. In 20 out of the 32 variant wheat plants, small segments of rye chromosomes were found being inserted into dif     

Evolutionary features of chondriome divergence in Triticum (wheat) and Aegilops shown by RFLP analysis of mitochondrial DNAs

The first comprehensive analysis was made of restriction fragment length polymorphism (RFLP) of the mitochondrial (mt) DNA of two related genera, Triticum (wheat) and Aegilops. This led to clarification of the nature of mtDNA variability and the inference of the phylogeny of the mitochondrial genomes (=chondriome). Forty-six alloplasmic lines and one euplasmic line of common wheat (2n = 42, genomes AABBDD) carrying plasmons (cytoplasmic genomes) of 47 accessions belonging to 33 species were used. This consisted of nearly all the Triticum and Aegilops species. RFLP analysis, carried out with seven mitochondrial gene probes (7.0 kb in total) in combination with three restriction endonucleases, found marked variation: Of the 168 bands detected, 165 were variable (98.2%), indicative that there is extremely high mtDNA variability in these genera. This high variability is attributed to the variation present in the intergenic regions. Most of the variation was between chondriomes of different plasmon types; only 8 bands (4.8%) between those of the same plasmon types were variable, evidence of clear chondriome divergence between different plasmon types. The first comprehensive phylogenetic trees of the chondriome were constructed on the basis of genetic distances. All but 1 of the polyploids had chondriomes closely related to those of 1 putative parent, indicative of uniparental chondriome transmission at the time of polyploid formation. The chondriome showed parallel evolutionary divergence to the plastome (chloroplast genome). Use of a minimum set of 3 mtDNA probe-enzyme combinations is proposed for tentative plasmon type identification and the screening of new plasmon types in those genera. Received: 20 March 1999 / Accepted: 22 June 1999     

Comparison of homoeologous chromosome pairing between hybrids of wheat genotypes Chinese Spring ph1b and Kaixian-luohanmai with rye

The ph-like genes in the Chinese common wheat landrace Kaixian-luohanmai (KL) induce homoeologous pairing in hybrids with alien species. In the present study, meiotic phenotypic differences on homoeologous chromosome pairing at metaphase I between hybrids of wheat genotypes Chinese Spring ph1b (CSph1b) and KL with rye were studied by genomic in situ hybridization (GISH). The frequency of wheat-wheat associations was higher in CSph1b×rye than in KL×rye. However, frequencies of wheat-rye and rye-rye associations were higher in KL×rye than in CSph1b×rye. These differences may be the result of different mechanisms of control between the ph-like gene(s) controlling homoeologous chromosome pairing in KL and CSph1b. Wheat-wheat associations were much more frequent than wheat-rye pairing in both hybriods. This may be caused by lower overall affinity, or homoeology, between wheat and rye chromosomes than between wheat chromosomes.     

Effects of alien cytoplasmic variation on carbon assimilation and productivity in wheat

In glasshouse studies of four alloplasmic wheat series, phenotypic characters were least affected when the recipient parent cytoplasm was replaced by donor cytoplasm of the S or D plasmatype. In the T. aestivum cv. 'Selkirk' series, cytoplasm substitution did not affect Pmax per unit leaf area, although the flag leaf area (and photosynthetic rate per leaf) of each alloplasmic line was greater than that of euplasmic 'Selkirk'. In field trials, all the D plasmatype alloplasmics tested produced more ears m^-2 than did euplasmic 'Selkirk'. The increased tiller number and leaf area of alloplasmic lines resulted in greater canopy light interception than euplasmic 'Selkirk' early in the season. This characteristic was associated with reduced weed populations under crops of alloplasmic 'Selkirk' lines grown under low-, but not high-input, agronomic regimes, with Ae. cylindrica- and Ae. ventricosa-'Selkirk' significantly outyielding alloplasmic 'Selkirk' under low-input conditions. The F2 populations from crosses between European wheat varieties and 'Selkirk' lines exhibited higher standard deviations for grain yield for alloplasmic than for euplasmic 'Selkirk', suggesting potential for selecting heterotic nuclear-cytoplasmic combinations with alien cytoplasms.     

Genetic control of embryo lethality in crosses between common wheat and rye

The phenotypic manifestation and genetic control of embryo lethality observed in crosses between common wheat and rye were studied. It was found that crosses between common wheat and inbred self-fertile rye lines L2 and 535 gave rise to ungerminating grains, in which the development and differentiation of the hybrid embryo are arrested. Study of the degree of embryo development in the hybrid grains obtained by crossing common wheat varieties with inbred rye lines L2 and 535 showed that genotypes of the parents affected the ratio between undifferentiated embryos of various sizes. Analysis of this trait was performed by test crosses according to a novel pedigree program with the use of interlinear hybrids and a set of fourth-generation hybrid recombinant inbred lines. Rye line L2 was shown to bear the Eml (Embryo lethality) gene, which terminates the development of the hybrid embryo in amphihaploids. The suggestion of complementary interaction between wheat and rye genes during formation of a "n ew" character in wheat-rye F1 hybrids is discussed. A method of detecting an allele not complementary to the rye Eml allele in wheat is proposed. The proposed test program allows appropriate study of the system of wheat and rye genes involved in complementary interaction in the genotype of a distant hybrid.     

Introgression and characterization of barley yellow dwarf virus resistance from Thinopyrum intermedium into wheat.

Wheatgrasses (species of Agropyron complex) have previously been reported to be resistant to barley yellow dwarf virus (BYDV). To introgress this resistance into wheat, Triticum aestivum x Thinopyrum (Agropyron) intermedium hybrids were advanced through a backcrossing program and reaction to BYDV, as determined by enzyme-linked immunosorbent assay (ELISA), is reported for the first time in backcross populations of wide hybrids between wheat and wheatgrasses. ELISA values revealed highly resistant to highly susceptible segregants in backcrosses. BYDV resistance was expressed in some backcross derivatives. Continued selection, based on cytology and ELISA in each generation, eliminated most of the unwanted wheatgrass chromosomes and produced self-fertile BYDV resistant wheat lines. The BYDV resistant lines with 2n = 42 had normal chromosome pairing similar to wheat, and their F1 hybrids with wheat had two univalents. DNA analyses showed that the source of alien chromatin in these BYDV resistant wheat lines is distinguishable from that in other Th. intermedium derived BYDV resistant wheat lines. Chromosome pairing and restriction fragment length polymorphism analyses indicated that the 42 chromosome resistant Purdue wheat lines are substitution lines in which chromosome 7D was replaced by a chromosome from Th. intermedium that was carrying gene(s) for BYDV resistance.     

Production of near-isogenic lines and marked monosomic lines in common wheat (Triticum aestivum) cv. Chinese Spring.

Sixteen near-isogenic lines (NILs) carrying a marker gene were produced by the recurrent backcrossing method in the genetic background of common wheat (Triticum aestivum) cv. Chinese Spring (CS). Three genes from alien species showed segregation distortion. In NILs carrying a marker gene of rye (Secale cereale) or Aegilops caudata, the alien chromosome segments were detected by fluorescence in situ hybridization (FISH). The NILs were grown with replications and the effect of marker genes on plant morphology in the genetic background of CS was investigated. These NILs were further crossed with the corresponding monosomics of CS and 13 monosomic lines whose monosome carries a respective marker gene were established and named "marked monosomics." Many of the marked monosomics were distinguishable from the disomic NILs because of the different dosage effect of the genes. The NILs are utilized for studies on gene isolation or gene regulation. Marked monosomics are useful not only for monosomic analysis but also for production of homologous chromosome substitution lines because chromosome observation is not required.     

抗茎腐病转基因小麦新种质的筛选

为拓宽小麦茎腐病(又称茎基腐病)抗源种类,筛选抗茎腐病小麦新种质,对43份转TaPIMP1、AtNPR1和Gastrodianin基因小麦纯合株系,进行目的基因表达分析,以及茎腐病、纹枯病和赤霉病抗性鉴定。结果表明,转基因株系的目的基因均能正常表达;转基因株系间茎腐病抗性差异明显,24份转基因株系茎腐病抗性,比受体对照扬麦12显著提高;转基因株系茎腐病抗性与纹枯病抗性相关性显著,与赤霉病相关性不显著。结合农艺性状鉴定,筛选出5份抗茎腐病转基因株系,其中2份兼抗纹枯病和赤霉病,1份兼抗纹枯病,可作为长江中下游麦区茎腐病备用抗源。     

Differential sensitivities of transpiration to evaporative demand and soil water deficit among wheat elite cultivars indicate different strategies for drought tolerance

In order to satisfy increasing wheat demands, scaling up wheat production will require boosting yield in suboptimal, drought-prone areas. Under rain-fed environments, one promising option is the identification of traits allowing for soil water conservation until the next rain episode. This can be achieved either by limiting transpiration rate (TR) of the crop to a maximum level when atmospheric drought (or VPD for vapor pressure deficit) is too high or by decreasing stomata conductance earlier in the soil drying cycle. Although promising, those strategies were never explored in wheat. A first objective of this study was to investigate the extent of the genetic variability of TR sensitivity to both VPD and soil water deficit among a group of eight elite wheat lines, which are cultivated under south Australian conditions. Those consisted of seven differentially drought-adapted lines and one check cultivar. TR responses to VPD were highly variable among genotypes, with six lines displaying a breakpoint in their TR response to VPD that ranged from 2.4 to 3.9 kPa, while two others had their TR increasing linearly as VPD increased. Transpiration response to a progressively decreasing fraction of transpirable soil water (FTSW) was investigated in those lines. A significant genetic variability in the responses among genotypes was observed. They revealed different FTSW thresholds at which transpiration started to decrease at levels ranging from 0.43 to 0.52, and different slopes for the decrease. A second objective was to investigate the existence of phenotypic correlations between the parameters characterizing transpiration sensitivities to both sources of water deficit (i.e., VPD and FTSW). Significant correlations were observed revealing that genotypes with conservative water use in their response to high VPD were also conservative in response to decreasing FTSW and that the drought tolerance of other lines might stem from an apposite strategy, invoking decreased sensitivity of TR to both sources of drought. Those findings provide new options for breeding drought tolerant lines based on this germplasm.     

Introgression of <Emphasis Type="Italic">Aegilops mutica</Emphasis> genes into common wheat genome

Introgression of genetic material from wheat wild relatives into the common wheat genome remains important. This is a natural and inexhaustible source of enrichment of the wheat gene pool with genes that improve wheat’s adaptive potential. Hexaploid lines F₄–F₅ of wheat type were developed via hybridization of common wheat Aurora (AABBDD) and genome-substituted amphidiploid Aurotica (AABBTT). The hexaploid genome of the latter includes the diploid genome TT from wheat relative Aegilops mutica instead of subgenome DD of common wheat. F₁–F₃ hybrids had limited self-fertility, which had substantially increased for some derivatives in F₄–F₅. For all generations, development of the lines was accompanied by cytogenetic control of the chromosome numbers. The chromosome numbers varied in general from 33 to 46 depending upon generation. In most descendants, that number was 42 chromosomes in F₄ when plants with chromosome numbers 40–44 were selected in each generation. F₅ lines originate from nine selffertile F₂ plants, differ from Aurora according to some morphological characters, and have alien DNA in their genome as was demonstrated by DNA dot-blot hybridization with genomic DNA of Aegilops mutica as a probe.     

Genetic analysis of anthocyanin of the anthers and culm pigmentation in common wheat

Anthocyanin pigmentation of various organs develops during plant ontogeny in response to adverse and damaging abiotic and biotic stressors (environmental factors). Using the monosome method, the genes responsible for anther and culm anthocyanin pigmentation (Pan1 and Pc2, respectively) were localized to 7D chromosome in introgressive lines from crosses between common wheat Triticum aestivum L. and the species Triticum timopheevii Zhuk. Genetic analysis of ten common wheat genotypes using testers carrying genes Pan1, Pn1, and Pn2 showed that these genotypes contained Pan1 and Pn2 genes. Visual examination of plants from 70 and 76 varieties of respectively winter and spring common wheat revealed anthocyanin pigmentation of anthers and culms in 36 varieties. Pan1 and Pn2 genes were presumably introduced into common wheat from Aegilops tauschii (Fig.) Tzvel., a donor of the D genome.     

Cytogenetic analysis of hybrids resistant to yellow rust and powdery mildew obtained by crossing common wheat (Triticum aestivum L., AABBDD) with wheat of the Timopheevi group (AtAtGG)

The karyotypes of 47 hybrid lines obtained from crosses of common wheat Triticum aestivum L. (cv. Rodina and line 353) with Triticum timopheevii Zhuk, (AtAtGG) and related species T. militinae Zhuk. et Migusch. (AtAtGG) and T. kiharae Dorof. et Migusch. (AtAtGGDsqDsq) were analyzed by C-banding. Most lines were resistant to yellow rust and powdery mildew. The introgression of alien genetic material to the common wheat genome was realized via substitutions of complete At-, G-, and D-genome chromosomes, chromosome arms, or their fragments. The pattern of chromosome substitutions in resistant lines differed from that in introgressive hybrids selected for other traits. Substitutions of chromosomes 6G, 2At, 2G, and 5G were revealed in 31, 23, 18, and 13 lines, respectively. Substitutions of chromosomes 4G-, 4At, and 6At were not observed. In 15 lines, a 5BS. 5BL-5GL translocation was identified. High frequency of substitutions of chromosomes 2At, 2G, 5G, and 6G indicate that they may carry the resistance genes and that they are closely related to the respective homoeologous chromosomes of common wheat that determines their high compensation ability.     

RAPD-PCR analysis of the variability of spring common wheat cultivar genomes and their androclinal double haploid form

Based on RAPD-PCR analysis with 15 primers including those homologous to particular loci, the level of genetic polymorphism in the collection of spring common wheat genotypes and their androclinal double haploid (ADH) lines was determined. Intraspecific polymorphism of the original wheat forms was 20%. By the absence of polymorphism in the molecular patterns of ADH lines and original forms, it was shown that, under the conditions used, no genetic changes in the genomic DNA of spring common wheat in anther culture occurred. Thus, the technology of direct in vitro androgenesis does not lead to genome rearrangements and may be used for rapid production of pure lines of such a complex allopolyploid as spring common wheat.