The Effect of Speckled Leaf Blotch on Apical Development and Yield in Winter Wheat in New Zealand

Speckled leaf blotch (Mycosphaerella graminicola) reduced yieldin a winter wheat trial by 18 per cent. Detailed analyses ofthe effects of disease on yield components showed that diseasereduced both grain number per ear and grain weight. The reductionin grain number per ear was due to a decrease in grain numberper spikelet, and this occurred for both main stem and tillers,and occurred equally at each spikelet position on the ear. The effect of disease on grain number was traced back to anearlier reduction in floret primordium number per ear, especiallyfloret number per spikelet. It was suggested that floret primordiumproduction was affected by the reduced assimilate supply tothe developing apex. The effects of disease on yield could therefore be attributedto effects on plant development both before and after anthesis.The disease effects on yield were not necessarily associatedwith the time of maximum disease severity. Plots with the early phase of disease epidemic only showed asignificant reduction in yield, but there was some evidenceof compensation for early reductions to yield potential in thelater-determined yield components. We suggest, therefore, thatan effective disease-control programme must take into accountthe possible early effects of disease on yield potential. Mycosphaerella graminicola, speckled leaf blotch, winter wheat, yield loss, apical development     

Mycosphaerella graminicola: from genomics to disease control

This Mycosphaerella graminicola pathogen profile covers recent advances in the knowledge of this ascomycete fungus and of the disease it causes, septoria tritici blotch of wheat. Research on this pathogen has accelerated since publication of a previous pathogen profile in this journal in 2002. Septoria tritici blotch continues to have high economic importance and widespread global impact on wheat production. Taxonomy: Mycosphaerella graminicola (Fuckel) J. Schröt. In Cohn (anamorph: Septoria tritici Roberge in Desmaz.). Kingdom Fungi, Phylum Ascomycota, Class Loculoascomycetes (filamentous ascomycetes), Order Dothideales, Genus Mycosphaerella, Species graminicola. Host range: Bread and durum wheat (Triticum aestivum L. and T. turgidum ssp. durum L.). Disease symptoms: Initially leaves develop a chlorotic flecking, which is followed by the development of necrotic lesions which contain brown–black pycnidia. Necrosis causes a reduction in photosynthetic capacity and therefore affects grain yield. Disease control: The disease is primarily controlled by a combination of resistant cultivars and fungicides. Rapid advances in disease control, especially in resistance breeding, are opening up new opportunities for the management of the disease. Useful websites: http://genome.jgi‐psf.org/Mycgr3/Mycgr3.home.html .     

MAP kinase signalling pathway components and targets conserved between the distantly related plant pathogenic fungi Mycosphaerella graminicola and Magnaporthe grisea

Mycosphaerella graminicola is a dimorphic fungus which causes Septoria tritici leaf blotch. This report describes the examination of the role of several components of the Pmk1p/Fus3p mitogen-activated protein kinase (MAPK) signalling pathway in the development of this species. The genes encoding the MAPK kinase kinase MgSte11p and the MAPK kinase MgSte7p were found to be indispensible for pathogenicity while the deletion of the gene encoding the proposed scaffold protein MgSte50p led to a reduction in virulence. These phenotypes were attributed to a reduced ability to form filaments on the plant surface which prevented penetration. A delayed disease progression was observed on deletion of the gene MGSTE12. The MGSTE7, MGSTE50 and MGSTE12 genes were able to complement mutants of Magnaporthe grisea lacking the orthologous genes. Interactions between the My. graminicola signalling components were also investigated. Furthermore genes whose MgSte12p/Mst12p dependence is conserved between My. graminicola and Ma. grisea were identified.     

Nitrate Supply and the Biophysics of Leaf Growth in Salix viminalis

The influence of nitrogen on leaf area development and the biophysicsof leaf growth was studied using clonal plants of the shrubwillow, Salix viminalis grown with either optimal (High N) orsub-optimal (Low N) supplies of nitrate. Leaf growth rate andfinal leaf size were reduced in the sub-optimal treatment andthe data suggest that in young rapidly growing leaves, thiswas primarily due to changes in cell wall properties, sincecell wall extensibility (% plasticity) was reduced in the LowN plants. The biophysical regulation of leaf cell expansion also differedwith nitrogen treatment as leaves aged. In the High N leaves,leaf cell turgor pressure (P) increased with age whilst in theLow N leaves P declined with age, again suggesting that foryoung leaves, cell wall plasticity limited expansion in theLow N plants. Measurements of cell wall properties showed thatcell wall elasticity (%E) was not influenced by nitrogen treatmentand remained constant regardless of leaf age. Key words: Salix, cell wall extensibility, nitrogen nutrition, biophysics of leaf growth     

Chromosomal location of a gene for resistance to septoria tritici blotch (Mycosphaerella graminicola)in the hexaploid wheat ’Synthetic 6x’

Septoria tritici blotch, caused by the fungus Mycosphaerella graminicola,is currently the major foliar disease of wheat world-wide, and new sources of resistance and knowledge about the genetics of resistance are needed to improve breeding for resistance to this disease. Sears’s ’Synthetic 6x’ hexaploid wheat, derived from a hybrid of Triticum dicoccoides and Triticum tauschii, was resistant to 12 of 13 isolates of M. graminicola tested. Chromosome 7D of ’Synthetic 6x’ was identified as carrying resistance to all 12 isolates in tests of seedlings of inter-varietal chromosome substitution lines of ’Synthetic 6x’ into ’Chinese Spring’ and to two isolates in tests of adult plants. A septoria tritici blotch resistance gene, named Stb5, was identified using the M. graminicola isolate IPO94269 and mapped on the short arm of chromosome 7D, near the centromere, in a population of single homozygous chromosome-recombinant lines for the 7D chromosome. Received: 1 February 2001 / Accepted: 17 April 2001     

New capabilities for Mycosphaerella graminicola research

Mycosphaerella graminicola is a major pathogen of wheat worldwide, causing Septoria leaf blotch disease. Targeted gene disruption in M. graminicola, by Agrobacterium tumefaciens‐mediated transformation, has become an established functional genomics tool for M. graminicola research in recent years. However, in order to advance research into this economically important pathogen, further functional genomics tools need to be developed. Here, we report three new capabilities for M. graminicola research: (i) two selectable markers have been shown to work robustly in M. graminicola, namely G418 and the fungicide carboxin; (ii) the generation of a strain of M. graminicola in which the KU70 (MUS‐51) homologue has been disrupted; in this strain, homologous recombination efficiencies increased to more than 95%, whilst maintaining wild‐type growth in vitro and full pathogenicity on wheat leaves; (iii) the ability to efficiently target and generate precise mutations of specific genes in the genomic context in M. graminicola. In addition, the insertion of the E198A mutation into the β‐tubulin gene (MgTUB1), conferring resistance to the fungicide benomyl, suggests that this mutant allele may provide an additional selectable marker. The collective use of these tools will permit further advancements in our knowledge of the biology and pathogenicity of this important plant pathogen.     

The Effect of Rooting Space on Whole Plant and Leaf Growth in Brussels Sprouts (Brassica oleracea var. gemmifera)

Seedlings of Brassica oleracea var. gemmifera DC. (Brusselssprouts) were grown in four pot sizes over a 4-week period.Whole plant, stem, root and foliage d. wts and foliage area,together with specific leaf area, leaf area ratio and numberof leaves initiated were reduced by restricting rooting space.Individual leaves showed similar reductions in d. wt and area,with the effect being more pronounced in later-formed leaves.Cell counts and measurements on the epidermis and palisade mesophylllayers of the first four leaves showed that the reduction ingrowth was due to reduced cell division. Cell numbers in thefirst-formed leaf were halved over the range of pot sizes used,and there was a progressively greater reduction in cell numbersin later-formed leaves. There was some tendency for cell sizeto decrease with decreasing rooting space, but this was notgeneral and was most marked between plants grown in the twosmallest pot sizes. Brassica oleracea var. gemmifera, Brussels sprouts, rooting space, growth analysis, leaf growth, cell numbers, cell sizes     

Changing Sink Demand Affects the Area but not the Specific Activity of Assimilate Sources in Cantaloupe (Cucumis meloL.)

To better understand source-sink interactions, this work focusedon the influence of fruit number on leaf area and photosyntheticactivity in cantaloupe. To this end, flowers were removed over2 years on two Charentais cultivars to obtain single-fruit plantsand plants with an unrestricted fruit load (which set two tofive fruits and constituted control plants). At the whole plantscale, net photosynthesis was reduced by about 30% under highfruit load. At the leaf scale, a submodel of stomatal conductancewas fitted to the data and was included in a rectangular hyperbolamodel of leaf photosynthesis. Maximum leaf net photosynthesisaveraged 14.83 µmol CO₂m^-2s^-1at 1000 µmol quantam^-2s^-1. Light use efficiency was not affected by fruit loadand equalled 0.040 mol CO₂mol^-1quanta. Leaf area of plants withunrestricted fruit load decreased after 24 days from pollination,while the leaf area of single-fruit plants was still increasing.The decrease was due to production of fewer new leaves per day,whereas the number of senescent leaves and the size of individualleaves were not affected by the treatment. Under high fruitload, cultivar Galoubet developed a larger projected leaf areathan cultivar Talma. Thus it is concluded that: (1) large cantaloupefruits may divert a large amount of assimilates away from, andgrow at the expense of, the canopy; and (2) photosynthesis ofthe canopy was lowered because leaf area was reduced whereasphotosynthetic rate of leaves was not altered.Copyright 1998Annals of Botany Company. Cucumis meloL., fruit load, source-sink interactions, leaf photosynthesis, canopy photosynthesis, leaf area, SLA, source strength.     

Late foliar diseases in wheat crops decrease nitrogen yield through N uptake rather than through variations in N remobilization

Background and Aims

French wheat grains may be of little value on world markets because they have low and highly variable grain protein concentrations (GPC). This nitrogen-yield to yield ratio depends on crop nitrogen (N) fertilization as well as on crop capacity to use N, which is known to vary with climate and disease severity. Here an examination is made of the respective roles that N remobilization and post-anthesis N uptake play in N yield variations; in particular, when wheat crops (Triticum aestivum) are affected by leaf rust (Puccinia triticina) and Septoria tritici blotch (teleomorph Mycosphaerella graminicola).

Methods

Data from a 4-year field experiment was used to analyse N yield variations in wheat crops grown either with a third or no late N fertilization. Natural aerial epidemics ensured a range of disease severity, and fungicide ensured disease-free control plots. The data set of Gooding et al. (2005, Journal of Agricultural Science 143: 503–518) was incorporated in order to enlarge the range of conditions.

Key Results

Post-anthesis N uptake accounted for a third of N yield whilst N remobilization accounted for two-thirds in all crops whether affected by diseases or not. However, variations in N yield were highly correlated with post-anthesis N uptake, more than with N remobilization, in diseased and also healthy crops. Furthermore, N remobilization did not significantly correlate with N yield in healthy crops. These findings matched data from studies using various wheat genotypes under various management and climatic conditions. Leaf area duration (LAD) accurately predicted N remobilization whether or not crops were diseased; in diseased crops, LAD also accurately predicted N uptake.

Conclusions

Under the experimental conditions, N yield variations were closely associated with post-anthesis N uptake in diseased but also in healthy crops. Understanding the respective roles of N uptake and N remobilization in the case of diseased and healthy crops holds the promise of better modelling of variations in N yield, and thus in GPC.Key words: Triticum aestivum, Puccinia triticina, leaf rust, Mycosphaerella graminicola, Septoria tritici blotch, N uptake, N remobilization, N yield, Leaf area duration     

Effect of Verticillium dahliae on Photosynthesis, Leaf Expansion and Senescence of Field-grown Sunflower

On the basis of known sunflower (Helianthus annuus L.) responsesto soil water deficit, it is proposed that the effect of thefungus Verticillium dahliae Klebahn on plant leaf area precedesand is greater than its effect on leaf photosynthesis and stomatalconductance. To test this hypothesis, we measured shoot andleaf area growth, leaf photosynthetic rate, stomatal conductanceand disease symptoms in a field experiment including hybridsof high (Sankol) and low (Dekasol 3900) susceptibility to V.dahliae. Plants inoculated with V. dahliae and controls werecompared. We also investigated the effect of V. dahliae on keycomponents of plant leaf area, leaf expansion and senescence,in inoculated and control plants of Sankol and Toba, a hybridof intermediate susceptibility to V. dahliae. Reduction in plantleaf area caused by V. dahliae was first detected 31 d afterinoculation (DAI), when visual symptoms of disease in inoculatedplants were slight (Sankol) or absent (Dekasol 3900). Reductionin leaf photosynthesis was first observed 66 DAI; stomatal conductanceand leaf dark respiration were both unaffected by V. dahliaeduring the whole experiment. In comparison with controls, V.dahliae reduced seasonal duration of plant leaf area by 25%in Dekalb 3900 and by 55% in Sankol, whereas the average reductionin leaf photosynthetic rate was 9%. In correspondence with thereduction in leaf area duration, inoculation reduced shoot drymatter of mature Sankol by 50%. In both experiments, less leafexpansion accounted for most of the early reduction in plantleaf area; as the disease progressed, increasing senescencealso contributed to reduced plant leaf area. It is concludedthat the response of sunflower to V. dahliae resembled the responseof the plant to soil water deficit: (1) plant leaf area, ratherthan leaf photosynthetic rate, accounted for the reduction ingrowth in mass; and (2) reduced leaf expansion early in theseason and faster leaf senescence in older plants accountedfor the decrease in plant leaf area. Copyright 2000 Annals ofBotany Company Helianthus annuus, Verticillium dahliae, allometry, apical dominance, drought, leaf expansion, leaf senescence, photosynthesis, stomatal conductance, growth     

Risk assessment studies on succinate dehydrogenase inhibitors, the new weapons in the battle to control Septoria leaf blotch in wheat

Chemical control of Septoria leaf blotch, caused by Mycosphaerella graminicola, is essential to ensure wheat yield and food security in most European countries. Mycosphaerella graminicola has developed resistance to several classes of fungicide and, with the efficacy of azoles gradually declining over time, new modes of action and/or improvements in host varietal resistance are urgently needed to ensure future sustainable disease control. Several new‐generation carboxamide fungicides with broad‐spectrum activity have recently been introduced into the cereal market. Carboxamides inhibit succinate dehydrogenase (Sdh) of the mitochondrial respiratory chain (complex II) but, because of their single‐site specificity, these fungicides may be prone to resistance development. The objective of this study was to assess the risk of resistance development to different Sdh inhibitor (SDHI) fungicides in M. graminicola. UV mutagenesis was conducted to obtain a library of carboxin‐resistant mutants. A range of SDHI resistance‐conferring mutations was found in Sdh subunits B, C and D. Pathogenicity studies with a range of Sdh variants did not detect any fitness costs associated with these mutations. Most of the amino acid residues identified (e.g. B‐S221P/T, B‐H267F/L/N/Y, B‐I269V and D‐D129E/G/T) are directly involved in forming the cavity in which SDHI fungicides bind. Docking studies of SDHI fungicides in structural models of wild‐type and mutated Sdh complexes also indicated which residues were important for the binding of different SDHI fungicides and showed a different binding for fluopyram. The predictive power of the model was also shown. Further diagnostic development, enabling the detection of resistant alleles at low frequencies, and cross‐resistance studies will aid the implementation of anti‐resistance strategies to prolong the cost‐effectiveness and lifetime of SDHI fungicides.     

Defining the Predicted Protein Secretome of the Fungal Wheat Leaf Pathogen Mycosphaerella graminicola

The Dothideomycete fungus Mycosphaerella graminicola is the causal agent of Septoria tritici blotch, a devastating disease of wheat leaves that causes dramatic decreases in yield. Infection involves an initial extended period of symptomless intercellular colonisation prior to the development of visible necrotic disease lesions. Previous functional genomics and gene expression profiling studies have implicated the production of secreted virulence effector proteins as key facilitators of the initial symptomless growth phase. In order to identify additional candidate virulence effectors, we re-analysed and catalogued the predicted protein secretome of M. graminicola isolate IPO323, which is currently regarded as the reference strain for this species. We combined several bioinformatic approaches in order to increase the probability of identifying truly secreted proteins with either a predicted enzymatic function or an as yet unknown function. An initial secretome of 970 proteins was predicted, whilst further stringent selection criteria predicted 492 proteins. Of these, 321 possess some functional annotation, the composition of which may reflect the strictly intercellular growth habit of this pathogen, leaving 171 with no functional annotation. This analysis identified a protein family encoding secreted peroxidases/chloroperoxidases (PF01328) which is expanded within all members of the family Mycosphaerellaceae. Further analyses were done on the non-annotated proteins for size and cysteine content (effector protein hallmarks), and then by studying the distribution of homologues in 17 other sequenced Dothideomycete fungi within an overall total of 91 predicted proteomes from fungal, oomycete and nematode species. This detailed M. graminicola secretome analysis provides the basis for further functional and comparative genomics studies.     

Virulence Spectrum of Mycosphaerella graminicola Isolates on Wheat Genotypes Carrying Known Resistance Genes to Septoria tritici Blotch

The virulence spectrum of 23 monopycnidiospore isolates of Mycosphaerella graminicola was determined using wheat genotypes that carried different resistance genes (Stb1–Stb8 and Stb15). Disease severity was measured as the percentage of necrotic leaf area. The isolates used in the experiments were of diverse origin: eight from Poland, seven from Germany, and eight from other countries around the world. Analysis of variance revealed significant differences in the virulence of the isolates. Using multiple regression and Cook’s D statistic, 26 significant cultivar × isolate interactions were detected. The Israeli isolate IPO86036 showed the widest spectrum of specific reactions. It expressed specific virulence on at least four cultivars and specific avirulence on at least three. The other isolates showed specific interactions with 1–6 different cultivars. Despite the limited number of isolates that were tested, we recommend that a number of resistant lines, namely cultivars Veranopolis (Stb2), Cs/Synthetic 7D (Stb5), Arina (Stb15, Stb6 and partial resistance), and Liwilla (unknown resistance factors), could be incorporated into central European wheat breeding programmes that are aimed at developing resistance against septoria tritici blotch. In contrast, resistance gene Stb7, which is carried by cultivar Estanzuela Federal, was ineffective against most of the isolates that were used. These results on the virulence spectrum of M. graminicola isolates provide valuable information for effective wheat breeding programmes to develop resistance to the pathogen.     

Studies in the Nutrition of Apple Rootstocks: 1. Effects of Deficiencies of Iron and Magnesium on Growth

Plants of the apple rootstock M.VII were grown for a singleseason by spraying their roots continuously with nutrient solutions:(a) complete, (b) low iron, (c) low magnesium, and (d) low ironand low magnesium. Detailed records were taken throughout theseason of fresh weight, shoot length, diameter, and leaf area,while the fresh and dry weights of component parts were determinedon harvested samples. The leaves of the iron-deficient plants were chlorotic and hada lower dry weight and higher water content per unit area thanthose of the control plants. Growth and net assimilation ratewere both reduced but the distribution of assimilates was similarto that in the controls. Total growth was also markedly reduced by the low-magnesiumtreatment, but the leaf symptoms were different and the plantswere morphologically distinct from the control plants. Verylittle chlorosis occurred, but necrosis and severe defoliation,progressing up the shoot, reduced the leaf area ratio and probablylargely accounted for the low net assimilation rate and relativegrowth rate. The diameter of the shoot was affected much morethan its length and the shoot/root ratio was greatly increased. Plants deficient in both iron and magnesium showed less defoliationthan when magnesium alone was low. More dry matter accumulatedin the old stem and less in the new shoot than would have occurredwith a simple combination of the single deficiencies.     

The Effects of Infection by Rust (Puccinia lagenophorae Cooke) on the Growth of Groundsel (Senecio vulgaris L.) Cultivated under a Range of Nutrient Concentrations

Groundsel (Senecio vulgaris L.), healthy or infected with therust fungus Puccinia lagenophorae Cooke, was grown at a rangeof nutrient concentrations in sand culture. There were statisticallysignificant interactions between the effects of infection andnutrient supply upon the dry weights of stems, leaves, rootsand reproductive tissues, leaf area and cumulative capitulumproduction. This interaction occurred since infection causedsignificant inhibitions of growth only at moderate or high nutrientconcentrations. At low concentrations rusted plants were similarto or slightly larger than controls. Both in controls and rustedplants root: shoot ratios increased as nutrient supply declined.The ratio of root: shoot dry weight was consistently reducedby infection whilst root length: leaf area ratio was relativelyunchanged. More detailed investigations confirmed that infection had littleeffect on plant growth under nutrient deficient conditions despitesuppression of the host's ability to increase root: shoot ratiosin response to nutrient stress. This reflected the inhibitionof relative growth rates in rusted plants at high but not lownutrient concentrations, which in turn reflected reduced netassimilation rates (NAR). Increases in leaf-area ratio (LAR)often ameliorated the decline in NAR in rusted plants. Senecio vulgaris L., Puccinia lagenophorae Cooke, nutrient deficiency, growth, root: shoot ratio     

Leaf Growth in Dactylis glomerate following Defoliation

Defoliation to a height of 2.5 cm considerably reduced the increasein leaf area in young Dactylis glomerata (cocksfoot) plantscompared with that of intact plants, the reduction in the rateof appearance of new leaves being relatively greater than thereduction in expansion of existing leaves. The growth of thoseexpanding leaves which were cut during defoliation accountedfor 94 per cent of the total increase in leaf area during thefirst four days after defoliation. In such a leaf, expandingcells were confined to a basal section which was well belowthe ligule of the enclosing fully expanded leaf. There was a positive relationship between rate of leaf expansionand total soluble carbohydrate content of the stubble when thecarbohydrate content was varied by placing the plants in thedark, but not when it was varied by defoliation and subsequentgrowth. These and other results suggest that the concentrationof soluble carbohydrate in the bases of expanding leaves wasa factor controlling leaf expansion following defoliation, andthat the concentration in any one leaf depended on the photosyntheticcontribution from its exposed portion. When the external nutrient supply was high, removal of the laminaeof fully expanded leaves, which comprised about two-thirds ofthe total leaf area, did not reduce leaf expansion. When thenutrient status was low, these leaves were of primary importance,presumably because of their role as a source of labile nutrients.     

The effect of 1-methylcyclopropene on the components of pro- and antioxidant systems of wheat and the development of defense reactions in fungal pathogenesis

The effect of 1-methylcyclopropene (1-MCP), which inhibits the reception of ethylene, on the following has been studied: hydrogen peroxide generation, oxalate oxidase activity, peroxidase activity, catalase activity, and lignin accumulation in infected leaves of soft spring wheat (Triticum aestivum L.) cultivars that differ in their resistance to the leaf blotch disease, caused by the hemibiotrophic fungus Septoria nodorum Berk. A decrease in the development of leaf blotch in wheat leaves under the influence of 1-MCP was, on one hand, followed by an inhibition of catalase activity; on the other hand, it was accompanied by an increase in oxalate oxidase and peroxidase activity, as well as an accumulation of H₂O₂ in tissues and lignin in the infected zone. The role of the ethylene reception system in the defense response of plants to infection with a hemibiotrophic pathogen, that causes leaf blotch disease, is discussed.     

Molecular Variability of Mycosphaerella graminicola as Detected by RAPD Markers

A total of 90 isolates of Mycosphaerella graminicola, the cause of septoria tritici leaf blotch of wheat, were tested for DNA polymorphism using 15 decamer random primers. There was a high level of genetic variability among isolates. In 131 random amplified polymorphic DNA (RAPD) fragments, which were produced, 96% were polymorphic. Based on multilocus analysis, 40 different molecular phenotypes were detected. These molecular phenotypes were randomly distributed among sampling sites, suggesting that no clonal structure existed in the population. Cluster analysis showed that the maximum similarity value among isolates was approximately 81% and no identical isolates were detected, indicating that every isolate was a unique genotype. The high degree of DNA polymorphism, the large number of different molecular phenotypes, their random distribution and the results of the cluster analysis all suggested that sexual reproduction has a major role in the genetic structure of M. graminicola in western Canada. The presence of sexual reproduction provides the opportunity for development of new virulent genotypes in the population and suggests that the pathogen may adapt rapidly to any race‐specific sources of resistance. Therefore, when breeding for resistance to M. graminicola, emphasis should be placed on use of non‐race‐specific resistance.     

Effects of Abscisic Acid on Growth of Wheat (Triticum aestivum L)

Daily application of abscisic acid (ABA) to growing wheat plants,although initially inhibiting growth, resulted, after a shortlag, in an increase in the number of leaves and tillers. Thismay have been due to reduced apical dominance. At 84 days thetotal dry weight and area of all leaves produced up to thistime was less for the plants treated with ABA than for the controlplants. However, the area of green, living leaves and the dryweight were not significantly affected by the ABA treatment.Further effects of the daily ABA treatment were the inhibitionof transpiration, especially on the abaxial surface, the reductionof leaf size, the promotion of flowering and the stimulationof trichome formation on the leaf surfaces. ABA did not promoteleaf senescence in whole plants and actually increased leaflongevity. Triticum aestivum L., wheat, leaf senescence, transpiration, growth, flowering, abscisic acid     

Chromosomal location of a race-specific resistance gene to <Emphasis Type="Italic">Mycosphaerella graminicola</Emphasis> in the spring wheat ST6

Septoria tritici blotch, caused by Mycosphaerella graminicola, is a serious foliar disease of wheat worldwide. Qualitative, race-specific resistance sources have been identified and utilized for resistant cultivar development. However, septoria tritici blotch resistant varieties have succumbed to changes in virulence of M. graminicola on at least three continents. The use of resistance gene pyramids may slow or prevent the breakdown of resistance. A clear understanding of the genetics of resistance and the identification of linked PCR-based markers will facilitate the recovery of wheat lines carrying multiple septoria tritici blotch resistance genes. The resistance gene in ST6 to isolate MG2 of M. graminicola was mapped with microsatellite markers in two populations, ST6/Erik and ST6/Katepwa. Bulk segregant analysis identified a marker on chromosome 4AL putatively linked to the resistance gene. A large linkage group was identified in each population using additional microsatellite markers mapping to chromosome 4AL. The resistance gene in ST6 mapped to the distal end of chromosome 4AL in each mapping population and was designated Stb7. Three of the microsatellite loci, Xwmc313, Xwmc219 and Xgwm160, mapped within 3.5 cM of Stb7; however, none flanked Stb7. Xwmc313 was the closest and mapped 0.3 and 0.5 cM from Stb7 in the crosses ST6/Katepwa and ST6/Erik, respectively. WMC313 will be very useful for marker-assisted selection of Stb7 in Canadian breeding programs because the ST6 allele of Xwmc313 was not identified in any of the Canadian common wheat cultivars tested.Communicated by P. Langridge