Common resistance to Fusarium head blight in Brazilian wheat cultivars

Mendes, Gabriela da Rocha Lemos; Ponte, Emerson Medeiros Del; Feltrin, Ana Carla; Badiale-Furlong, Eliana; Oliveira, Antônio Costa de

doi:10.1590/1678-992X-2016-0407

ABSTRACT:

Mycotoxin levels in Fusarium head blight (FHB) infections can be difficult to quantify. The relationship between mycotoxin and disease is not consistent and it is not clear if wheatpathogen interaction is of significance in regions where more than one Fusarium species with distinct trichothecene production ability co-exists. This study aimed to investigate whether a set of eight Brazilian wheat genotypes, varying in resistance according to classification by the breeder, exhibit a common or differential resistance to Fusarium graminearum (Fgra) (deoxynivalenolproducing) and Fusarium meridionale (nivalenol-producing) (Fmer) using full-spike and central spikelet inoculation (type II resistance). Fgra was generally more aggressive than Fmer based on the percentage of diseased spikes (99 and 84 %, respectively) and number of diseased spikelets (mean 2.8 and 2.0, respectively) below the central spikelet. The genotype-pathogen species interaction was not significant, but there were differences between the genotypes, with BRS 194 and BRS 327 being the least and most resistant, respectively, based on severity ratings. The incidence of Fusarium-damaged kernel (FDK, %) was not affected by species, but two genotypes (BRS Parrudo and BRS 327) showed a lower incidence of FDK. There were substantial variations in the accumulation of deoxynivalenol and nivalenol among the genotypes, reaching maxima of 691.2 µg g⁻¹ and 355.2 µg g⁻¹, respectively, suggesting that Fgra is a more potent producer of trichothecene. Our data confirm prior resistance classifications by the breeders and suggest that the use of a single highly aggressive Fgra isolate may be sufficient for effective screening for FHB resistance. However, further studies are needed to elucidate the accumulation of resistance to trichothecene.

Keywords:
visual assessment; spray-inoculation; point-inoculation; mycotoxins

Introduction

Fusarium head blight (FHB) is one of the most damaging diseases threatening wheat worldwide and is responsible for severe reductions in grain yield and quality (McMullen et al., 2012McMullen, M.P.; Bergstrom, G.C.; De Wolf, E.; Dill-Macky, R.; Hershman, D.E.; Shaner, G.; Van Sanford, D.A. 2012. A unified effort to fight an enemy of wheat and barley: Fusarium head blight. Plant Disease 96: 1712-1728.). The disease is caused mainly by members of the F. graminearum species complex (FGSC), which produce trichothecene mycotoxins including deoxynivalenol (DON) and nivalenol (NIV) (Desjardins et al., 1993Desjardins, A.E.; Hohn, T.M.; McCormick, S.P. 1993. Trichothecene biosynthesis in Fusarium species: chemistry, genetics, and significance. Microbiological Reviews 57: 595-604.; McMullen et al., 2012McMullen, M.P.; Bergstrom, G.C.; De Wolf, E.; Dill-Macky, R.; Hershman, D.E.; Shaner, G.; Van Sanford, D.A. 2012. A unified effort to fight an enemy of wheat and barley: Fusarium head blight. Plant Disease 96: 1712-1728.). Regulatory agencies in major wheat-producing countries limit the maximum levels of mycotoxins in commodities. In Brazil, the maximum limit in wheat grain is set at 3000 µg kg⁻¹ (Anvisa, 2011Agência Nacional de Vigilância Sanitária [ANVISA]. 2011. Resolution n° 7, maximum permissible levels for mycotoxins in food – Resolução n° 7, limites máximos tolerados (LMT) para micotoxinas em alimentos. Accessible at: http://bvsms.saude.gov.br/bvs/saudelegis/anvisa/2011/res0007_18_02_2011_rep.html [Accessed July 7, 2016] (in Portuguese).
http://bvsms.saude.gov.br/bvs/saudelegis... ). Thus far, integration of resistant cultivars and fungicide applications is the recommended approach for disease control and mycotoxin reduction. Wheat breeders have focused on cost-effective visual assessments of resistance to initial infection (Type I) and to further spreading of the disease within the spike (Type II), which has led to selection of genotypes with moderate resistance to FHB, particularly to Type II (Rudd et al., 2001Rudd, J.C.; Horsley, R.D.; McKendry, A.L.; Elias, E.M. 2001. Host plant resistance genes for Fusarium head blight : sources, mechanisms, and utility in conventional breeding systems. Crop Science 41: 620-627.; Sneller et al., 2012Sneller, C.; Guttieri, M.; Paul, P.; Costa, J.; Jackwood, R. 2012. Variation for resistance to kernel infection and toxin accumulation in winter wheat infected with Fusarium graminearum. Phytopathology 102: 306-314.). In Brazil, a number of cultivars exhibit moderate resistance, but the levels are not sufficient to prevent epidemics in a disease-conducive environment (Alves et al., 2013Alves, R.H.; Nora T.D.; Franco, F.D.A.; Carlos A.; Stangarlin, R. 2013. Type I and type II resistance reaction to FHB in wheat cultivars. Summa Phytopathologica 39: 167-171 (in Portuguese, with abstract in English).; Silva et al., 2010Silva, M.S.; Só, M.; Caierão, E.; Scheeren, P.L.; Eichelberger, L.; Junior, A.N.; Zavariz, M. 2010. Cultivar release BRS 327: a new bread wheat cultivar. Crop Breeding and Applied Biotechnology 10: 370-373.). For instance, the Brazilian cvs. Frontana and BRS Parrudo have been used as standards for moderate resistance (Caierão et al., 2014Caierão, E.; Scheeren, P.L.; Silva, M.S.; Castro, R.L. 2014. History of wheat cultivars released by Embrapa in forty years of research. Crop Breeding and Applied Biotechnology 14: 216-223.; Lemmens et al., 2004Lemmens, M.; Griesser, M.; Scholz, U.; Schondelmaier, J.; Buerstmayr, H.; Steiner, B. 2004. Molecular mapping of resistance to Fusarium head blight in the spring wheat cultivar Frontana. Theoretical and Applied Genetics 109: 215-224.; Nicolli et al., 2015Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.; Van Ginkel et al., 1996Van Ginkel, M.; Van der Shaar, W.; Zhuping, Y.; Rajaram, S. 1996. Inheritance of resistance to scab in two wheat cultivars from Brazil and China. Plant Disease 80: 863-867.).

In Brazil, F. graminearum, a DON producer, is the main FHB pathogen, followed by F. meridionale, which produces mainly NIV but also small amounts of DON (Nicolli et al., 2015Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.). Whereas F. graminearum is dominant overall (> 85 % frequency) in Brazil, F. meridionale is an important species (up to 30 % frequency) in the state of Paraná, due to the fact that maize, which is widely cultivated in this state, is another host of this pathogen (Astolfi et al., 2012Astolfi, P.; Reynoso, M.M.; Ramirez, M.L.; Chulze, S.N.; Alves, T.C.; Tessmann, D.J.; Del Ponte, E.M. 2012. Genetic population structure and trichothecene genotypes of Fusarium graminearum isolated from wheat in southern Brazil. Plant Pathology 61: 289-295.; Del Ponte et al., 2015Del Ponte, E.M.; Spolti, P.; Ward, T.; Gomes, L.B.; Nicolli, C.P.; Kuhnem, P.R.; Da Silva, C.N.; Tessmann, D.J. 2015. Regional and field-specific factors affect the composition of Fusarium head blight pathogens in subtropical no-till wheat agroecosystem of Brazil. Phytopathology 105: 246-254.). Resistance to FHB was suggested to be common across several Fusarium species, including those within FGSC, but the evaluation was limited to wheat genotypes in Eastern Europe (Mesterházy et al., 2005Mesterházy, A.; Bartók, T.; Kászonyi, G.; Varga, M.; Tóth, B.; Varga, J. 2005. Common resistance to different Fusarium spp. causing Fusarium head blight in wheat. European Journal of Plant Pathology 112: 267-281.). Previous controlled environment studies in Brazil have indicated that resistance in two cultivars have been influenced by the species of FHB pathogen used for inoculation, suggesting a genotype-species interaction effect (Spolti et al., 2012Spolti, P.; Barros, N.C.; Gomes, L.B.; Santos, J.; Del Ponte, E.M. 2012. Phenotypic and pathogenic traits of two species of the Fusarium graminearum complex possessing either 15-ADON or NIV genotype. European Journal of Plant Pathology 133: 621-629.). Thus, we aimed to characterize the reaction for a set of eight Brazilian wheat genotypes of known resistance when challenged by the two most prevalent FGSC pathogen species causing FHB in Brazil.

Materials and Methods

Wheat genotypes

Eight wheat genotypes were selected for this study based on their known reaction to FHB and extent of use in southern Brazil. Five genotypes had a moderately resistant (MR) reaction (BRS 327, BRS Parrudo, BRS Guamirim, Frontana and TBIO Alvorada) and three had a susceptible (S) reaction (BRS 194, Quartzo and CD 105) as demonstrated by both field and controlledenvironment experiments (Alves et al., 2013Alves, R.H.; Nora T.D.; Franco, F.D.A.; Carlos A.; Stangarlin, R. 2013. Type I and type II resistance reaction to FHB in wheat cultivars. Summa Phytopathologica 39: 167-171 (in Portuguese, with abstract in English).; Nicolli et al., 2015Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.).

Fungal isolates and inoculum production

The two isolates used in this study, each representing one of the two species most commonly associated with FHB in Brazil (Del Ponte et al., 2015Del Ponte, E.M.; Spolti, P.; Ward, T.; Gomes, L.B.; Nicolli, C.P.; Kuhnem, P.R.; Da Silva, C.N.; Tessmann, D.J. 2015. Regional and field-specific factors affect the composition of Fusarium head blight pathogens in subtropical no-till wheat agroecosystem of Brazil. Phytopathology 105: 246-254.), F. graminearum and F. meridionale, were selected based on their known aggressiveness and toxigenic potential determined in previous studies (Nicolli et al., 2015Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.; Spolti et al., 2012Spolti, P.; Barros, N.C.; Gomes, L.B.; Santos, J.; Del Ponte, E.M. 2012. Phenotypic and pathogenic traits of two species of the Fusarium graminearum complex possessing either 15-ADON or NIV genotype. European Journal of Plant Pathology 133: 621-629.). They are deposited at the Lavras Mycological collection (CML) under the following codes: CML 3344 (F. meridionale strain) and CML 3066 (F. graminearum strain). Inoculum was produced in SNA (Spezieller Nährstoffarmer Agar) media as described (Spolti et al., 2012Spolti, P.; Barros, N.C.; Gomes, L.B.; Santos, J.; Del Ponte, E.M. 2012. Phenotypic and pathogenic traits of two species of the Fusarium graminearum complex possessing either 15-ADON or NIV genotype. European Journal of Plant Pathology 133: 621-629.) and consisted of a suspension of 10⁵ macroconidia mL⁻¹.

Plant growth and inoculation treatments

For each genotype, eight plastic pots (1 L) containing soil substrate (equal parts of humus:soil:vermiculite) fertilized with macronutrients (NPK in the ratio of 10:10:10) were sown with ten seeds each. The pots were maintained in a greenhouse from planting to flowering for approximately 3 months at 25 ± 5 °C at an average relative humidity of around 60 %. Inoculations were performed at full flowering when plants are most susceptible (Spolti et al., 2012Spolti, P.; Barros, N.C.; Gomes, L.B.; Santos, J.; Del Ponte, E.M. 2012. Phenotypic and pathogenic traits of two species of the Fusarium graminearum complex possessing either 15-ADON or NIV genotype. European Journal of Plant Pathology 133: 621-629.).

Two methods of inoculation were used in separate experiments. In the first full-spike spray-inoculation was used to simulate conditions resembling natural infection (Miedaner, Moldovan and Ittu, 2003), and the following responses were evaluated: 1) incidence of disease (proportion of diseased spikes), used to infer resistance to initial infection (Type I); 2) Fusarium-damaged kernels, through the visual assessment of symptomatic kernels; and 3) accumulation of the trichothecenes DON and NIV in grains. The second method, in a separate experiment, was central-spikelet inoculation, which allows for assessing type II resistance; i.e. resistance to spreading from a point of infection (Bai and Shaner, 2004Bai, G.; Shaner, G. 2004. Management and resistance in wheat and barley to fusarium head blight. Annual Review of Phytopathology 42: 135-161.; Mesterházy et al., 2003Mesterházy, A.; Bartók, T.; Lamper, C. 2003. Influence of wheat cultivar, species of Fusarium, and isolate aggressiveness on the efficacy of fungicides for control of Fusarium head blight. Plant Disease 87: 1107-1115.).

Spray-inoculation assay

Wheat spikes at the full flowering stage were sprayed individually with 3 mL of conidial suspension using a hand-sprayer. The conidial suspension was prepared on the day of inoculation and conidia germination was > 80 % during inoculation. After inoculation, plants were kept in a moist chamber at 25 ± 2 °C and a relative humidity of 95 ± 2 % for 48 h. Next, the plants were moved into a growth chamber at 25 °C with a 12 h alternating dark/light cycle. The proportion of symptomatic spikelets, also known as the FHB index, were assessed visually at 5, 10 and 15 days after the 2-day incubation period. At 25 to 30 days after flowering, the spikes were harvested, hand-threshed and dried uniformly to 13 % moisture. The incidence of Fusarium-damaged kernels (FDK, %), i.e., small, shrunken, and whitish-pink in color, was determined by dividing the number of symptomatic grains by the total number of grains harvested from each pot. Concentration levels of deoxynivalenol (DON) and nivalenol (NIV) were determined using HPLC-UV. The validation parameters evaluated were the limit of detection (LOD), which refers to the lowest concentration of mycotoxin that can be detected, and recovery percentage, i.e., the proportion of the amount of mycotoxins present in or added to the grain material, which is extracted and quantified. The method used showed a 16.7 µg kg⁻¹, 33.3 µg kg⁻¹ of LOD for DON and NIV, respectively, and 89 % and 76 % recovery for DON and NIV, respectively (E. Seus, Federal University of Rio Grande/Chemistry and Food School, Rio Grande do Sul, Brazil, unpublished data).

Central-spikelet inoculation assay

At full flowering (> 50 % of visible anthers), 10 µL of the macroconidia suspension was gently applied, using a micropipette, to a floret of a central spikelet in a spike, usually the fifth spikelet from the top to the base of the spike. After inoculation, the plants were maintained in a growth chamber under the same conditions as the previous experiment. The number of symptomatic spikelets below the inoculation point was counted at 5, 10 and 15 days after the 2-day moist chamber incubation following inoculation (early milk to early dough stages). Diseased spikelets above the inoculation point were not counted because symptoms could not be distinguished from premature death of tissue due to blocking of vessels at lower points on the spike (Horevaj et al., 2011Horevaj, P.; Gale, L.R.; Milus, E.A. 2011. Resistance in winter wheat lines to initial infection and spread within spikes by deoxynivalenol and nivalenol chemotypes of Fusarium graminearum. Plant Disease 95: 31-37.). The area under the disease progress curve (based on counts of symptomatic spikelets) was calculated for each genotype in order to compare the type II resistance among the genotypes.

Experimental design and data analysis

Both experiments were conducted in a factorial (eight wheat genotypes × two fungal species) completely randomized design with eight replications (pots) per treatment. A non-inoculated treatment was included in the experiment as a negative control. Homocedasticity and normality in the fitted residuals data from both experiments were assessed based on visual inspection of the residuals and Levene and Shapiro-Wilks tests, respectively. Since each experiment was conducted twice an Anova model was used initially, considering the experiment as a factor in the analysis, to indicate whether data from both experiments could be combined for analysis. For the spray-inoculation experiment, a generalized linear mixed model was fitted to data on disease severity only at 5 days after inoculation, because at later times severity was very high and uniform across treatments. The experiment and replications were treated as a random factor and wheat genotype and fungal species as fixed effects. For FDK, the assumptions of parametric Anova were not met, and thus the Kruskal-Wallis test was used to compare single effects of wheat genotypes and species. Due to very small amounts of grain mass obtained for each replicate in the spray-inoculation experiment, grains from all replicates (pots) of a treatment were combined for mycotoxin analysis, and thus the means of DON and NIV could not be estimated and compared across treatments. All statistical analyses were performed in the R statistical computing environment. The mixed models were fitted using the lmer function of lme4 package of R. Treatment means were calculated using the lsmeans function of lsmeans R package and compared based on Tukey's test (p ≤ 0.05). Additionally, wheat genotypes were unambiguously discriminated based on the Scott-knot test (p ≤ 0.05).

Results

Spray inoculation assay

Fusarium head blight symptoms were observed at high incidence (> 70 %) in the spikes of all wheat genotypes at 5 days after the 2-day incubation, especially in plants inoculated with F. graminearum (Table 1); the mean FHB index averaged 99 % among wheat genotypes (p > 0.05). Mean severity in wheat genotypes inoculated with F. meridionale averaged 84 % and three groups were defined based on Tukey's test (p ≤ 0.05), with BRS Parrudo and Quartzo showing the lowest and highest severity means, respectively.

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Table 1
Fusarium head blight (FHB) severity, incidence of Fusarium-damaged kernels (FDK), and trichothecene mycotoxin (DON = deoxynivalenol and NIV = nivalenol) concentrations in wheat genotypes inoculated with a Fusarium meridionale (Fmer) or F. graminearum (Fgra) isolate during the full flowering stage and maintained at 25 °C for up to 5 days, following a 2-day moist incubation period after inoculation.

There was no effect of fungal species on FDK levels (p > 0.05). Two groups of wheat genotypes were defined based on the Kruskal-Wallis test. Frontana and BRS Parrudo differed significantly from the other genotypes, with FDK levels of 23 % and 21 %, respectively. BRS 327 did not differ from these two least damaged genotypes, but its FDK mean was also similar to the other genotypes, ranging from 39 % to 97 %.

The DON and NIV trichothecenes were found in wheat kernels from the spray-inoculated experiments at various levels across the genotypes. The DON and NIV levels across the genotypes were very high, on average, reaching 238.4 µg g⁻¹ and 78.5 µg g⁻¹, respectively. In all but one genotype (CD 105), DON levels were higher than NIV levels. There was a negative but non-significant correlation between DON and NIV levels (r = -0.21, p = 0.6). DON levels were > 300 µg g⁻¹ in Quartzo, Frontana and BRS Guamirim; < 100 µg g⁻¹ in BRS 327, BRS Parrudo and CD 105 and intermediate for BRS 194 and TBIO Alvorada (Table 1). Very high NIV levels (> 350 µg g⁻¹) were found in CD 105, followed by TBIO Alvorada and Quartzo (NIV > 82 µg g⁻¹). Frontana, BRS 194 and BRS 327 had NIV levels < 7 µg g⁻¹. When total trichothecenes (DON + NIV) were considered, the lowest levels were found in BRS Parrudo and BRS 327 (< 100 µg g⁻¹). The highest total of trichothecenes was found in Quartzo (> 770 µg g⁻¹).

Central-spikelet inoculation assay

FHB symptoms below the inoculation point were found in all genotypes inoculated with both species. However, symptoms induced by F. graminearum progressed faster than those induced by F. meridionale, generally leading to increased severity levels across all genotypes, especially during the first 10 days after inoculation (Figure 1A). The Anova model fitted to the area under the disease progress curve (AUDPC) corroborated (p = 0.58) visual inspection of the progress curves which suggested a non-significant effect of cultivar × species interaction. However, host genotype (p < 0.001) and pathogen species (p < 0.001), significantly affected AUDPC. The lsmeans estimate of AUDPC for F. graminearum was two times higher than that for F. meridionale (Figure 1C); mean final severity values ranged from 20 to 40 % for the former and from 4 to 23 % for the latter across the wheat genotypes. Lsmeans estimates, irrespective of the species, ranged from 13 to 30 % across the eight genotypes. The Scott-knot test separated the cultivars into two groups, with BRS 194, BRS Guamirim and CD105 being more susceptible than the others (Figure 1B). BRS Parrudo and Frontana exhibited the lowest AUDPC when these two species were considered (Figure 1A), whereas BRS 327 was the least susceptible because of the slower progress of the symptoms induced by the Fmer isolate (Figure 1A).

Figure 1
Number of diseased spikelets below the central floret of wheat genotypes inoculated with a Fusarium meridionale (gray lines) or an F. graminearum (black lines) isolate (A) and the calculated area under the disease (number of diseased spikelets) progress curve (AUDPC) for each cultivar (B) and inoculated species (C).

Discussion

This study provides the first detailed analysis of different types of FHB resistance for a set of wheat genotypes challenged by the two most common FHB pathogens in Brazil, which differ in the type of trichothecene produced. A number of the selected genotypes are currently grown in large acreage and possess different levels of resistance as determined by breeders using visual assessments during field screening (Schlang and Duveiller, 2012Schlang, N.; Duveiller, E. 2012. Current approaches and utilization of new screening techniques for evaluation of FHB resistance at CIMMYT. Plant Breeding and Seed Science 64: 89-103.).

We found that one of the most significant traits commonly determined in the less susceptible commercial genotypes worldwide, type II resistance, or resistance to disease spread, did not depend on the cultivarpathogen interaction, meaning that the ranking of the genotypes did not depend on the pathogen species. This is important information for breeders, and agrees with the results of a European study (Mesterházy et al., 2005Mesterházy, A.; Bartók, T.; Kászonyi, G.; Varga, M.; Tóth, B.; Varga, J. 2005. Common resistance to different Fusarium spp. causing Fusarium head blight in wheat. European Journal of Plant Pathology 112: 267-281.). Based on our results, the selection of superior wheat genotypes could thus be performed using a single aggressive isolate from either species, preferably the most aggressive one, or F. graminearum of the 15-ADON genotype, which has been shown to be highly adaptable as a wheat pathogen (Del Ponte et al., 2015Del Ponte, E.M.; Spolti, P.; Ward, T.; Gomes, L.B.; Nicolli, C.P.; Kuhnem, P.R.; Da Silva, C.N.; Tessmann, D.J. 2015. Regional and field-specific factors affect the composition of Fusarium head blight pathogens in subtropical no-till wheat agroecosystem of Brazil. Phytopathology 105: 246-254.; Nicolli et al., 2015Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.). In contrast, F. meridionale has been suggested as being more adapted to infecting maize, given the higher frequency in this crop than F. graminearum (Kuhnem et al., 2016Kuhnem, P.R.; Ward, T.J.; Silva, C.N.; Spolti, P.; Ciliato, M.L.; Tessmann, D.J.; Del Ponte, E.M. 2016. Composition and toxigenic potential of the Fusarium graminearum species complex from maize ears, stalks and stubble in Brazil. Plant Pathology 65: 1185-1191.).

The inoculation experiments were performed under conditions which are very conducive to the development of disease. Therefore, when using high inoculum pressure applied as spray toward the full spikes, severity reached 100 % at 5 days after inoculation with the exception of BRS Parrudo (> 80 %). Nevertheless, the portion of Fusarium-damaged kernels in two genotypes, including Frontana, an old cultivar which is considered a standard for resistance, and BRS Parrudo, were the least damaged, suggesting a type IV resistance (Mesterházy, 1995Mesterházy, A. 1995. Types and components of resistance to Fusarium head blight of wheat. Plant Breeding 114: 377-386.; Mesterházy et al., 1999Mesterházy, A.; Bartók, T.; Mirocha, C.G.; Komoróczy, R. 1999. Nature of wheat resistance to Fusarium head blight and the role of deoxynivalenol for breeding. Plant Breeding 118: 97-110.), or the ability of the genotypes to tolerate damage, though not suppress symptoms on the spikes. In fact, previous studies have shown that Frontana exhibited low levels of damage in kernels caused by Fusarium species, which might be due to a resistance mechanism (Burlakoti et al., 2009Burlakoti, R.R.; Mergoum, M.; Kianian, S.F.; Adhikari, T.B. 2009. Combining different resistance components enhances resistance to Fusarium head blight in spring wheat. Euphytica 172: 197-205.; Wiśniewska et al., 2004Wiśniewska, H.; Perkowski, J.; Kaczmarek, Z. 2004. Scab response and deoxynivalenol accumulation in spring wheat kernels of different geographical origins following inoculation with Fusarium culmorum. Journal of Phytopathology 152: 613-621.).

Due to the very conducive environment during the experiments, most genotypes spray-inoculated with the DON-producer F. graminearum isolate exhibited high severity, which masked differences between the cultivars, and prevented making conclusions regarding type I resistance. The high levels of severity from F. graminearum inoculations, compared to F. meridionale, may relate to high potential for trichothecene production by F. graminearum; DON levels were around three times higher than NIV which resulted from inoculations with F. meridionale. In planta, trichothecenes are known to act by blocking the synthesis of proteins and favor pathogen colonization in host tissue (Desjardins et al., 1993Desjardins, A.E.; Hohn, T.M.; McCormick, S.P. 1993. Trichothecene biosynthesis in Fusarium species: chemistry, genetics, and significance. Microbiological Reviews 57: 595-604.; Desjardins et al., 1996Desjardins, A.E.; Proctor, R.H.; Bai, G.; McCormick, S.P.; Shaner, G.; Buechley, G.; Hohn, T.M. 1996. Reduced virulence of trichothecene-nonproducing mutants of Gibberella zeae in wheat field tests. Molecular Plant-Microbe Interactions 9: 775-781.). Moreover, DON is recognized as a virulence factor during pathogenesis, with more symptoms being associated with higher DON production, whereas NIV in wheat is produced in smaller quantities than DON (Desjardins et al., 2004Desjardins, A.E.; Jarosz, A.M.; Plattner, R.D.; Alexander, N.J.; Brown, D.W.; Jurgenson, J.E. 2004. Patterns of trichothecene production, genetic variability, and virulence to wheat of Fusarium graminearum from smallholder farms in Nepal. Journal of Agricultural and Food Chemistry 52: 6341-6346.).

Although resistance among the genotypes could not be discriminated using spray inoculations, the trichothecene concentration found in the kernels was highly variable. However, statistical evidence could not be assessed due to limitation in grain mass, which required that replicates were combined into a single sample. Nevertheless, the genotypes with lower numeric values of DON and NIV were BRS 194 and BRS 327, suggesting a mechanism of DON degradation or another factor limiting mycotoxin production in these genotypes, which should be assessed in future research. In general, DON levels were higher than NIV, confirming previous findings (Nicolli et al., 2015Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.). However, for a number of genotypes not previously evaluated for this trait, such as CD 105, NIV levels were seven times higher than DON for reasons that should be further explored. Frontana, although exhibiting relatively low levels of disease severity and damage in kernels, showed the second largest amount of DON but very low levels of NIV. This was unexpected given a previous report of Frontana's ability to degrade deoxynivalenol in embryo cultures (Miller and Arnison, 1986Miller, J.D.; Arnison, P.G. 1986. Degradation of deoxynivalenol by suspension cultures of the Fusarium head blight resistant wheat cultivar Frontana. Canadian Journal of Plant Pathology 8: 147-150.). However, there is evidence that in vitro studies on mycotoxin accumulation correlate poorly with in vivo experiments, which will require further experimentation to clarify (Gosman et al., 2005Gosman, N.; Chandler, E.; Thomsett, M.; Draeger, R.; Nicholson, P. 2005. Analysis of the relationship between parameters of resistance to Fusarium head blight and in vitro tolerance to deoxynivalenol of the winter wheat cultivar WEK0609. European Journal of Plant Pathology 111: 57-66.; Malbrán et al., 2014Malbrán, I.; Mourelos, C.A.; Girotti, J.R.; Balatti, P.A.; Lori, G.A. 2014. Toxigenic capacity and trichothecene production by Fusarium graminearum isolates from Argentina and their relationship with aggressiveness and fungal expansion in the wheat spike. Phytopathology 104: 357-364.; Walker et al., 2001Walker, S.L.; Leath, S.; Hagler, W.M.; Murphy, J.P. 2001. Variation among isolates of Fusarium graminearum associated with Fusarium head blight in North Carolina. Plant Disease 85: 404-410.).

In general, our data on mycotoxin accumulation agree with previous studies that have also shown a weak association between visual symptoms and the accumulation of mycotoxin (Arseniuk et al., 1999Arseniuk, E.; Foremska, E.; Góral, T.; Chelkowski, J. 1999. Fusarium head blight reactions and accumulation of deoxynivalenol (DON) and some of its derivatives in kernels of wheat, triticale and rye. Journal of Phytopathology 147: 577-590.; Mesterházy et al., 1999Mesterházy, A.; Bartók, T.; Mirocha, C.G.; Komoróczy, R. 1999. Nature of wheat resistance to Fusarium head blight and the role of deoxynivalenol for breeding. Plant Breeding 118: 97-110.; Wiśniewska et al., 2004Wiśniewska, H.; Perkowski, J.; Kaczmarek, Z. 2004. Scab response and deoxynivalenol accumulation in spring wheat kernels of different geographical origins following inoculation with Fusarium culmorum. Journal of Phytopathology 152: 613-621.). Therefore, when selecting for mycotoxin resistance, it would be instructive to include data on mycotoxin accumulation as a component of the breeding selection criteria (Arseniuk et al., 1999Arseniuk, E.; Foremska, E.; Góral, T.; Chelkowski, J. 1999. Fusarium head blight reactions and accumulation of deoxynivalenol (DON) and some of its derivatives in kernels of wheat, triticale and rye. Journal of Phytopathology 147: 577-590.; Ji et al., 2015Ji, F.; Wu, J.; Zhao, H.; Xu, J.; Shi, J. 2015. Relationship of deoxynivalenol content in grain, chaff, and straw with Fusarium head blight severity in wheat varieties with various levels of resistance. Toxins 7: 728-742.; Jin et al., 2014Jin, F.; Bai, G.; Zhang, D.; Dong, Y.; Ma, L.; Bockus, W.; Dowell, F. 2014. Fusarium-damaged kernels and deoxynivalenol in Fusarium-infected U.S. winter wheat. Phytopathology 104: 472-478.; Schlang and Duveiller, 2012Schlang, N.; Duveiller, E. 2012. Current approaches and utilization of new screening techniques for evaluation of FHB resistance at CIMMYT. Plant Breeding and Seed Science 64: 89-103.). To overcome the high costs associated with mycotoxin analysis, assessments of FDK, in addition to being a more affordable method, usually correlate more strongly with mycotoxin levels than visual assessment of the wheat spikes, and could be used as a surrogate variable to select for resistance to mycotoxin (Mesterházy et al., 2005Mesterházy, A.; Bartók, T.; Kászonyi, G.; Varga, M.; Tóth, B.; Varga, J. 2005. Common resistance to different Fusarium spp. causing Fusarium head blight in wheat. European Journal of Plant Pathology 112: 267-281.; Sneller et al., 2012Sneller, C.; Guttieri, M.; Paul, P.; Costa, J.; Jackwood, R. 2012. Variation for resistance to kernel infection and toxin accumulation in winter wheat infected with Fusarium graminearum. Phytopathology 102: 306-314.). In conclusion, our study confirms significant differences between two members of the F. graminearum species complex related to their ability to cause FHB in wheat, irrespective of the cultivar. Out of the genotypes evaluated in this study, BRS Parrudo and BRS 327 were among the most resistant overall, exhibiting generally lower levels of symptoms on both spike and kernel as well as lower levels of trichothecenes compared to the other cultivars. The mechanisms involved in the resistance by these genotypes merit further investigation.

References

Agência Nacional de Vigilância Sanitária [ANVISA]. 2011. Resolution n° 7, maximum permissible levels for mycotoxins in food – Resolução n° 7, limites máximos tolerados (LMT) para micotoxinas em alimentos. Accessible at: http://bvsms.saude.gov.br/bvs/saudelegis/anvisa/2011/res0007_18_02_2011_rep.html [Accessed July 7, 2016] (in Portuguese).
» http://bvsms.saude.gov.br/bvs/saudelegis/anvisa/2011/res0007_18_02_2011_rep.html
Alves, R.H.; Nora T.D.; Franco, F.D.A.; Carlos A.; Stangarlin, R. 2013. Type I and type II resistance reaction to FHB in wheat cultivars. Summa Phytopathologica 39: 167-171 (in Portuguese, with abstract in English).
Arseniuk, E.; Foremska, E.; Góral, T.; Chelkowski, J. 1999. Fusarium head blight reactions and accumulation of deoxynivalenol (DON) and some of its derivatives in kernels of wheat, triticale and rye. Journal of Phytopathology 147: 577-590.
Astolfi, P.; Reynoso, M.M.; Ramirez, M.L.; Chulze, S.N.; Alves, T.C.; Tessmann, D.J.; Del Ponte, E.M. 2012. Genetic population structure and trichothecene genotypes of Fusarium graminearum isolated from wheat in southern Brazil. Plant Pathology 61: 289-295.
Bai, G.; Shaner, G. 2004. Management and resistance in wheat and barley to fusarium head blight. Annual Review of Phytopathology 42: 135-161.
Burlakoti, R.R.; Mergoum, M.; Kianian, S.F.; Adhikari, T.B. 2009. Combining different resistance components enhances resistance to Fusarium head blight in spring wheat. Euphytica 172: 197-205.
Caierão, E.; Scheeren, P.L.; Silva, M.S.; Castro, R.L. 2014. History of wheat cultivars released by Embrapa in forty years of research. Crop Breeding and Applied Biotechnology 14: 216-223.
Del Ponte, E.M.; Spolti, P.; Ward, T.; Gomes, L.B.; Nicolli, C.P.; Kuhnem, P.R.; Da Silva, C.N.; Tessmann, D.J. 2015. Regional and field-specific factors affect the composition of Fusarium head blight pathogens in subtropical no-till wheat agroecosystem of Brazil. Phytopathology 105: 246-254.
Desjardins, A.E.; Hohn, T.M.; McCormick, S.P. 1993. Trichothecene biosynthesis in Fusarium species: chemistry, genetics, and significance. Microbiological Reviews 57: 595-604.
Desjardins, A.E.; Jarosz, A.M.; Plattner, R.D.; Alexander, N.J.; Brown, D.W.; Jurgenson, J.E. 2004. Patterns of trichothecene production, genetic variability, and virulence to wheat of Fusarium graminearum from smallholder farms in Nepal. Journal of Agricultural and Food Chemistry 52: 6341-6346.
Desjardins, A.E.; Proctor, R.H.; Bai, G.; McCormick, S.P.; Shaner, G.; Buechley, G.; Hohn, T.M. 1996. Reduced virulence of trichothecene-nonproducing mutants of Gibberella zeae in wheat field tests. Molecular Plant-Microbe Interactions 9: 775-781.
Gosman, N.; Chandler, E.; Thomsett, M.; Draeger, R.; Nicholson, P. 2005. Analysis of the relationship between parameters of resistance to Fusarium head blight and in vitro tolerance to deoxynivalenol of the winter wheat cultivar WEK0609. European Journal of Plant Pathology 111: 57-66.
Horevaj, P.; Gale, L.R.; Milus, E.A. 2011. Resistance in winter wheat lines to initial infection and spread within spikes by deoxynivalenol and nivalenol chemotypes of Fusarium graminearum Plant Disease 95: 31-37.
Ji, F.; Wu, J.; Zhao, H.; Xu, J.; Shi, J. 2015. Relationship of deoxynivalenol content in grain, chaff, and straw with Fusarium head blight severity in wheat varieties with various levels of resistance. Toxins 7: 728-742.
Jin, F.; Bai, G.; Zhang, D.; Dong, Y.; Ma, L.; Bockus, W.; Dowell, F. 2014. Fusarium-damaged kernels and deoxynivalenol in Fusarium-infected U.S. winter wheat. Phytopathology 104: 472-478.
Kuhnem, P.R.; Ward, T.J.; Silva, C.N.; Spolti, P.; Ciliato, M.L.; Tessmann, D.J.; Del Ponte, E.M. 2016. Composition and toxigenic potential of the Fusarium graminearum species complex from maize ears, stalks and stubble in Brazil. Plant Pathology 65: 1185-1191.
Lemmens, M.; Griesser, M.; Scholz, U.; Schondelmaier, J.; Buerstmayr, H.; Steiner, B. 2004. Molecular mapping of resistance to Fusarium head blight in the spring wheat cultivar Frontana. Theoretical and Applied Genetics 109: 215-224.
Malbrán, I.; Mourelos, C.A.; Girotti, J.R.; Balatti, P.A.; Lori, G.A. 2014. Toxigenic capacity and trichothecene production by Fusarium graminearum isolates from Argentina and their relationship with aggressiveness and fungal expansion in the wheat spike. Phytopathology 104: 357-364.
McMullen, M.P.; Bergstrom, G.C.; De Wolf, E.; Dill-Macky, R.; Hershman, D.E.; Shaner, G.; Van Sanford, D.A. 2012. A unified effort to fight an enemy of wheat and barley: Fusarium head blight. Plant Disease 96: 1712-1728.
Mesterházy, A. 1995. Types and components of resistance to Fusarium head blight of wheat. Plant Breeding 114: 377-386.
Mesterházy, A.; Bartók, T.; Kászonyi, G.; Varga, M.; Tóth, B.; Varga, J. 2005. Common resistance to different Fusarium spp. causing Fusarium head blight in wheat. European Journal of Plant Pathology 112: 267-281.
Mesterházy, A.; Bartók, T.; Lamper, C. 2003. Influence of wheat cultivar, species of Fusarium, and isolate aggressiveness on the efficacy of fungicides for control of Fusarium head blight. Plant Disease 87: 1107-1115.
Mesterházy, A.; Bartók, T.; Mirocha, C.G.; Komoróczy, R. 1999. Nature of wheat resistance to Fusarium head blight and the role of deoxynivalenol for breeding. Plant Breeding 118: 97-110.
Miller, J.D.; Arnison, P.G. 1986. Degradation of deoxynivalenol by suspension cultures of the Fusarium head blight resistant wheat cultivar Frontana. Canadian Journal of Plant Pathology 8: 147-150.
Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.
Rudd, J.C.; Horsley, R.D.; McKendry, A.L.; Elias, E.M. 2001. Host plant resistance genes for Fusarium head blight : sources, mechanisms, and utility in conventional breeding systems. Crop Science 41: 620-627.
Schlang, N.; Duveiller, E. 2012. Current approaches and utilization of new screening techniques for evaluation of FHB resistance at CIMMYT. Plant Breeding and Seed Science 64: 89-103.
Silva, M.S.; Só, M.; Caierão, E.; Scheeren, P.L.; Eichelberger, L.; Junior, A.N.; Zavariz, M. 2010. Cultivar release BRS 327: a new bread wheat cultivar. Crop Breeding and Applied Biotechnology 10: 370-373.
Sneller, C.; Guttieri, M.; Paul, P.; Costa, J.; Jackwood, R. 2012. Variation for resistance to kernel infection and toxin accumulation in winter wheat infected with Fusarium graminearum Phytopathology 102: 306-314.
Spolti, P.; Barros, N.C.; Gomes, L.B.; Santos, J.; Del Ponte, E.M. 2012. Phenotypic and pathogenic traits of two species of the Fusarium graminearum complex possessing either 15-ADON or NIV genotype. European Journal of Plant Pathology 133: 621-629.
Van Ginkel, M.; Van der Shaar, W.; Zhuping, Y.; Rajaram, S. 1996. Inheritance of resistance to scab in two wheat cultivars from Brazil and China. Plant Disease 80: 863-867.
Walker, S.L.; Leath, S.; Hagler, W.M.; Murphy, J.P. 2001. Variation among isolates of Fusarium graminearum associated with Fusarium head blight in North Carolina. Plant Disease 85: 404-410.
Wiśniewska, H.; Perkowski, J.; Kaczmarek, Z. 2004. Scab response and deoxynivalenol accumulation in spring wheat kernels of different geographical origins following inoculation with Fusarium culmorum Journal of Phytopathology 152: 613-621.

Edited by

Edited by: Mark L. Gleason

Publication Dates

Publication in this collection
Sep-Oct 2018

History

Received
05 Oct 2016
Accepted
19 July 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Agência Nacional de Vigilância Sanitária [ANVISA]. 2011. Resolution n° 7, maximum permissible levels for mycotoxins in food – Resolução n° 7, limites máximos tolerados (LMT) para micotoxinas em alimentos. Accessible at: http://bvsms.saude.gov.br/bvs/saudelegis/anvisa/2011/res0007_18_02_2011_rep.html [Accessed July 7, 2016] (in Portuguese).
» http://bvsms.saude.gov.br/bvs/saudelegis/anvisa/2011/res0007_18_02_2011_rep.html

[2] Alves, R.H.; Nora T.D.; Franco, F.D.A.; Carlos A.; Stangarlin, R. 2013. Type I and type II resistance reaction to FHB in wheat cultivars. Summa Phytopathologica 39: 167-171 (in Portuguese, with abstract in English).

[3] Arseniuk, E.; Foremska, E.; Góral, T.; Chelkowski, J. 1999. Fusarium head blight reactions and accumulation of deoxynivalenol (DON) and some of its derivatives in kernels of wheat, triticale and rye. Journal of Phytopathology 147: 577-590.

[4] Astolfi, P.; Reynoso, M.M.; Ramirez, M.L.; Chulze, S.N.; Alves, T.C.; Tessmann, D.J.; Del Ponte, E.M. 2012. Genetic population structure and trichothecene genotypes of Fusarium graminearum isolated from wheat in southern Brazil. Plant Pathology 61: 289-295.

[5] Bai, G.; Shaner, G. 2004. Management and resistance in wheat and barley to fusarium head blight. Annual Review of Phytopathology 42: 135-161.

[6] Burlakoti, R.R.; Mergoum, M.; Kianian, S.F.; Adhikari, T.B. 2009. Combining different resistance components enhances resistance to Fusarium head blight in spring wheat. Euphytica 172: 197-205.

[7] Caierão, E.; Scheeren, P.L.; Silva, M.S.; Castro, R.L. 2014. History of wheat cultivars released by Embrapa in forty years of research. Crop Breeding and Applied Biotechnology 14: 216-223.

[8] Del Ponte, E.M.; Spolti, P.; Ward, T.; Gomes, L.B.; Nicolli, C.P.; Kuhnem, P.R.; Da Silva, C.N.; Tessmann, D.J. 2015. Regional and field-specific factors affect the composition of Fusarium head blight pathogens in subtropical no-till wheat agroecosystem of Brazil. Phytopathology 105: 246-254.

[9] Desjardins, A.E.; Hohn, T.M.; McCormick, S.P. 1993. Trichothecene biosynthesis in Fusarium species: chemistry, genetics, and significance. Microbiological Reviews 57: 595-604.

[10] Desjardins, A.E.; Jarosz, A.M.; Plattner, R.D.; Alexander, N.J.; Brown, D.W.; Jurgenson, J.E. 2004. Patterns of trichothecene production, genetic variability, and virulence to wheat of Fusarium graminearum from smallholder farms in Nepal. Journal of Agricultural and Food Chemistry 52: 6341-6346.

[11] Desjardins, A.E.; Proctor, R.H.; Bai, G.; McCormick, S.P.; Shaner, G.; Buechley, G.; Hohn, T.M. 1996. Reduced virulence of trichothecene-nonproducing mutants of Gibberella zeae in wheat field tests. Molecular Plant-Microbe Interactions 9: 775-781.

[12] Gosman, N.; Chandler, E.; Thomsett, M.; Draeger, R.; Nicholson, P. 2005. Analysis of the relationship between parameters of resistance to Fusarium head blight and in vitro tolerance to deoxynivalenol of the winter wheat cultivar WEK0609. European Journal of Plant Pathology 111: 57-66.

[13] Horevaj, P.; Gale, L.R.; Milus, E.A. 2011. Resistance in winter wheat lines to initial infection and spread within spikes by deoxynivalenol and nivalenol chemotypes of Fusarium graminearum Plant Disease 95: 31-37.

[14] Ji, F.; Wu, J.; Zhao, H.; Xu, J.; Shi, J. 2015. Relationship of deoxynivalenol content in grain, chaff, and straw with Fusarium head blight severity in wheat varieties with various levels of resistance. Toxins 7: 728-742.

[15] Jin, F.; Bai, G.; Zhang, D.; Dong, Y.; Ma, L.; Bockus, W.; Dowell, F. 2014. Fusarium-damaged kernels and deoxynivalenol in Fusarium-infected U.S. winter wheat. Phytopathology 104: 472-478.

[16] Kuhnem, P.R.; Ward, T.J.; Silva, C.N.; Spolti, P.; Ciliato, M.L.; Tessmann, D.J.; Del Ponte, E.M. 2016. Composition and toxigenic potential of the Fusarium graminearum species complex from maize ears, stalks and stubble in Brazil. Plant Pathology 65: 1185-1191.

[17] Lemmens, M.; Griesser, M.; Scholz, U.; Schondelmaier, J.; Buerstmayr, H.; Steiner, B. 2004. Molecular mapping of resistance to Fusarium head blight in the spring wheat cultivar Frontana. Theoretical and Applied Genetics 109: 215-224.

[18] Malbrán, I.; Mourelos, C.A.; Girotti, J.R.; Balatti, P.A.; Lori, G.A. 2014. Toxigenic capacity and trichothecene production by Fusarium graminearum isolates from Argentina and their relationship with aggressiveness and fungal expansion in the wheat spike. Phytopathology 104: 357-364.

[19] McMullen, M.P.; Bergstrom, G.C.; De Wolf, E.; Dill-Macky, R.; Hershman, D.E.; Shaner, G.; Van Sanford, D.A. 2012. A unified effort to fight an enemy of wheat and barley: Fusarium head blight. Plant Disease 96: 1712-1728.

[20] Mesterházy, A. 1995. Types and components of resistance to Fusarium head blight of wheat. Plant Breeding 114: 377-386.

[21] Mesterházy, A.; Bartók, T.; Kászonyi, G.; Varga, M.; Tóth, B.; Varga, J. 2005. Common resistance to different Fusarium spp. causing Fusarium head blight in wheat. European Journal of Plant Pathology 112: 267-281.

[22] Mesterházy, A.; Bartók, T.; Lamper, C. 2003. Influence of wheat cultivar, species of Fusarium, and isolate aggressiveness on the efficacy of fungicides for control of Fusarium head blight. Plant Disease 87: 1107-1115.

[23] Mesterházy, A.; Bartók, T.; Mirocha, C.G.; Komoróczy, R. 1999. Nature of wheat resistance to Fusarium head blight and the role of deoxynivalenol for breeding. Plant Breeding 118: 97-110.

[24] Miller, J.D.; Arnison, P.G. 1986. Degradation of deoxynivalenol by suspension cultures of the Fusarium head blight resistant wheat cultivar Frontana. Canadian Journal of Plant Pathology 8: 147-150.

[25] Nicolli, C.P.; Spolti, P.; Tibola, C.S.; Fernandes, J.M.C.; Del Ponte, E.M. 2015. Fusarium head blight and trichothecene production in wheat by Fusarium graminearum and F. meridionale applied alone or in mixture at post-flowering. Tropical Plant Pathology 40: 134-140.

[26] Rudd, J.C.; Horsley, R.D.; McKendry, A.L.; Elias, E.M. 2001. Host plant resistance genes for Fusarium head blight : sources, mechanisms, and utility in conventional breeding systems. Crop Science 41: 620-627.

[27] Schlang, N.; Duveiller, E. 2012. Current approaches and utilization of new screening techniques for evaluation of FHB resistance at CIMMYT. Plant Breeding and Seed Science 64: 89-103.

[28] Silva, M.S.; Só, M.; Caierão, E.; Scheeren, P.L.; Eichelberger, L.; Junior, A.N.; Zavariz, M. 2010. Cultivar release BRS 327: a new bread wheat cultivar. Crop Breeding and Applied Biotechnology 10: 370-373.

[29] Sneller, C.; Guttieri, M.; Paul, P.; Costa, J.; Jackwood, R. 2012. Variation for resistance to kernel infection and toxin accumulation in winter wheat infected with Fusarium graminearum Phytopathology 102: 306-314.

[30] Spolti, P.; Barros, N.C.; Gomes, L.B.; Santos, J.; Del Ponte, E.M. 2012. Phenotypic and pathogenic traits of two species of the Fusarium graminearum complex possessing either 15-ADON or NIV genotype. European Journal of Plant Pathology 133: 621-629.

[31] Van Ginkel, M.; Van der Shaar, W.; Zhuping, Y.; Rajaram, S. 1996. Inheritance of resistance to scab in two wheat cultivars from Brazil and China. Plant Disease 80: 863-867.

[32] Walker, S.L.; Leath, S.; Hagler, W.M.; Murphy, J.P. 2001. Variation among isolates of Fusarium graminearum associated with Fusarium head blight in North Carolina. Plant Disease 85: 404-410.

[33] Wiśniewska, H.; Perkowski, J.; Kaczmarek, Z. 2004. Scab response and deoxynivalenol accumulation in spring wheat kernels of different geographical origins following inoculation with Fusarium culmorum Journal of Phytopathology 152: 613-621.

Genotype	FHB Severity		FDK	Trichothecenes
Genotype	Fgra	Fmer	FDK	DON (Fgra)	NIV (Fmer)
	----------------------------- % -------------------------------			--------------- µg g⁻¹ ---------------
BRS 194	100.0 A^ns ns = not significant.	79.9 Bbc	40.6 a	182.7	5.9
BRS 327	100.0 A	86.7 Bbc	38.8 ab	92.1	6.6
BRS Guamirim	99.2 A	90.2 Abc	51.8 a	307.3	37.6
BRS Parrudo	99.8 A	64.6 Bc	21.0 b	64.3	10.8
CD 105	99.7 A	93.6 Abc	71.8 a	45.3	355.2
Frontana	100.0 A	80.6 Babc	22.6 b	337.9	4.3
Quartzo	99.8 A	94.9 Aa	86.1a	691.2	82.4
TBIO Alvorada	98.0 A	83.0 Babc	97.1a	186.5	125.8

Brasil

Brasil

Common resistance to Fusarium head blight in Brazilian wheat cultivars

ABSTRACT:

Introduction

Materials and Methods

Wheat genotypes

Fungal isolates and inoculum production

Plant growth and inoculation treatments

Spray-inoculation assay

Central-spikelet inoculation assay

Experimental design and data analysis

Results

Spray inoculation assay

Central-spikelet inoculation assay

Discussion

References

Edited by

Publication Dates

History