Relationship between leaf stages and epistasis for resistance to Stagonospora nodorum in durum wheat

Bnejdi, Fethi; Saadoun, Mourad; Naouari, Mouna; El Gazzah, Mohamed

doi:10.1590/S1415-47572012005000033

Abstract

Ten varieties and eight generations (2F1, 2F2, 2B1 and 2B2) of durum wheat derived from two crosses were evaluated for resistance to natural infection by Stagonospora nodorum blotch (SNB) at the 2-3 and 6-7 leaf stages at two sites over two years. There were significant differences in the incidence of SNB between leaf stages in most of the wheat varieties, with resistance being most evident at the 6-7 leaf stage. Separate analyses of the mean values for each generation showed that the genetic mechanism of defense against the pathogen depended upon the leaf stage. At the 2-3 leaf stage, only additive and dominance effects were implicated in the control of SNB for the two crosses at the two sites and for the two replications. For the 6-7 leaf stage, inheritance was more complicated and an epistatic effect was involved. Narrow-sense heritability values (range: 0.63-0.67) were consistent between crosses and leaf stages. These findings indicate a lack of resistance to SNB at the 2-3 leaf stage whereas resistance was observed at the 6-7 leaf stage and involved the genetic mechanisms of plant defense such as epistasis.

adaptability; inheritance; leaf stage; Stagonospora nodorum blotch

Relationship between leaf stages and epistasis for resistance to Stagonospora nodorum in durum wheat

Fethi Bnejdi^I; Mourad Saadoun^II; Mouna Naouari^I; Mohamed El Gazzah^I

^ILaboratoire de Génétique et Biométrie, Département de Biologie, Faculté des Sciences de Tunis, Université Tunis El Manar 2092, Tunisia

^IILaboratoire de Protection des Végétaux, Institut National de la Recherche Agronomique de Tunisie, Tunisia

^{Send correspondence to} Send correspondence to Fethi Bnejdi Laboratoire de Génétique et Biométrie, Département de Biologie, Faculté des Sciences de Tunis Université Tunis El Manar 2092, Tunisia E-mail: fethibnejdi@yahoo.fr

ABSTRACT

Ten varieties and eight generations (2F1, 2F2, 2B1 and 2B2) of durum wheat derived from two crosses were evaluated for resistance to natural infection by Stagonospora nodorum blotch (SNB) at the 2-3 and 6-7 leaf stages at two sites over two years. There were significant differences in the incidence of SNB between leaf stages in most of the wheat varieties, with resistance being most evident at the 6-7 leaf stage. Separate analyses of the mean values for each generation showed that the genetic mechanism of defense against the pathogen depended upon the leaf stage. At the 2-3 leaf stage, only additive and dominance effects were implicated in the control of SNB for the two crosses at the two sites and for the two replications. For the 6-7 leaf stage, inheritance was more complicated and an epistatic effect was involved. Narrow-sense heritability values (range: 0.63-0.67) were consistent between crosses and leaf stages. These findings indicate a lack of resistance to SNB at the 2-3 leaf stage whereas resistance was observed at the 6-7 leaf stage and involved the genetic mechanisms of plant defense such as epistasis.

Key words: adaptability, inheritance, leaf stage, Stagonospora nodorum blotch.

Introduction

Durum wheat (Triticum turgidum L. var. durum) is a tetraploid species widely cultivated in the Mediterranean Basin, Canada, USA, Argentina and India (Blanco et al., 1998). In Tunisia, durum wheat is the primary cultivated crop and occupies more than half of the area dedicated to cereal crops (Bnejdi and El Gazzah, 2008). Information regarding the nature and magnitude of genetic effects prevailing in the breeding material is necessary in order to choose the breeding procedure that best exploits the genetic potential of different plant traits in a crop.

Stagonospora nodorum blotch (SNB), an important pathogen of wheat and related cereals, causes leaf and glume blotch in all major growing areas (Peter et al., 2006; Friesen et al., 2008). Resistance to SNB is particularly important in wheat breeding programs because of the detrimental effect of this biotic stress on plant growth and subsequent yields and grain quality (Eyal, 1981; King et al., 1983; Eyal et al., 1987). Several authors have shown that resistance to the leaf and head phases may be under separate genetic control (Bostwick et al., 1993; Hu et al., 1996; Wicki et al., 1999). Several independent genes that regulate glume and flag leaf resistance have been identified (Fried and Meister, 1987; Aguilar et al., 2005), although single genes have been identified in some Triticum accessions (Parlevliet, 1977; Ma and Hughes, 1995; Murphy et al., 2000; Feng et al., 2004). Disease resistance is often highly correlated with late-maturing, tall cultivars (Scott, 1973; Eyal, 1981; Trottet and Merrien, 1982; Aguilar et al., 2005). Inheritance of SNB has been the subject of intensive studies at different vegetative stages: e.g. 2-3 leaf (Chu et al., 2008; Oliver et al., 2008), 4 leaf (Kim et al., 2004) and heading (Fried and Meister, 1987) stages. The objective of this study was to determine the mode of inheritance of SNB at the 2-3 and 6-7 leaf stages in durum wheat varieties.

Materials and Methods

Plant material

Eighteen populations of durum wheat were evaluated for resistance to natural infection by SNB at two Tunisian sites (Tunis and El Kef) during two successive agricultural seasons (2008-2009 and 2009-2010). These populations consisted of ten varieties (Inrat 69, Swabaa Elijia, Chili, Derbassi, Biskri, Khiar, Om Rabiaa, Maâli, Razzek and Karim 80) and eight generations (2F1, 2F2, 2B1 and 2B2) derived from two crosses: Swabaa Elijia (Pr) x Karim 80 (Ps) and Chili (Pr) x Karim 80 (Ps). A randomized complete block design was used for the experiment.

Evaluation of resistance to SNB

Resistance to SNB at the 2-3 and 6-7 leaf stages was assessed based on the percentage of leaf area affected, with each leaf being assigned to one of the following categories: 0, 1, 5, 10, 25, 50, 75 and 100% of the area affected (Eyal et al., 1987). For each plant, the percentage of affected area for all leaves was averaged for each stage. The number of plants evaluated varied depending on the generation and was greater in generations with greater segregation, such as F2, B1 and B2.

Statistical analyses

Analysis of variance using general linear model (GLM) procedures (SAS Institute, 1990) indicated that replication and site effects were significant. Therefore, the means for each generation were analyzed separately by site and replication.

Best-model: The means of different generations were analyzed by a joint scaling test as described by Rowe and Alexander (1980) using the weighted least squares method (Mather and Jinks, 1982; Kearsey and Pooni, 1996; Lynch and Walsh, 1998). The observed generation means were used to estimate the parameters of a model consisting only of mean (m), additive (a) and dominance (d) genetic effects. The adequacy of this genetic model was assessed using a chi-square goodness-of-fit statistic derived from deviations from this model. When the additive-dominance model was insufficient, a six-parameter model was applied. The significance of each parameter was determined by a t-test.

Heritability: Homogeneity of the variances of nonsegregating generations was tested using Bartlett's test (Bartlett, 1937). When the variances were heterogeneous, the environmental variance was replaced by an adequate number of separate parameters and pooled to produce a single environmental variance. Additive, dominance and environmental variance components were estimated using the maximum likelihood method with the observed variance of the six basic generations (Pr, Ps, F1, F2, B1 and B2) as the initial weights (df/2 x S2) (Lynch and Walsh, 1998). Narrow-sense heritability (h²n) was calculated as: h²n= VA/(VA + VD + VE), where VA is the additive genetic component of variance, VD is the dominance or nonadditive genetic component of variance, and VE is the environmental variance (Kearsey and Pooni, 1996).

Results

The incidence of SNB varied with the leaf developmental stage and, for most varieties, was more important at the 2-3 leaf stage than at the 6-7 leaf stage (Figure 1). For the varieties Beskri, Maâli and Swabaa Elijia there was no significant difference in the resistance between the leaf stages. There were differences in the resistance to SNB between genotypes during the two seasons and at the two sites. The varieties Swabaa Elijia and Chili were more tolerant than the other varieties. The varieties Inrat-69, Om Rabiaa and Maâli were moderately resistant, while Khiar, Derbessi, Razzek and Karim 80 were very susceptible.

For the two crosses, significant differences among generations were detected in all environments and at the two stages of growth. As expected, the parental lines were consistently different and the means for Pr and Ps in each cross and leaf stage tended to be extreme whereas the means for B1 and B2 tended to be close to those of their respective recurrent parents (Table 1). Estimates of the different types of gene effects in the individual crosses clearly illustrated this variation. At the 2-3 leaf stage, the variation among generation means for resistance to SNB was sufficiently explained by a simple additive-dominance model for the two crosses and the combination site -year (Table 2). The P-values ranged from 0.38 to 0.93 for the cross Razzek x Swabaa Elijia and from 0.93 to 0.99 for Karim 80 x Chili. The additive effect was more important than dominance effect and highly significant in all cases (Table 2). For the 6-7 leaf stage, an additive-dominance model did not adequately explain variation in the generation means for the two crosses and all combinations (cross -site -year) (Table 3). Instead, a digenic epistatic model was found to be appropriate for the majority of cases. In two cases, both the additive-dominance and digenic epistatic models failed to explain the variation in generation means (Table 3).

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Table 4 summarizes the estimates of different variance components and h²n. For the two growth stages, the variance components were estimated and used to calculate h²n for both crosses at the two sites and for the two replications. In all cases, the additive variance was highly significant and of greater magnitude than the environmental and dominance variance. The range of h²n was 0.63-0.67 in the two crosses and for all combinations.

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Discussion

In this study, we examined the role of growth stage in the mechanism of resistance to SNB. There was considerable variation in susceptibility among the varieties, with reactions ranging from moderately resistant to highly susceptible at both development stages. Karim 80 and Razzek, the most cultivated and productive cultivars in Tunisia, were very susceptible where Swabaa Elijia and Chili were the most resistant of all the varieties evaluated. For all varieties, the incidence of SNB was greater at the 2-3 leaf stage than at the 6-7 leaf stage at the two sites during the two seasons. The decrease in severity seen at the 6-7 leaf stage may reflect the ability of the plant to exploit a variety of genetic interactions. In contrast, at the 2-3 leaf stage, the necessary defense mechanisms may not yet have been established so that only additive and dominance effects were implicated in resistance to SNB. The difference in resistance between the two leaf stages was particularly pronounced for the varieties Om Rabiaa, Chili and Inrat 69. There was also a significant difference in resistance between the two stages for the variety Swabaa Elijia, and any breeding program based on this resistant variety would more efficient than using Chili.

In all cases, there were significant differences among the generation means for resistance to SNB for the two developmental stages and the two crosses, indicating genetic diversity for this attribute. For the 2-3 leaf stage, the variation among the generation means was best fitted by a model that included only additive and dominance effects for the two crosses and all combinations. For the 6-7 leaf stage, the significant digenic terms indicated that epistasis was responsible for departure from the additive-dominance model. In two cases, both the additive-dominance and digenic epistatic models failed to explain the variation among generation means, indicating that other mechanisms of genetic control such as higher order interactions or linkage effects were important. Further analyses of additional generations are needed to determine whether the cause of the model failure was the presence of higher order interactions or linkage effects.

Significant estimates of additive gene effects (a and aa) and dominance effects (d) were usually negative, indicating that these effects contributed more to resistance than to susceptibility (Mather and Jinks, 1982). There is no consensus in the literature on the type of inheritance involved in resistance to SNB. Some reports have concluded that additive and dominance effects are very important for SNB resistance (Wilkinson et al., 1990; Bostwick et al., 1993; Wicki et al., 1999; Kim et al., 2004). In contrast, others have indicated that epistasis has a significant role in the expression of SNB, e.g., Bruno and Nelson (1990) and Friesen et al. (2007) who reported that epistatic effects contributed to the resistance to SNB in winter wheat. Our results indicated that genetic interactions were expressed only when the plant was vigorous. At the 2-3 leaf stage the genetic mechanism of resistance is not well developed and the plant is unable to establish genetic interactions. In maize, resistance to the European corn borer was found to increase from the 3-leaf through to the 10-leaf stage (Bergvinson D, 1993, PhD thesis, University of Ottawa, Ottawa, Canada). Shaik et al. (1989) reported an effect of leaf stage on the variability of the reactions of Phaseolus vulgaris to Uromyces appendiculatus. Broers (1989) observed a large growth stage effect on latency period, infection frequency and urediosorus size during resistance to leaf rust in wheat.

The estimated h²n was consistent between growth stages for the two crosses in all cases and ranged from 0.63 to 0.67. A greater range of narrow-sense heritability (48%-68%) was reported by Fried and Meister (1987). The stability of narrow-sense heritability between development stages indicated that resistance to SNB was not under separate genetic control. However, a genetic interaction was evident only when the plants were vigorous.

There was some discrimination among varieties at the more advanced vegetative stage, where the genetic mechanism of resistance was functional. Our results showed higher narrow-sense heritability values, suggesting that genetic effects had a major role in resistance to SNB and that selection for this trait should be highly efficient. The presence of non-additive effects (dominance and epistasis) seen here suggested that the expected progress from selection during early segregating generations would be limited.

Acknowledgments

We thank Dr. Colin Hanbury of the University of Western Australia for helpful editorial comments and corrections to our manuscript.

Received: May 20, 2011

Accepted: September 27, 2011.

Associate Editor: Marcia Pinheiro Margis

License information: 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.

Aguilar V, Stamp P, Winzeler M, Winzeler H, Schachermayr G, Keller B, Zanetti S and Messmer MM (2005) Inheritance of field resistance to Stagonospora nodorum leaf and glume blotch and correlations with other morphological traits in hexaploid wheat (Triticum aestivum L.). Theor Appl Genet 111:325-336.
Bartlett MS (1937) Some examples of statistical methods of research in agriculture and applied biology. J R Stat Soc 4:137-183.
Blanco A, Bellomo MP, Cenci A, De Giovanni C, D'Ovidio R, Iacono E, Laddomada B, Pagnotta MA, Porceddu E, Sciancalepore A, et al. (1998) A genetic linkage map of durum wheat. Theor Appl Genet 97:721-728.
Bnejdi F and El Gazzah M (2008) Inheritance of resistance to yellowberry in durum wheat. Euphytica 163:225-230.
Bostwick DE, Ohm HW and Shaner G (1993) Inheritance of septoria glume blotch resistance in wheat. Crop Sci 33:439-443.
Broers LHM (1989) Influence of development stage and host genotype on three components of partial resistance to wheat leaf rust in spring wheat. Euphytica 44:187-195.
Bruno HH and Nelson LR (1990) Partial resistance to septoria glume blotch analyzed in winter wheat seedlings. Crop Sci 30:54-59.
Chu CG, Xu SS, Faris JD, Nevo E and Friesen TL (2008) Seedling resistance to tan spot and Stagonospora nodorum leaf blotch in wild emmer wheat (Triticum dicoccoides). Plant Dis 92:1229-1236.
Eyal Z (1981) Integrated control of Septoria diseases of wheat. Plant Dis 65:763-768.
Eyal Z, Scharen AL, Prescott JM and Van Ginkel M (1987) The Septoria Diseases of Wheat: Concepts and Methods of Disease Management. CIMMYT, Mexico D.F., 46 pp
Feng J, Ma H and Hughes GR (2004) Genetics of resistance to Stagonospora nodorum blotch resistance of hexaploid wheat. Crop Sci 44:2043-2048.
Fried PM and Meister E (1987) Inheritance of leaf and head resistance of winter wheat to Septoria nodorum in a diallel cross. Phytopathology 77:1371-1375.
Friesen TL, Meinhardt SW and Faris JD (2007) The Stagonospora nodorum-wheat pathosystem involves multiple proteinaceous host-selective toxins and corresponding host sensitivity genes that interact in an inverse gene-forgene manner. Plant J 51:681-692.
Friesen TL, Zhang Z, Solomon PS, Oliver RP and Faris JD (2008) Characterization of the interaction of a novel Stagonospora nodorum host-selective toxin with a wheat susceptibility gene1[W]. Plant Physiol 146:682-693.
Hu X, Bostwick D, Sharma H, Ohm H and Shaner G (1996) Chromosome and chromosomal arm locations of genes for resistance to septoria glume blotch in wheat cultivar Cotipora. Euphytica 91:251-257.
Kearsey MJ and Pooni HS (1996) The Genetical Analysis of Quantitative Traits. 1st edition. Chapman and Hall, London, 381 pp.
Kim YK, Brown-Guedira GL, Cox TS and Bockus WW (2004) Inheritance of resistance to Stagonospora nodorum leaf blotch in Kansas winter wheat cultivars. Plant Dis 88:530-536.
King JE, Cook RJ and Melville SC (1983) A review of septoria diseases of wheat and barley. Ann Appl Biol 103:345-373.
Lynch M and Walsh B (1998) Genetics and Analysis of Quantitative Traits. Sinauer Associates Inc., Sunderland, 980 pp.
Ma H and Hughes GR (1995) Genetic control and chromosomal location of Triticum timopheevii-derived resistance to Septoria nodorum blotch in durum wheat. Genome 38:332-338.
Mather K and Jinks JL (1982) Biometrical Genetics. 3rd edition. Chapman and Hall, London, 396 pp.
Murphy NEA, Loughman R, Wilson R, Lagudah ES, Appels R and Jones MGK (2000) Resistance to Septoria nodorum blotch in the Aegilops tauschii accession RL5271 is controlled by a single gene. Euphytica 113:227-233.
Oliver RE, Cai X, Wang RC, Xu SS and Friesen TL (2008) Resistance to tan spot and Stagonospora nodorum blotch in wheat-alien species derivatives. Plant Dis 92:150-157.
Parlevliet J (1977) Plant pathosystems: An attempt to elucidate horizontal resistance. Euphytica 26:553-556.
Peter SS, Rohan LGT, Kar-Chun T, Ormonde WDC and Richard PO (2006) Stagonospora nodorum: Cause of Stagonospora nodorum blotch of wheat. Mol Plant Pathol 7:147-156.
Rowe KE and Alexander WL (1980) Computations for estimating the genetic parameter in joint-scaling tests. Crop Sci 20:109-110.
SAS Institute (1990) SAS/STAT User's Guide ver. 6. 4th edition. SAS Institute, Cary.
Scott PR (1973) Incidence and effects of Septoria nodorum on wheat cultivars. Ann Appl Biol 75:321-329.
Shaik M, Dickinson TA and Steadman JR (1989) Variation in rust susceptibility in beans: Predicting lesion size from leaf developmental stage measured by leaf age, length and plastochron index. Phytopathology 79:1035-1042.
Trottet M and Merrien P (1982) Analysis of the behaviour of twenty lines of soft wheat towards Septoria nodorum Berk. Agronomie 2:727-734.
Wicki W, Winzeler M, Schmi JE, Stamp P and Messmer M (1999) Inheritance of resistance to leaf and glume blotch caused by Septoria nodorum Berk. in winter wheat. Theor Appl Genet 99:1265-1272.
Wilkinson CA, Murphy JP and Rufty RC (1990) Diallel analysis of components of partial resistance to Septoria nodorum in wheat. Plant Dis 74:47-50.

Send correspondence to

Fethi Bnejdi

Laboratoire de Génétique et Biométrie, Département de Biologie, Faculté des Sciences de Tunis

Université Tunis El Manar 2092, Tunisia

E-mail:

fethibnejdi@yahoo.fr

Publication Dates

Publication in this collection
24 May 2012
Date of issue
2012

History

Received
20 May 2011
Accepted
27 Sept 2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Aguilar V, Stamp P, Winzeler M, Winzeler H, Schachermayr G, Keller B, Zanetti S and Messmer MM (2005) Inheritance of field resistance to Stagonospora nodorum leaf and glume blotch and correlations with other morphological traits in hexaploid wheat (Triticum aestivum L.). Theor Appl Genet 111:325-336.

[2] Bartlett MS (1937) Some examples of statistical methods of research in agriculture and applied biology. J R Stat Soc 4:137-183.

[3] Blanco A, Bellomo MP, Cenci A, De Giovanni C, D'Ovidio R, Iacono E, Laddomada B, Pagnotta MA, Porceddu E, Sciancalepore A, et al. (1998) A genetic linkage map of durum wheat. Theor Appl Genet 97:721-728.

[4] Bnejdi F and El Gazzah M (2008) Inheritance of resistance to yellowberry in durum wheat. Euphytica 163:225-230.

[5] Bostwick DE, Ohm HW and Shaner G (1993) Inheritance of septoria glume blotch resistance in wheat. Crop Sci 33:439-443.

[6] Broers LHM (1989) Influence of development stage and host genotype on three components of partial resistance to wheat leaf rust in spring wheat. Euphytica 44:187-195.

[7] Bruno HH and Nelson LR (1990) Partial resistance to septoria glume blotch analyzed in winter wheat seedlings. Crop Sci 30:54-59.

[8] Chu CG, Xu SS, Faris JD, Nevo E and Friesen TL (2008) Seedling resistance to tan spot and Stagonospora nodorum leaf blotch in wild emmer wheat (Triticum dicoccoides). Plant Dis 92:1229-1236.

[9] Eyal Z (1981) Integrated control of Septoria diseases of wheat. Plant Dis 65:763-768.

[10] Eyal Z, Scharen AL, Prescott JM and Van Ginkel M (1987) The Septoria Diseases of Wheat: Concepts and Methods of Disease Management. CIMMYT, Mexico D.F., 46 pp

[11] Feng J, Ma H and Hughes GR (2004) Genetics of resistance to Stagonospora nodorum blotch resistance of hexaploid wheat. Crop Sci 44:2043-2048.

[12] Fried PM and Meister E (1987) Inheritance of leaf and head resistance of winter wheat to Septoria nodorum in a diallel cross. Phytopathology 77:1371-1375.

[13] Friesen TL, Meinhardt SW and Faris JD (2007) The Stagonospora nodorum-wheat pathosystem involves multiple proteinaceous host-selective toxins and corresponding host sensitivity genes that interact in an inverse gene-forgene manner. Plant J 51:681-692.

[14] Friesen TL, Zhang Z, Solomon PS, Oliver RP and Faris JD (2008) Characterization of the interaction of a novel Stagonospora nodorum host-selective toxin with a wheat susceptibility gene1[W]. Plant Physiol 146:682-693.

[15] Hu X, Bostwick D, Sharma H, Ohm H and Shaner G (1996) Chromosome and chromosomal arm locations of genes for resistance to septoria glume blotch in wheat cultivar Cotipora. Euphytica 91:251-257.

[16] Kearsey MJ and Pooni HS (1996) The Genetical Analysis of Quantitative Traits. 1st edition. Chapman and Hall, London, 381 pp.

[17] Kim YK, Brown-Guedira GL, Cox TS and Bockus WW (2004) Inheritance of resistance to Stagonospora nodorum leaf blotch in Kansas winter wheat cultivars. Plant Dis 88:530-536.

[18] King JE, Cook RJ and Melville SC (1983) A review of septoria diseases of wheat and barley. Ann Appl Biol 103:345-373.

[19] Lynch M and Walsh B (1998) Genetics and Analysis of Quantitative Traits. Sinauer Associates Inc., Sunderland, 980 pp.

[20] Ma H and Hughes GR (1995) Genetic control and chromosomal location of Triticum timopheevii-derived resistance to Septoria nodorum blotch in durum wheat. Genome 38:332-338.

[21] Mather K and Jinks JL (1982) Biometrical Genetics. 3rd edition. Chapman and Hall, London, 396 pp.

[22] Murphy NEA, Loughman R, Wilson R, Lagudah ES, Appels R and Jones MGK (2000) Resistance to Septoria nodorum blotch in the Aegilops tauschii accession RL5271 is controlled by a single gene. Euphytica 113:227-233.

[23] Oliver RE, Cai X, Wang RC, Xu SS and Friesen TL (2008) Resistance to tan spot and Stagonospora nodorum blotch in wheat-alien species derivatives. Plant Dis 92:150-157.

[24] Parlevliet J (1977) Plant pathosystems: An attempt to elucidate horizontal resistance. Euphytica 26:553-556.

[25] Peter SS, Rohan LGT, Kar-Chun T, Ormonde WDC and Richard PO (2006) Stagonospora nodorum: Cause of Stagonospora nodorum blotch of wheat. Mol Plant Pathol 7:147-156.

[26] Rowe KE and Alexander WL (1980) Computations for estimating the genetic parameter in joint-scaling tests. Crop Sci 20:109-110.

[27] SAS Institute (1990) SAS/STAT User's Guide ver. 6. 4th edition. SAS Institute, Cary.

[28] Scott PR (1973) Incidence and effects of Septoria nodorum on wheat cultivars. Ann Appl Biol 75:321-329.

[29] Shaik M, Dickinson TA and Steadman JR (1989) Variation in rust susceptibility in beans: Predicting lesion size from leaf developmental stage measured by leaf age, length and plastochron index. Phytopathology 79:1035-1042.

[30] Trottet M and Merrien P (1982) Analysis of the behaviour of twenty lines of soft wheat towards Septoria nodorum Berk. Agronomie 2:727-734.

[31] Wicki W, Winzeler M, Schmi JE, Stamp P and Messmer M (1999) Inheritance of resistance to leaf and glume blotch caused by Septoria nodorum Berk. in winter wheat. Theor Appl Genet 99:1265-1272.

[32] Wilkinson CA, Murphy JP and Rufty RC (1990) Diallel analysis of components of partial resistance to Septoria nodorum in wheat. Plant Dis 74:47-50.

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