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Evaluation Of Slovak Winter Wheat Quality In Terms Of Puroindoline Genes

Evaluation Of Slovak Winter Wheat Quality In Terms Of Puroindoline Genes DOI: 10.1515/agri-2015-0014 LENKA KLCOVÁ1,2*, DANIELA MIKULÍKOVÁ1, STEFAN MASÁR1, ALZBETA ZOFAJOVÁ1 National Agricultural and Food Centre Constantine The Philosopher University in Nitra KLCOVÁ, L. MIKULÍKOVÁ, D. MASÁR, S. ZOFAJOVÁ, A.: Evaluation of Slovak winter wheat quality in terms of puroindoline genes. Agriculture (Ponohospodárstvo), vol. 61, 2015, no. 3, pp. 88­96. The grain hardness of 100 current and 24 old superior Slovak winter wheat cultivars was studied at molecular level. Using polymerase chain reactions (PCRs), normal and null alleles of both puroindoline Pina and Pinb genes were identified. Three different genotypes were found: 1) normal allele of both genes (dominant wild type with soft endosperm) - Pina-D1a/Pinb-D1a; 2) normal allele of the Pina gene and null allele of the Pinb gene ­ PinaD1a/Pinb-D1b; and 3) null allele of the Pina gene and normal allele of the Pinb gene Pina-D1b/Pinb-D1a. No Slovak current as well as old wheat cultivar had together null allele of both puroindoline genes. The frequencies of wild-type Pinb-D1a and null Pinb-D1b allele in current cultivars were 62.0% and 38.0%, respectively, whilst in old cultivars, 8.3% and 91.7%, respectively. Regarding null allele Pina-D1b of puroindoline Pina gene, only in Rheia current cultivar, one was found. All other cultivars had wild-type Pina-D1a allele. Alacris, Alana, Axis, Balada, Blava, Bona Dea, Bruta, Charger, Hana, Ilona, IS Karpatia, Ludwig and Sulamit current cultivars were selected as donors of the null Pinb-D1b allele for molecular breeding in order to improve the grain hardness as important wheat quality trait. Statistically significant correlations between null Pinb-D1b allele and grain size as well as colour were found. In comparison with wild type, cultivars with this null allele have paler and longer grain with higher length-to-width ratio and lighter grain colour. Key words: current and old Slovak cultivars, grain size and colour, null allele, polymerase chain reaction, puroindoline genes, winter wheat The variation in grain hardness (hard or soft endosperm texture) is one of the most important traits that determine the utilisation and marketing of hexaploid wheat. Wheat grain texture is determined by the degree of grain hardness or softness. Hardness is defined as `difficulty to penetrate or reduce to smaller fragments'. This characteristic strongly influences the functionality of wheat and affects a range of parameters including the milling (tempering, milling yield, flour particle size, shape and density of flour particles), baking and end-use properties (Giroux & Morris 1998; Morris 2002). An important functional difference between hard and soft wheats is in their water absorption. Hard wheat varieties are typically higher in protein content (12­15%) and stronger gluten-forming proteins than soft wheat ones (5­10%). Grain hardness was negatively correlated with break flour yield, flour yield and mixing score and positively correlated with flour ash (Martin et al. 2001). Grain hardness was not correlated with loaf volume or crumb grain score (Hogg et al. 2005). Wheat hardness (the degree of adhesion between the starch granules and the protein matrix) is regulated by the friabilin. The discovery of this 15-kDa Mgr. Lenka Klcová (*Corresponding author), National Agricultural and Food Centre ­ Research Institute of Plant Production, Bratislavská cesta 122, 921 68 Piesany, Slovak Republic. E-mail: l.klcova@vurv.sk Constantine The Philosopher University, Faculty of Natural Sciences, A. Hlinku 1, 949 01 Nitra, Slovak Republic protein provided a biochemical way to distinguish between hard and soft wheats. It is present in larger amounts in soft wheats compared to hard ones and consists of three major polypeptides (Gautier et al. 1994; Rahman et al. 1994; Giroux & Morris 1997): puroindoline-a (Pina), puroindoline-b (Pinb) and grain softness protein 1 (Gsp-1). A single locus Hardness (Ha) for the grain endosperm texture was identified at the short arm of chromosome 5D (Turnbull et al. 2003). They designated the gene Hardness, with the soft allele Ha and the hard allele ha. Softness is a dominant trait. Previous studies suggested that the grain hardness is correlated with the soft type Pina and Pinb, not total puroindoline (Swan et al. 2006). Igrejas et al. (2001) found Pinb to be more closely correlated with grain hardness than Pina. The soft grain texture in wheat is the result of both puroindoline genes occurrence in the wild-type form. When one of the puroindolines is either absent or altered by various mutations, it results in a hard texture. Gene sequence variation and mutations of both puroindoline genes account for the majority of variation in the wheat grain texture. To date, in winter wheat, 16 and 24 recessive null alleles were identified at the Pina and Pinb loci, respectively (Bhave & Morris 2008). However, still ­ from time to time ­ new mutations of both puroindoline genes are discovered (Chen et al. 2009). Most of mutate alleles occur only isolated in some localities (Lilemo & Morris 2000; Chen et al. 2005, 2006), for instance, in Northern Europe (Pinb-D1c allele), Sweden and Netherlands (Pinb-D1d), a few of Chinese landrances (Pina-D1l, PinaD1n, PinbD1p), Jiangsu province (Pina-D1m) and Guizhou province (Pinb-D1t). Some of the alleles result in particular single nucleotide change or deletion at various positions in the coding region, another result in the `stop' codon TGA (tryptophan). The dominant wild-type alleles (Pina-D1a and Pinb-D1a), as well as recessive Pinb-D1b null allele, occur most frequently. The Pina-D1a allele (wild type) is present in all soft hexaploid and possibly all hard hexaploid wheats carrying the hardness mutation in puroindoline-b. The Pinb-D1a allele (wild type) occurs in all soft hexaploid and possibly in all hard hexaploid wheats carrying the mutation in puroindoline-a. The PinbD1b is a `loss of function' mutation. It is prevalent amongst a wide set of both recent and historical cultivars (Giroux & Morris 1997). Grain hardness is largely controlled by genetic factors; however, it can be also partly affected by the environmental and other factors allowing N management, tillage system, fertiliser as well as fallow management, pest infestations, moisture, gliadin composition, lipid, starch and pentosan content (Huebner & Gaines 1992; Peterson et al. 1992; Lyon & Shelton 1999; Konopka et al. 2005b; Oury et al. 2015). Owing to the lack of information about hardness of Slovak winter wheat cultivars at molecular level, the specific objective of this study was to discover allelic variation of both puroindoline genes in current and old Slovak cultivars. Another aim was to recognize the relation of glycine serine point mutation to the grain size and colour as well as to determine suitable cultivars as donors of the Pinb-D1b null allele for marker-assisted selection (MAS) in order to manipulate the grain hardness. MATERIAL AND METHODS Plant materials Seed samples (200 grains of each cultivar) of 100 current (registered in the Slovak National List of Varieties) and 24 old superior Slovak winter wheat cultivars were obtained from The Gene Bank of Slovak Republic in Piesany (kindly provided by Dr. Pavol Hauptvogel). Following the published data (McIntosh et al. 2003), Bolero cultivar (Italy) was used as standard for the detection of normal allele of both puroindoline genes. In addition, Amidon cultivar (USA), which has null allele (Pina-D1b) of the Pina gene, as well as Brasilia (Italy) and Pascal (France) cultivars possessing null allele (Pinb-D1b) of the Pinb gene were used. Genomic DNA preparation DNA was extracted from 100 mg of young wheat leaf tissue using the DNeasy Plant Mini Kit (Qiagen, Hilden, Germany) according to the manufacturer's instructions. Primers and PCR conditions Amplification of the Pina and Pinb puroindoline genes was performed using sequence-specific primers Pina-D1-F, Pina-D1-R, Pinb-D1-F, Pinb-D1-R, Pinb-glyR and Pinb-serR (Gautier et al. 1994; Giroux & Morris 1997; Tranquilli et al. 1999). The sequences for forward (F) and reverse (R) primers were as follows: Pina-D1-F: 5-CCC TGT AGA GAC AAA GCT AA-3 Pina-D1-R: 5-TCA CCA GTA ATA GCC AAT AGT G-3 Pinb-D1-F: 5-ATG AAG ACC TTA TTC CTC CTA-3 Pinb-D1-R: 5-TCA CCA GTA ATA GCC ACT AGG GAA-3 Pinb-glyR: 5-CTC ATG CTC ACA GCC GCC-3 Pinb-serR: 5-CTC ATG CTC ACA GCC GCT-3 The polymerase chain reactions (PCRs) were performed in a final reaction volume of 15 µl using 25 ng of genomic DNA, 1 × PCR buffer, 1.5 mM MgCl 2, 0.2 mM dNTP, 0.2 M of each forward and reverse primers and 0.8 U of Taq DNA polymerase (Invitrogen). The amplification conditions for Pina included initial denaturation at 94°C for 3 min, followed by 37 cycles at 94°C for 90 s, at 55°C for 90 s, at 72°C for 2 min and final extension at 72°C for 10 min. To amplify Pinb, annealing temperature was raised up to 58°C. PCRs were conducted using PTC-200 thermal cycler (MJ Research Inc., Waltham). Amplified PCR products were analysed on 1.4% agarose gels, stained with ethidium bromide. Amplification is observed only for the wild-type Pina-D1a, yielding 330 bp fragment; null allele Pina-D1b amplifies no band. After amplification of a 447-bp segment of the Pinb-D1 gene using primers designed by Gautier et al. (1994), the PCR product was digested by the restriction endonuclease BsrBI. The enzyme recognises the sequence with the glycine serine mutation but not the sequence without the mutation. After digestion, fragments of 320 bp are expected for genotypes lacking the mutation (normal allele), whilst fragments of 200 bp are expected for genotypes carrying the null allele for hard texture (Tranquilli et al. 1999). For differen90 tiation of normal Pinb-D1a from null Pinb-D1b allele, primers Pinb-glyR/Pinb-serR and PinbD1-F were used (Gautier et al. 1994). Grain parameters assessment In triplicate, 36 grains of two genetically related pairs of old wheat cultivars Slovenská B and Slovenská 777 (Slovenská B line II and Slovenská B line III as well as Slovenská 777 line I and Slovenská 777 line V) were examined for grain dimensions and 24 grains for colour. Digital image analysis (images were obtained with scanner HP Scanjet 4370, Hewlet Packard) was used to measure grain length and width (Tahir et al. 2007) as well as red, green and blue (RGB) colour components. The methods of measurement were similar as described by Taska et al. (2005). Dimension parameters were measured in the Microsoft photo editor 3. To determine the grain colour histograms of RGB component, the Assess Image Analysis Software for Plant Disease Quantification were used (Lamari 2002). Statistical methods Standard statistical testing including analysis of variance (ANOVA), general linear model, Bonferroni test and Tukey's HSD test (statistical software package SPSS® 11.5) was used for data evaluation. The value P < 0.05 was considered statistically significant. RESULTS AND DISCUSSION All 124 evaluated wheat cultivars belong to following alleles of the Pina and Pinb genes (Table 1): normal Pina-D1a and Pinb-D1a and null Pina-D1b and Pinb-D1b alleles. Concerning the Pina gene, null allele Pina-D1b, which is associated with harder texture than Pinb-D1b mutation (Morris & Massa 2003), was found only in Rheia current cultivar. Other current cultivars, as well as old cultivars, have wild-type Pina-D1a allele. Regarding the Pinb gene, frequencies of normal (wild-type) Pinb-D1a and null Pinb-D1b allele were 62.0% and 38.0%, respectively, in current cultivars, whilst 8.3% and 91.7%, respectively, in historical ones. Recessive null PinbD1b allele was found mostly in cultivars with good bread-making quality (Alacris, Alana, Axis, Balada, Blava, Bona Dea, Bruta, Charger, Hana, Ilona, IS Karpatia, Ludwig, and Sulamit). Surprisingly, almost all (22 from 24) old superior cultivars were homozygous for recessive null Pinb-D1b allele. The null Pinb-D1b allele was detected in Slovenská 777 (I­IV), Stupická Bastard (I­V), Kastická bezosinatá (I­III), Radosinská Dorada (I­V), Slovenská 200 I, Slovenská B (I and II) and Bucianska cervenoklasá (I and II) cultivars. Because all varieties had normal (Pina-D1a and Pinb-D1a) or the most frequent null allele (Pina-D1b and Pinb-D1b) of both puroindoline genes, we did not look for other sporadically occurring null alleles. Three different genotypes of puroindoline genes were found: 1) normal allele of both genes, Pina-D1a/Pinb-D1a (dominant wild type with soft grain); 2) normal allele of the Pina gene and null allele of the Pinb gene, Pina-D1a/Pinb-D1b (moderately hard grain); and 3) null allele of the Pina gene and normal allele of the Pinb gene, Pina-D1b/ Pinb-D1a (very hard grain). Neither in the current nor in the old Slovak wheat cultivars we detected simultaneous presence of null alleles of Pina and Pinb genes. Dominant wild type with soft grain was achieved in 61.0% of current cultivars and in only 8.3% of old wheat cultivars (Table 2). The genotype Pinb-D1b was detected in 38.0% of current and 91.7% of old superior cultivars. Whilst in old cultivars, the Pina-D1a/Pinb-D1b genotype with moderately hard grain dominated, in current cultivars, the dominant wild-type Pina-D1a/Pinb-D1a with soft grain associated with poorer wheat quality was more frequent. This fact points to forgetting of grain hardness importance in breeding for other wheat qualitative traits. Our results provide the possibility of Slovak wheat cultivars breeding for hardness improvement. Obtained results from cultivars of the Slovak origin are in agreement with observations of other authors who also found the Pinb-D1b mutation as prevalent amongst a wide set of both recent and historical wheat cultivars of different origin (Giroux & Morris 1997). The null allele has a glycine serine substitution at position 46 in the puroindoline Pinb gene (Giroux & Morris 1997). The Pinb-D1b allele was first characterised in the `Chinese Spring' T a b l e 1 The frequency of homozygous alleles in winter wheat cultivars Pina gene Cultivars (number) Current registered (100) Old (24) Normal allele Pina-D1a [%] 99.0 100.0 Null allele Pina-D1b [%] 1.0 0.0 Normal allele Pinb-D1a [%] 62.0 8.3 Pinb gene Null allele Pinb-D1b [%] 38.0 91.7 T a b l e 2 The frequency of homozygous genotypes in winter wheat cultivars Puroindoline genotype Pina-D1a/Pinb-D1a Pina-D1b/Pinb-D1a Pina-D1a/Pinb-D1b Pina-D1b/Pinb-D1b Current cultivars [%] 61.0 1.0 38.0 0.0 Old cultivars [%] 8.3 0.0 91.7 0.0 Pina ­ Puroindoline-a gene; Pinb ­ Puroindoline-b gene substitution line possessing the 5D chromosomes of `Cheyenne'. Giroux & Morris (1997) discovered that the hardness mutation is a single base change (GGCAGC) in the codon of Gly-46, converting glycine to serine. The mutation is highly conserved and might explain the most of phenotypically hard hexaploid wheats. Lillemo and Morris (2000) showed that the prevalence of mutation might be largely related to the gene pools of interest and also the particular area of origin. Genotypes with Pinb-D1b possess significantly lower flour ash content and higher milling yield than those of genotypes with Pina-D1b. For steamed bread, mean scores for loaf volume, crumb colour, width and structure and total score of Pinb-D1b genotypes were significantly higher than those of genotypes with Pina-D1b and wild-type Pinb-D1a (Chen et al. 2007). Two old Slovak wheat cultivars, Slovenská B and Slovenská 777, had different alleles of the Pinb gene (Slovenská B line III had normal allele and Slovenská B line II the null allele, Slovenská 777 line V had normal and Slovenská 777 line I had the null allele). Therefore, we focused on comparing the width, length and RGB colour components in relation to the presence of the null and normal allele of Pinb-D1b gene in these genetically related lines of cultivars Slovenská B and Slovenská 777. Concerning Pinb gene, significant influence on grain length, grain length-to-width ratio, width-tolength ratio and grain colour components red, green and blue in RGB colour model was found (Table T a b l e 3 Mean squares from ANOVA for wheat grain size and grain colour components to alleles of the Pinb gene Variability of the Pinb gene Grain dimensions Between groups Length Within groups Total Between groups Width Within groups Total Between groups Length/width Within groups Total Between groups Width/length Within groups Total Grain colour components Between groups Red Within groups Total Between groups Green Within groups Total Between groups Blue Within groups NS df 1 46 47 1 46 47 1 46 47 1 46 47 1 142 143 1 142 143 1 142 143 not significant Mean squares 8,576.053+ 1,257.283 1,313.985NS 809.291 0.373 0.043 0.018 0.002 18,292.563 303.642 18,225.000 235.359 33,580.562 282.534 Total Significant at the 0.01 level; + significant at the 0.05 level; 3). From Table 4, the rounder kernel in cultivars having null allele of the Pinb gene is evident. The mean values of grain length and width were 623 and 288 pixels for normal allele Pinb-D1a and 596 and 299 pixels for null allele Pinb-D1b, respectively. In comparison with normal allele Pinb-D1a, the cultivars with the null allele Pinb-D1b have significantly shorter kernel (P < 0.05) and lower length-to-width ratio (P < 0.01). Using digital image analysis, significant differences in wheat grain size and colour were ascertained. Grain size influences milling quality of wheat (Marshall et al. 1986). Sizes together with density determine grain weight, which has a favourable effect on agronomic and flour yield of wheat (Dziki & Laskowski 2005). Quantitative trait loci (QTL) for grain length and width in bread wheat were found on various chromosomes (Dholakia et al. 2003; Breseghello & Sorrells 2007). From the low genetic correlation between grain length and width found, Bergman et al. (2000) deduced their independent inheritance. In addition, cultivars with the null allele PinbD1b have lighter grain colour. RGB colour components in cultivars with the null allele have significantly (P < 0.01) higher values as compared to cultivars with normal allele (Table 5). Mean squares from general linear model and coefficient of determination (R2) for length, width, length-to-width ratio, width-to-length ratio and colour components RGB indicate that the fitted model explains significant (P < 0.01) great deal of variability (Table 6). Dobraszczyk et al. (2002) indicated that grain hardness corresponds to endosperm density. Results of Konopka et al. (2005a) pointed to relationship between the endosperm colour and grain hardness in wheat cultivars. However, the authors found that environment causes variability of the protein content, hardness, vitreousness, length and size of grains, and all these can affect grains colour. T a b l e 4 Mean values of grain size in relation to the Pinb gene (the Bonferroni test) Grain dimensions Length Width Length/width Width/length Allele of the Pinb gene Normal Null Pinb-D1b Normal Null Pinb-D1b Normal Null Pinb-D1b Normal Null Pinb-D1b N 24 24 24 24 24 24 24 24 NS Mean 623.089 596.355 288.473 298.937 2.182 2.005 0.463 0.502 not significant Std. error 7.027 7.443 5.426 6.330 0.048 0.036 0.441 0.484 Difference 26.733+ 10.464NS 0.176 0.039 Significant at the 0.01 level; + significant at the 0.05 level; T a b l e 5 The effect of alleles on RGB colour components in relation to the Pinb gene (Tukey's HSD test) Cultivar Slovenská B III Slovenská 777 V Slovenská 777 I Slovenská B II Allele of Pinb gene Normal Normal Null Pinb-D1b Null Pinb-D1b N 36 36 36 36 Red (R) 187.86 200.50 218.03 a a Green (G) 139.58 148.89 167.08 a a Blue (B) 50.53a 52.39a 78.72b 85.28b 215.42b 166.39b Different letter (a, b) indicate statistically significant differences (P 0.01) CONCLUSIONS Wheat marketing system established the primary classification of hexaploid wheat based on the endosperm texture. The grain hardness is one of the most important traits and affects a range of parameters including the milling, baking and end-use properties of wheat. The aim of our work was to evaluate the grain hardness of 100 current and 24 old superior Slovak winter wheat cultivars at molecular level and determine its relation to grain size and colour. Normal (wild-type) and null alleles of both puroindoline Pina and Pinb genes were identified using PCRs. In conclusion, no one of cultivars tested had together null allele of both Pin genes. Only one null Pina allele was identified in Slovak winter wheat cultivars. Null allele Pinb-D1b (`loss of function' mutation resulting from the replacement of glycine by serine T a b l e 6 Mean squares from general linear model and coefficient of determination (R2) for length, width, length/width, width/length, and colour component red, green, blue in relation to the Pinb gene Source Model Length Pinb Error Total Model Width Pinb Error Total Model Length/Width Pinb Error Total Model Width/Length Pinb Error Total Model Red Pinb Error Total Model Green Pinb Error Total Model Blue Pinb Error df Grain dimensions 2 2 46 48 2 2 46 48 2 2 46 48 2 2 46 48 Colour components 2 2 142 144 2 2 142 144 2 2 142 144 3,048,285.951 3,048,285.951 303.642 Mean square 8,926,552.480 8,926,552.480 1,257,283.000 R2 0.997 2,070,960.041 2,070,960.041 809.291 105.376 105.376 0.043 5.592 0.002 1,749,779.514 1,749,779.514 235.359 337,390.562 337,390.562 282.534 Total Significant at the 0.01 level at position 46), which is prevalent amongst most of the European countries, was detected in 38.0% of current and 91.7% of old superior cultivars. Its incidence was higher in old superior in comparison with current cultivars. Statistically significant correlations between null Pinb-D1b allele and grain size as well as colour were found. The cultivars with the null allele Pinb-D1b have significantly shorter kernel, lower length-to-width ratio and lighter grain colour. We selected cultivars that would be helpful in molecular breeding programme as donors of the null allele in order to manipulate grain hardness as one of the main quality traits of winter wheat. Acknowledgements. Supported by the Ministry of Agriculture and Rural Development of the Slovak Republic, Project GENETIMPRO. Authors thank Mrs. Jela Klcová for her excellent technical assistance. and biochemical characterization pf puroindoline-a and b alleles in Chinese landraces and historical cultivars. In Theoretical and Applied Genetics, vol. 112, pp. 400­ 409. DOI: 10.1007/s00122-005-0095-z. DHOLAKIA, B.B. ­ AMMIRAJU, J.S.S. ­ SINGH, H. ­ LAGU, M.D. ­ RÖDER, M.S. ­ RAO, V.S. ­ DHALIWAL, H.S. ­ RANJEKAR, P.K. ­ GUPTA, V.S. 2003. Molecular marker analysis of kernel size and shape in bread wheat. In Plant Breeding, vol. 122, pp. 392­ 395. DOI: 10.1046/j.1439-0523.2003.00896.x. DOBRASZCZYK, B.J. ­ WHITWORTH, M.B. ­ VINCENT, J.F.V. ­ KHAN A.A. 2002. Single kernel wheat hardness and fracture properties in relation to density and the modelling of fracture in wheat endosperm. In Journal of Cereal Science, vol. 35, pp. 245­263. DZIKI, D. ­ LASKOWSKI, J. 2005. Wheat kernel physical properties and milling process. In Acta Agrophysica, vol. 6, pp. 59­71. GAUTIER, M.F. ­ ALEMAN, M.E. ­ GUIRAO, A. ­ MARION, D. ­ JOUDRIER P. 1994. Triticum aestivum L. puroindolines, two basic cysteine-rich seed proteins: cDNA sequence analysis and developmental gene expression. In Plant Molecular Biology, vol. 25, pp. 43­57. DOI: 10.1007/BF00024197. GIROUX, M.J. ­ MORRIS, C.F. 1997. A glycine to serine change in puroindoline-b is associated with wheat grain hardness and low levels of starch-surface friabilin. In Theoretical and Applied Genetics, vol. 95, pp. 857­864. DOI: 10.1007/s001220050636. GIROUX, M.J. ­ MORRIS, C.F. 1998. Wheat grain hardness results from highly conserved mutation in the friabilin components puroindoline-a and b. In Proceedings of the National Academy of Science USA, vol. 95, pp. 6262­6266. HOGG, A.C. ­ BEECHER, B. ­ MARTIN, J.M. ­ MEYER, F. ­ TALBERT, L. ­ LANNING S. ­ GIROUX, M.J. 2005. Hard wheat milling and bread baking traits affected by the seedspecific overexpression of puroindolines. In Crop Science, vol. 45, pp 871­878. DOI: 10.2135/cropsci2004.0113. HUEBNER, F.R. ­ GAINES, C.S. 1992. Relation between wheat kernel hardness, environment, and gliadin composition. In Cereal Chemistry, vol. 69, pp. 148­151. IGREJAS, G. ­ GABORIT, T. ­ OURY, F.X. ­ CHIRON, H. ­ MARION, D. ­ BRANLARD G. 2001. Genetic and environmental effects on puroindoline-a and puroindoline-b and their technological properties in French bread wheats. In Journal of Cereal Science, vol. 34, pp. 37­47. KONOPKA, I. ­ KOZIROK, W. ­ TASKA M. 2005a. Wheat endosperm hardness. Part I. Relationship to colour of kernel cross-section. In European Food Research and Technology, vol. 220, pp. 11­19. DOI: 10.1007/s00217-004-1037-8. KONOPKA, I. ­ ROTKIEWICZ, D. ­ TASKA M. 2005b. Wheat endosperm hardness. Part II. Relation to content and composition of flour lipids. In European Food Research and Technology, vol. 220, pp. 20­24. DOI: 10.1007/s00217-004-1038-7. LAMARI, L. 2002. Assess: Image Analysis Software for plant disease quantification V1.0. In BOCK, http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Agriculture de Gruyter

Evaluation Of Slovak Winter Wheat Quality In Terms Of Puroindoline Genes

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DOI: 10.1515/agri-2015-0014 LENKA KLCOVÁ1,2*, DANIELA MIKULÍKOVÁ1, STEFAN MASÁR1, ALZBETA ZOFAJOVÁ1 National Agricultural and Food Centre Constantine The Philosopher University in Nitra KLCOVÁ, L. MIKULÍKOVÁ, D. MASÁR, S. ZOFAJOVÁ, A.: Evaluation of Slovak winter wheat quality in terms of puroindoline genes. Agriculture (Ponohospodárstvo), vol. 61, 2015, no. 3, pp. 88­96. The grain hardness of 100 current and 24 old superior Slovak winter wheat cultivars was studied at molecular level. Using polymerase chain reactions (PCRs), normal and null alleles of both puroindoline Pina and Pinb genes were identified. Three different genotypes were found: 1) normal allele of both genes (dominant wild type with soft endosperm) - Pina-D1a/Pinb-D1a; 2) normal allele of the Pina gene and null allele of the Pinb gene ­ PinaD1a/Pinb-D1b; and 3) null allele of the Pina gene and normal allele of the Pinb gene Pina-D1b/Pinb-D1a. No Slovak current as well as old wheat cultivar had together null allele of both puroindoline genes. The frequencies of wild-type Pinb-D1a and null Pinb-D1b allele in current cultivars were 62.0% and 38.0%, respectively, whilst in old cultivars, 8.3% and 91.7%, respectively. Regarding null allele Pina-D1b of puroindoline Pina gene, only in Rheia current cultivar, one was found. All other cultivars had wild-type Pina-D1a allele. Alacris, Alana, Axis, Balada, Blava, Bona Dea, Bruta, Charger, Hana, Ilona, IS Karpatia, Ludwig and Sulamit current cultivars were selected as donors of the null Pinb-D1b allele for molecular breeding in order to improve the grain hardness as important wheat quality trait. Statistically significant correlations between null Pinb-D1b allele and grain size as well as colour were found. In comparison with wild type, cultivars with this null allele have paler and longer grain with higher length-to-width ratio and lighter grain colour. Key words: current and old Slovak cultivars, grain size and colour, null allele, polymerase chain reaction, puroindoline genes, winter wheat The variation in grain hardness (hard or soft endosperm texture) is one of the most important traits that determine the utilisation and marketing of hexaploid wheat. Wheat grain texture is determined by the degree of grain hardness or softness. Hardness is defined as `difficulty to penetrate or reduce to smaller fragments'. This characteristic strongly influences the functionality of wheat and affects a range of parameters including the milling (tempering, milling yield, flour particle size, shape and density of flour particles), baking and end-use properties (Giroux & Morris 1998; Morris 2002). An important functional difference between hard and soft wheats is in their water absorption. Hard wheat varieties are typically higher in protein content (12­15%) and stronger gluten-forming proteins than soft wheat ones (5­10%). Grain hardness was negatively correlated with break flour yield, flour yield and mixing score and positively correlated with flour ash (Martin et al. 2001). Grain hardness was not correlated with loaf volume or crumb grain score (Hogg et al. 2005). Wheat hardness (the degree of adhesion between the starch granules and the protein matrix) is regulated by the friabilin. The discovery of this 15-kDa Mgr. Lenka Klcová (*Corresponding author), National Agricultural and Food Centre ­ Research Institute of Plant Production, Bratislavská cesta 122, 921 68 Piesany, Slovak Republic. E-mail: l.klcova@vurv.sk Constantine The Philosopher University, Faculty of Natural Sciences, A. Hlinku 1, 949 01 Nitra, Slovak Republic protein provided a biochemical way to distinguish between hard and soft wheats. It is present in larger amounts in soft wheats compared to hard ones and consists of three major polypeptides (Gautier et al. 1994; Rahman et al. 1994; Giroux & Morris 1997): puroindoline-a (Pina), puroindoline-b (Pinb) and grain softness protein 1 (Gsp-1). A single locus Hardness (Ha) for the grain endosperm texture was identified at the short arm of chromosome 5D (Turnbull et al. 2003). They designated the gene Hardness, with the soft allele Ha and the hard allele ha. Softness is a dominant trait. Previous studies suggested that the grain hardness is correlated with the soft type Pina and Pinb, not total puroindoline (Swan et al. 2006). Igrejas et al. (2001) found Pinb to be more closely correlated with grain hardness than Pina. The soft grain texture in wheat is the result of both puroindoline genes occurrence in the wild-type form. When one of the puroindolines is either absent or altered by various mutations, it results in a hard texture. Gene sequence variation and mutations of both puroindoline genes account for the majority of variation in the wheat grain texture. To date, in winter wheat, 16 and 24 recessive null alleles were identified at the Pina and Pinb loci, respectively (Bhave & Morris 2008). However, still ­ from time to time ­ new mutations of both puroindoline genes are discovered (Chen et al. 2009). Most of mutate alleles occur only isolated in some localities (Lilemo & Morris 2000; Chen et al. 2005, 2006), for instance, in Northern Europe (Pinb-D1c allele), Sweden and Netherlands (Pinb-D1d), a few of Chinese landrances (Pina-D1l, PinaD1n, PinbD1p), Jiangsu province (Pina-D1m) and Guizhou province (Pinb-D1t). Some of the alleles result in particular single nucleotide change or deletion at various positions in the coding region, another result in the `stop' codon TGA (tryptophan). The dominant wild-type alleles (Pina-D1a and Pinb-D1a), as well as recessive Pinb-D1b null allele, occur most frequently. The Pina-D1a allele (wild type) is present in all soft hexaploid and possibly all hard hexaploid wheats carrying the hardness mutation in puroindoline-b. The Pinb-D1a allele (wild type) occurs in all soft hexaploid and possibly in all hard hexaploid wheats carrying the mutation in puroindoline-a. The PinbD1b is a `loss of function' mutation. It is prevalent amongst a wide set of both recent and historical cultivars (Giroux & Morris 1997). Grain hardness is largely controlled by genetic factors; however, it can be also partly affected by the environmental and other factors allowing N management, tillage system, fertiliser as well as fallow management, pest infestations, moisture, gliadin composition, lipid, starch and pentosan content (Huebner & Gaines 1992; Peterson et al. 1992; Lyon & Shelton 1999; Konopka et al. 2005b; Oury et al. 2015). Owing to the lack of information about hardness of Slovak winter wheat cultivars at molecular level, the specific objective of this study was to discover allelic variation of both puroindoline genes in current and old Slovak cultivars. Another aim was to recognize the relation of glycine serine point mutation to the grain size and colour as well as to determine suitable cultivars as donors of the Pinb-D1b null allele for marker-assisted selection (MAS) in order to manipulate the grain hardness. MATERIAL AND METHODS Plant materials Seed samples (200 grains of each cultivar) of 100 current (registered in the Slovak National List of Varieties) and 24 old superior Slovak winter wheat cultivars were obtained from The Gene Bank of Slovak Republic in Piesany (kindly provided by Dr. Pavol Hauptvogel). Following the published data (McIntosh et al. 2003), Bolero cultivar (Italy) was used as standard for the detection of normal allele of both puroindoline genes. In addition, Amidon cultivar (USA), which has null allele (Pina-D1b) of the Pina gene, as well as Brasilia (Italy) and Pascal (France) cultivars possessing null allele (Pinb-D1b) of the Pinb gene were used. Genomic DNA preparation DNA was extracted from 100 mg of young wheat leaf tissue using the DNeasy Plant Mini Kit (Qiagen, Hilden, Germany) according to the manufacturer's instructions. Primers and PCR conditions Amplification of the Pina and Pinb puroindoline genes was performed using sequence-specific primers Pina-D1-F, Pina-D1-R, Pinb-D1-F, Pinb-D1-R, Pinb-glyR and Pinb-serR (Gautier et al. 1994; Giroux & Morris 1997; Tranquilli et al. 1999). The sequences for forward (F) and reverse (R) primers were as follows: Pina-D1-F: 5-CCC TGT AGA GAC AAA GCT AA-3 Pina-D1-R: 5-TCA CCA GTA ATA GCC AAT AGT G-3 Pinb-D1-F: 5-ATG AAG ACC TTA TTC CTC CTA-3 Pinb-D1-R: 5-TCA CCA GTA ATA GCC ACT AGG GAA-3 Pinb-glyR: 5-CTC ATG CTC ACA GCC GCC-3 Pinb-serR: 5-CTC ATG CTC ACA GCC GCT-3 The polymerase chain reactions (PCRs) were performed in a final reaction volume of 15 µl using 25 ng of genomic DNA, 1 × PCR buffer, 1.5 mM MgCl 2, 0.2 mM dNTP, 0.2 M of each forward and reverse primers and 0.8 U of Taq DNA polymerase (Invitrogen). The amplification conditions for Pina included initial denaturation at 94°C for 3 min, followed by 37 cycles at 94°C for 90 s, at 55°C for 90 s, at 72°C for 2 min and final extension at 72°C for 10 min. To amplify Pinb, annealing temperature was raised up to 58°C. PCRs were conducted using PTC-200 thermal cycler (MJ Research Inc., Waltham). Amplified PCR products were analysed on 1.4% agarose gels, stained with ethidium bromide. Amplification is observed only for the wild-type Pina-D1a, yielding 330 bp fragment; null allele Pina-D1b amplifies no band. After amplification of a 447-bp segment of the Pinb-D1 gene using primers designed by Gautier et al. (1994), the PCR product was digested by the restriction endonuclease BsrBI. The enzyme recognises the sequence with the glycine serine mutation but not the sequence without the mutation. After digestion, fragments of 320 bp are expected for genotypes lacking the mutation (normal allele), whilst fragments of 200 bp are expected for genotypes carrying the null allele for hard texture (Tranquilli et al. 1999). For differen90 tiation of normal Pinb-D1a from null Pinb-D1b allele, primers Pinb-glyR/Pinb-serR and PinbD1-F were used (Gautier et al. 1994). Grain parameters assessment In triplicate, 36 grains of two genetically related pairs of old wheat cultivars Slovenská B and Slovenská 777 (Slovenská B line II and Slovenská B line III as well as Slovenská 777 line I and Slovenská 777 line V) were examined for grain dimensions and 24 grains for colour. Digital image analysis (images were obtained with scanner HP Scanjet 4370, Hewlet Packard) was used to measure grain length and width (Tahir et al. 2007) as well as red, green and blue (RGB) colour components. The methods of measurement were similar as described by Taska et al. (2005). Dimension parameters were measured in the Microsoft photo editor 3. To determine the grain colour histograms of RGB component, the Assess Image Analysis Software for Plant Disease Quantification were used (Lamari 2002). Statistical methods Standard statistical testing including analysis of variance (ANOVA), general linear model, Bonferroni test and Tukey's HSD test (statistical software package SPSS® 11.5) was used for data evaluation. The value P < 0.05 was considered statistically significant. RESULTS AND DISCUSSION All 124 evaluated wheat cultivars belong to following alleles of the Pina and Pinb genes (Table 1): normal Pina-D1a and Pinb-D1a and null Pina-D1b and Pinb-D1b alleles. Concerning the Pina gene, null allele Pina-D1b, which is associated with harder texture than Pinb-D1b mutation (Morris & Massa 2003), was found only in Rheia current cultivar. Other current cultivars, as well as old cultivars, have wild-type Pina-D1a allele. Regarding the Pinb gene, frequencies of normal (wild-type) Pinb-D1a and null Pinb-D1b allele were 62.0% and 38.0%, respectively, in current cultivars, whilst 8.3% and 91.7%, respectively, in historical ones. Recessive null PinbD1b allele was found mostly in cultivars with good bread-making quality (Alacris, Alana, Axis, Balada, Blava, Bona Dea, Bruta, Charger, Hana, Ilona, IS Karpatia, Ludwig, and Sulamit). Surprisingly, almost all (22 from 24) old superior cultivars were homozygous for recessive null Pinb-D1b allele. The null Pinb-D1b allele was detected in Slovenská 777 (I­IV), Stupická Bastard (I­V), Kastická bezosinatá (I­III), Radosinská Dorada (I­V), Slovenská 200 I, Slovenská B (I and II) and Bucianska cervenoklasá (I and II) cultivars. Because all varieties had normal (Pina-D1a and Pinb-D1a) or the most frequent null allele (Pina-D1b and Pinb-D1b) of both puroindoline genes, we did not look for other sporadically occurring null alleles. Three different genotypes of puroindoline genes were found: 1) normal allele of both genes, Pina-D1a/Pinb-D1a (dominant wild type with soft grain); 2) normal allele of the Pina gene and null allele of the Pinb gene, Pina-D1a/Pinb-D1b (moderately hard grain); and 3) null allele of the Pina gene and normal allele of the Pinb gene, Pina-D1b/ Pinb-D1a (very hard grain). Neither in the current nor in the old Slovak wheat cultivars we detected simultaneous presence of null alleles of Pina and Pinb genes. Dominant wild type with soft grain was achieved in 61.0% of current cultivars and in only 8.3% of old wheat cultivars (Table 2). The genotype Pinb-D1b was detected in 38.0% of current and 91.7% of old superior cultivars. Whilst in old cultivars, the Pina-D1a/Pinb-D1b genotype with moderately hard grain dominated, in current cultivars, the dominant wild-type Pina-D1a/Pinb-D1a with soft grain associated with poorer wheat quality was more frequent. This fact points to forgetting of grain hardness importance in breeding for other wheat qualitative traits. Our results provide the possibility of Slovak wheat cultivars breeding for hardness improvement. Obtained results from cultivars of the Slovak origin are in agreement with observations of other authors who also found the Pinb-D1b mutation as prevalent amongst a wide set of both recent and historical wheat cultivars of different origin (Giroux & Morris 1997). The null allele has a glycine serine substitution at position 46 in the puroindoline Pinb gene (Giroux & Morris 1997). The Pinb-D1b allele was first characterised in the `Chinese Spring' T a b l e 1 The frequency of homozygous alleles in winter wheat cultivars Pina gene Cultivars (number) Current registered (100) Old (24) Normal allele Pina-D1a [%] 99.0 100.0 Null allele Pina-D1b [%] 1.0 0.0 Normal allele Pinb-D1a [%] 62.0 8.3 Pinb gene Null allele Pinb-D1b [%] 38.0 91.7 T a b l e 2 The frequency of homozygous genotypes in winter wheat cultivars Puroindoline genotype Pina-D1a/Pinb-D1a Pina-D1b/Pinb-D1a Pina-D1a/Pinb-D1b Pina-D1b/Pinb-D1b Current cultivars [%] 61.0 1.0 38.0 0.0 Old cultivars [%] 8.3 0.0 91.7 0.0 Pina ­ Puroindoline-a gene; Pinb ­ Puroindoline-b gene substitution line possessing the 5D chromosomes of `Cheyenne'. Giroux & Morris (1997) discovered that the hardness mutation is a single base change (GGCAGC) in the codon of Gly-46, converting glycine to serine. The mutation is highly conserved and might explain the most of phenotypically hard hexaploid wheats. Lillemo and Morris (2000) showed that the prevalence of mutation might be largely related to the gene pools of interest and also the particular area of origin. Genotypes with Pinb-D1b possess significantly lower flour ash content and higher milling yield than those of genotypes with Pina-D1b. For steamed bread, mean scores for loaf volume, crumb colour, width and structure and total score of Pinb-D1b genotypes were significantly higher than those of genotypes with Pina-D1b and wild-type Pinb-D1a (Chen et al. 2007). Two old Slovak wheat cultivars, Slovenská B and Slovenská 777, had different alleles of the Pinb gene (Slovenská B line III had normal allele and Slovenská B line II the null allele, Slovenská 777 line V had normal and Slovenská 777 line I had the null allele). Therefore, we focused on comparing the width, length and RGB colour components in relation to the presence of the null and normal allele of Pinb-D1b gene in these genetically related lines of cultivars Slovenská B and Slovenská 777. Concerning Pinb gene, significant influence on grain length, grain length-to-width ratio, width-tolength ratio and grain colour components red, green and blue in RGB colour model was found (Table T a b l e 3 Mean squares from ANOVA for wheat grain size and grain colour components to alleles of the Pinb gene Variability of the Pinb gene Grain dimensions Between groups Length Within groups Total Between groups Width Within groups Total Between groups Length/width Within groups Total Between groups Width/length Within groups Total Grain colour components Between groups Red Within groups Total Between groups Green Within groups Total Between groups Blue Within groups NS df 1 46 47 1 46 47 1 46 47 1 46 47 1 142 143 1 142 143 1 142 143 not significant Mean squares 8,576.053+ 1,257.283 1,313.985NS 809.291 0.373 0.043 0.018 0.002 18,292.563 303.642 18,225.000 235.359 33,580.562 282.534 Total Significant at the 0.01 level; + significant at the 0.05 level; 3). From Table 4, the rounder kernel in cultivars having null allele of the Pinb gene is evident. The mean values of grain length and width were 623 and 288 pixels for normal allele Pinb-D1a and 596 and 299 pixels for null allele Pinb-D1b, respectively. In comparison with normal allele Pinb-D1a, the cultivars with the null allele Pinb-D1b have significantly shorter kernel (P < 0.05) and lower length-to-width ratio (P < 0.01). Using digital image analysis, significant differences in wheat grain size and colour were ascertained. Grain size influences milling quality of wheat (Marshall et al. 1986). Sizes together with density determine grain weight, which has a favourable effect on agronomic and flour yield of wheat (Dziki & Laskowski 2005). Quantitative trait loci (QTL) for grain length and width in bread wheat were found on various chromosomes (Dholakia et al. 2003; Breseghello & Sorrells 2007). From the low genetic correlation between grain length and width found, Bergman et al. (2000) deduced their independent inheritance. In addition, cultivars with the null allele PinbD1b have lighter grain colour. RGB colour components in cultivars with the null allele have significantly (P < 0.01) higher values as compared to cultivars with normal allele (Table 5). Mean squares from general linear model and coefficient of determination (R2) for length, width, length-to-width ratio, width-to-length ratio and colour components RGB indicate that the fitted model explains significant (P < 0.01) great deal of variability (Table 6). Dobraszczyk et al. (2002) indicated that grain hardness corresponds to endosperm density. Results of Konopka et al. (2005a) pointed to relationship between the endosperm colour and grain hardness in wheat cultivars. However, the authors found that environment causes variability of the protein content, hardness, vitreousness, length and size of grains, and all these can affect grains colour. T a b l e 4 Mean values of grain size in relation to the Pinb gene (the Bonferroni test) Grain dimensions Length Width Length/width Width/length Allele of the Pinb gene Normal Null Pinb-D1b Normal Null Pinb-D1b Normal Null Pinb-D1b Normal Null Pinb-D1b N 24 24 24 24 24 24 24 24 NS Mean 623.089 596.355 288.473 298.937 2.182 2.005 0.463 0.502 not significant Std. error 7.027 7.443 5.426 6.330 0.048 0.036 0.441 0.484 Difference 26.733+ 10.464NS 0.176 0.039 Significant at the 0.01 level; + significant at the 0.05 level; T a b l e 5 The effect of alleles on RGB colour components in relation to the Pinb gene (Tukey's HSD test) Cultivar Slovenská B III Slovenská 777 V Slovenská 777 I Slovenská B II Allele of Pinb gene Normal Normal Null Pinb-D1b Null Pinb-D1b N 36 36 36 36 Red (R) 187.86 200.50 218.03 a a Green (G) 139.58 148.89 167.08 a a Blue (B) 50.53a 52.39a 78.72b 85.28b 215.42b 166.39b Different letter (a, b) indicate statistically significant differences (P 0.01) CONCLUSIONS Wheat marketing system established the primary classification of hexaploid wheat based on the endosperm texture. The grain hardness is one of the most important traits and affects a range of parameters including the milling, baking and end-use properties of wheat. The aim of our work was to evaluate the grain hardness of 100 current and 24 old superior Slovak winter wheat cultivars at molecular level and determine its relation to grain size and colour. Normal (wild-type) and null alleles of both puroindoline Pina and Pinb genes were identified using PCRs. In conclusion, no one of cultivars tested had together null allele of both Pin genes. Only one null Pina allele was identified in Slovak winter wheat cultivars. Null allele Pinb-D1b (`loss of function' mutation resulting from the replacement of glycine by serine T a b l e 6 Mean squares from general linear model and coefficient of determination (R2) for length, width, length/width, width/length, and colour component red, green, blue in relation to the Pinb gene Source Model Length Pinb Error Total Model Width Pinb Error Total Model Length/Width Pinb Error Total Model Width/Length Pinb Error Total Model Red Pinb Error Total Model Green Pinb Error Total Model Blue Pinb Error df Grain dimensions 2 2 46 48 2 2 46 48 2 2 46 48 2 2 46 48 Colour components 2 2 142 144 2 2 142 144 2 2 142 144 3,048,285.951 3,048,285.951 303.642 Mean square 8,926,552.480 8,926,552.480 1,257,283.000 R2 0.997 2,070,960.041 2,070,960.041 809.291 105.376 105.376 0.043 5.592 0.002 1,749,779.514 1,749,779.514 235.359 337,390.562 337,390.562 282.534 Total Significant at the 0.01 level at position 46), which is prevalent amongst most of the European countries, was detected in 38.0% of current and 91.7% of old superior cultivars. Its incidence was higher in old superior in comparison with current cultivars. Statistically significant correlations between null Pinb-D1b allele and grain size as well as colour were found. The cultivars with the null allele Pinb-D1b have significantly shorter kernel, lower length-to-width ratio and lighter grain colour. We selected cultivars that would be helpful in molecular breeding programme as donors of the null allele in order to manipulate grain hardness as one of the main quality traits of winter wheat. Acknowledgements. Supported by the Ministry of Agriculture and Rural Development of the Slovak Republic, Project GENETIMPRO. Authors thank Mrs. Jela Klcová for her excellent technical assistance. and biochemical characterization pf puroindoline-a and b alleles in Chinese landraces and historical cultivars. In Theoretical and Applied Genetics, vol. 112, pp. 400­ 409. DOI: 10.1007/s00122-005-0095-z. 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