Abstract
The quality of wheat products has been a new challenge next to wheat production which was achieved substantially during green revolution. The end-use quality of wheat is an essential factor for its commercial demand. The quality of wheat is largely based on the wheat storage proteins which extensively influences the dough properties. High molecular weight glutenin subunits (HMWGS), low molecular weight glutenin subunits (LMWGS) and gliadins significantly influence the end-use quality. Genomics and proteomics study of these gluten proteins of bread and durum wheat have explored new avenues for precise identification of the alleles and their role in end-use quality improvement. Secalin protein of Secale cereale encoded by Sec-1 loci and is associated with 1RS.1BL translocation has been known for deterioration of end-use quality. Chromosomal manipulations using various approaches have led to the development of new recombinant lines of wheat without secalin. Advanced techniques associated with assessment of end-use quality have integrated the knowledge of useful or deteriorating HMWGS/LMWGS alleles and their potential role in end-use quality. This review gives a comprehensive insight of different aspects of the end-use quality perspective for bread making in wheat along with some information on the immunological interference of gluten in celiac disease.
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References
Ammar K, Mergoum M, Rajaram S (2004) The history and evolution of triticale. Triticale improvement and production (No.CIS-4898.CIMMYT)
Amri A, Boujnah M, Nsarellah N, Taghouti M, Nachit MM (2000) Genetic and agronomic approaches to improve durum wheat quality in Morocco. In: Nachit MM, Fonzo N, Araus JL (eds) Durum wheat improvement in the Mediterranean region: new challenges. CIHEAM-IAMZ, Zaragoza, pp 543–547
Anderson OD, Cassidy B, Steffen J, Dvorak J, Greene FC (1991) Structure of the high- and low-molecular-weight gene families of the homeologous group 1 chromosomes of the hexaploid bread wheat cultivar Cheyenne. In: Bushuk W, Tkachuk R (eds) Gluten proteins. AACC, St. Paul, pp 512–519
Austin A, Ram A (1971) Studies on chapati making quality of wheat. Rajendra Printers, New Delhi, pp 1–108
Ayalew H, Kumssa TT, Butler TJ, Ma XF (2018) Triticale improvement for forage and cover crop uses in the Southern Great Plains of the United States. Front Plant Sci 9:1130. https://doi.org/10.3389/fpls.2018.01130
Bakshi S, Bhagwat SG (2016) High molecular weight glutenin subunit variation among Indian wheat varieties. J Agric Sci 6(11):349–355
Bangur R, Batey IL, McKenzie E, MacRitchie F (1997) Dependence of extensiograph parameters on wheat protein composition measured by SE-HPLC. J Cereal Sci 25(3):237–241
Barak S, Mudgil D, Khatkar BS (2013) Relationship of gliadin and glutenin proteins with dough rheology, flour pasting and bread making performance of wheat varieties. LWT-Food Sci Technol 51(1):211–217
Barak S, Mudgil D, Khatkar BS (2015) Biochemical and functional properties of wheat gliadins: a review. Food Sci Nutr 55(3):357–368
Boehm JD, Ibba MI, Kiszonas AM, Morris CF (2017) End-use quality of CIMMYT-derived soft-kernel durum wheat germplasm: II. Dough strength and pan bread quality. Crop Sci 57(3):1485–94
Branković G, Dodig D, Pajić V, Kandić V, Knežević D, Đurić N, Živanović T (2018) Genetic parameters of Triticum aestivum and Triticum durum for technological quality properties in Serbia. Zemdirbyste-Agriculture 105(1):39–48
Caballero PA, Gómez M, Rosell CM (2007) Bread quality and dough rheology of enzyme-supplemented wheat flour. Eur Food Res Technol 224(5):525–534
Cakmak I, Pfeiffer WH, McClafferty B (2010) Biofortification of durum wheat with zinc and iron. Cereal Chem 87(1):10–20
Chňapek M, Peroutková R, Vivodík M, Gálová Z (2015) Identification of technologically important genes and their products in the collection of bread wheat genotypes. J Microbiol Biotechnol Food Sci 04 (Special issue 02):26–29
Cho SW, Roy SK, Chun JB, Cho K, Park CS (2017) Overexpression of the Bx7 high molecular weight glutenin subunit on the Glu-B1 locus in a Korean wheat landraces. Plant Biotechnol Rep 11:97–105
D’Ovidio R, Masci S (2004) The low-molecular-weight glutenin subunits of wheat gluten. J Cereal Sci 39:321–339
Delcour JA, Hoseney RC (2010) Principles of cereal science and technology. AACC Internatioanl, St. Paul
Delcour JA, Joye IJ, Pareyt B, Wilderjans E, Brijs K, Lagrain B (2012) Wheat gluten functionality as a quality determinant in cereal-based food products. Ann Rev Food Sci Technol 3:469–492
Dhaka V, Khatkar BS (2015) Effects of gliadin/glutenin and HMW-GS/LMW-GS ratio on dough rheological properties and bread making potential of wheat varieties. J Food Qual 38(2):71–82
Dowell FE, Maghirang EB, Xie F, Lookhart GL, Pierce RO, Seabourn BW, Bean SR, Wilson JD, Chung OK (2006) Predicting wheat quality characteristics and functionality using near-infrared spectroscopy. Cereal Chem 83(5):529–536
Filip E (2018) Composition of high molecular weight glutenin subunits in polish common wheat cultivars (Triticum aestivum L.). J Food Quality. https://doi.org/10.1155/2018/2473420
Fleitas MC, Schierenbeck M, Gerard GS, Dietz JI, Golik SI, Campos PE, Simón MR (2018) How leaf rust disease and its control with fungicides affect dough properties, gluten quality and loaf volume under different N rates in wheat. J Cereal Sci 80:119–127
Frakolaki G, Giannou V, Topakas E, Tzia C (2018) Chemical characterization and breadmaking potential of spelt versus wheat flour. J Cer Sci 79:50–56
Freund W, Kim MY (2006) Determining the baking quality of wheat and rye flour. pdfs.semanticscholar.org
Gálová Z, Michalik I, Knoblochova H, Gregova E (2002) Variation in HMW glutenin subunits of different species of wheat. Rostlinna Vyroba 48(2):15–19
Garg M, Dhaliwal HS, Chhuneja P, Kumar D, Dou QW, Elamein HMM, Tanaka H, Tsujimoto H (2007) Negative effect of chromosome 1A on dough strength shown by modification of 1D addition in durum wheat (Triticum durum). Theor Appl Genet 114:1141–1150
Garg M, Tanaka H, Ishikawa N, Takata K, Yanaka M, Tsujimoto H (2009) Agropyron elongatum HMW-glutenins have a potential to improve wheat end-product quality through targeted chromosome introgression. J Cereal Sci 50:358–363
Gellrich C, Schieberle P, Wieser H (2003) Biochemical characterization and quantification of the storage protein (secalin) types in rye flour. Cereal Chem 80:102–109
Gianibelli MC, Larroque OR, MacRitchie F, Wrigley CW (2001) Biochemical, genetic, and molecular characterization of wheat glutenin and its component subunits. Cereal Chem 78(6):635–646
Gianibelli MC, Echaide M, Larroque OR, Carrillo JM, Dubcovsky J (2002) Biochemical and molecular characterisation of Glu-1 loci in Argentinean wheat cultivars. Euphytica 128(1):61–73
Giraldo P, Rodriguez-Quijano M, Simon C, Vázquez JF, Carrillo JM (2010) Allelic variation in HMW glutenins in Spanish wheat landraces and their relationship with bread quality. Span J Agric Res 8(4):1012–1023
Gómez M, Ronda F, Blanco CA, Caballero PA, Apesteguía A (2003) Effect of dietary fibre on dough rheology and bread quality. Eur Food Res Technol 216(1):51–56
Graybosch RA (2001) Mini review: uneasy unions: quality effects of rye chromatin transfers to wheat. J Cereal Sci 33(1):3–16
Guo X, Sun X, Zhang Y, Wang R, Yan X (2018) Interactions between soy protein hydrolyzates and wheat proteins in noodle making dough. Food Chem 245:500–507
Hadnađev M, DapčevićHadnadev T, Šimurina O, Filipčev B (2013) Empirical and fundamental rheological properties of wheat flour dough as affected by different climatic conditions. J Agric Sci Technol 15:1381–1391
Howell T, Hale I, Jankuloski L, Bonafede M, Gilbert M, Dubcovsky J (2014) Mapping a region within the 1RS.1BL translocation in common wheat affecting grain yield and canopy water status. Theoret Appl Genet 127(12):2695–2709
Hrušková M, Švec I, Jirsa O (2006) Correlation between milling and baking parameters of wheat varieties. J Food Eng 77(3):439–444
Ito M, Maruyama-Funatsuki W, Ikeda TM, Nishio Z, Nagasawa K, Tabiki T (2015) Dough properties and bread-making quality-related characteristics of Yumechikara near-isogenic wheat lines carrying different Glu-B3 alleles. Breed Sci 65(3):241–248
Janni M, Cadonici S, Pignone D, Marmiroli N (2017) Survey and new insights in the application of PCR-based molecular markers for identification of HMW-GS at the Glu-B1 locus in durum and bread wheat. Plant Breed 136(4):467–473
Kaur A, Shevkani K, Katyal M, Singh N, Ahlawat AK, Singh AM (2016) Physicochemical and rheological properties of starch and flour from different durum wheat varieties and their relationships with noodle quality. J Food Sci Technol 4:2127–2138
Kaur A, Bains NS, Sood A, Yadav B, Sharma P, Kaur S, Garg M, Midha V, Chhuneja P (2017) Molecular characterization of α-gliadin gene sequences in Indian wheat cultivars vis-à-vis celiac disease eliciting epitopes. J Plant Biochem Biotechnol 26(1):106–112
Khalid KH, Ohm JB, Simsek S (2017) Whole wheat bread: effect of bran fractions on dough and end-product quality. J Cereal Sci 78:48–56
Khatkar BS, Bell AE, Schofield JD (1996) A comparative study of the inter-relationships between mixograph parameters and bread-making qualities of wheat flours and glutens. J Sci Food Agri 72(1):71–85
Khoury DE, Ducharme BS, Joye IJ (2018) A review on the gluten-free diet: technological and nutritional challenges. Nutrients 10(10):1410
Kiszonas AM, Morris CF (2018) Wheat breeding for quality: a historical review. Cereal Chem 95(1):17–34
Kumar S, Sohu VS, Gupta SK, Singh RP, Bains NS (2018) Understanding the chapatti making attributes of Indian wheats. I: The physico-chemical basis. J Appl Nat Sci 10(2):572–592
Lebwohl B, Blaser MJ, Ludvigsson JF, Green PH, Rundle A, Sonnenberg A, Genta RM (2013) Decreased risk of celiac disease in patients with Helicobacter pylori colonization. Am J Epidemiol 178(12):1721–1730
Lei ZS, Gale KR, He ZH, Gianibelli C, Larroque O, Xia XC, Butow BJ, Ma W (2006) Y-type gene specific markers for enhanced discrimination of high-molecular weight glutenin alleles at the Glu-B1 locus in hexaploid wheat. J Cereal Sci 43(1):94–101
Lerner SE, Seghezzo ML, Molfese ER, Ponzio NR, Cogliatti M, Rogers WJ (2006) N-and S-fertiliser effects on grain composition, industrial quality and end-use in durum wheat. J Cereal Sci 44(1):2–11
Lew EJL, Kuzmicky DD, Kasarda DD (1992) Characterization of low molecular weight glutenin subunits by reversed-phase high performance liquid chromatography, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and N-terminal amino acid sequencing. Cereal Chem 69:508–515
Liu E, Lee HS, Aronsson CA, Hagopian WA, Koletzko S, Rewers MJ, Eisenbarth GS, Bingley PJ, Bonifacio E, Simell V, Agardh D (2014) Risk of pediatric celiac disease according to HLA haplotype and country. New Engl J Med 371(1):42–49
Lombardo LA, Nisi MM, Salines N, Ghione CE, Helguera M (2017) Identification of novel high molecular weight glutenin subunit mutants in bread wheat (Triticum aestivum L.). Cytogenet Cell Genet 51(4):305–314
Ludvigsson JF, Ludvigsson J, Ekbom A, Montgomery SM (2006) Celiac disease and risk of subsequent type 1 diabetes: a general population cohort study of children and adolescents. Diabetes Care 29:2483–2488
Lukaszewski AJ (2000) Manipulation of the 1RS.1BL translocation in wheat by induced homeologous recombination. Crop Sci 40(1):216–225
Lukaszewski AJ (2003) Registration of six germplasms of durum wheat with introgressions of the Glu-D1 locus. Crop Sci 43(3):1138
Lukow OM, Forsyth SA, Payne PI (1992) Over-production of HMW [High Molecular Weight] glutenin subunits coded on chromosome 1B in common wheat-Triticum aestivum. J Genet Breed 46:187–192
Macharia GK, Peña RJ, Simsek S, Anderson JA (2014) Variation at glutenin subunit loci, single kernel characterization and evaluation of grain protein in East African bread wheat varieties. Euphytica 197(3):409–421
Masure HG, Fierens E, Delcour JA (2016) Current and forward looking experimental approaches in gluten-free bread making research. J Cereal Sci 67:92–111
Mergoum M, Singh PK, Pena RJ, Lozano-del Río AJ, Cooper KV, Salmon DF, Macpherson HG (2009) Triticale: a “new” crop with old challenges. In: Carena M (ed) Cereals. Springer, Berlin, pp 267–287
Merlino M, Leroy P, Chambon C, Branlard G (2009) Mapping and proteomic analysis of albumin and globulin proteins in hexaploid wheat kernels (Triticum aestivum L.). Theor Appl Genet 18:1321–1337
Morris CF, Casper J, Kiszonas AM, Fuerst EP, Murray J, Simeone MC, Lafiandra D (2015) Soft kernel durum wheat—a new bakery ingredient? Cereal Foods World 60:76–83. https://doi.org/10.1094/CFW-60-2-0076
Mutlu AC, Boyaci IH, Genis HE, Ozturk R, Basaran-Akgul N, Sanal T, Evlice AK (2011) Prediction of wheat quality parameters using near-infrared spectroscopy and artificial neural networks. Eur Food Res Technol 233(2):267–274
Nakamura H (2000) Allelic variation at high-molecular-weight glutenin subunit Loci, Glu-A1, Glu-B1 and Glu-D1, in Japanese and Chinese hexaploid wheats. Euphytica 112(2):187
Nazco R, Villegas D, Ammar K, Pena RJ, Moragues M, Royo C (2012) Can Mediterranean durum wheat landraces contribute to improved grain quality attributes in modern cultivars? Euphytica 185(1):1–7
Nijhawan S, Goyal G (2015) Celiac disease review. J Gastrointest Dig Syst 5(6):350
Osman AM, Struik PC, van Bueren ETL (2012) Perspectives to breed for improved baking quality wheat varieties adapted to organic growing conditions. J Sci Food Agric 92(2):207–215
Pattison AL (2013) Genetic improvement of grain quality for bread making in triticale. https://ses.library.usyd.edu.au.
Payne PI (1987) Genetics of wheat storage proteins and the effect of allelic variation on bread-making quality. Annu Rev Plant Physiol 38(1):141–153
Peña RJ, Trethowan R, Pfeiffer WH, Ginkel MV (2002) Quality (end-use) improvement in wheat: compositional, genetic, and environmental factors. J Crop Prod 5(1–2):1–37
Pietzak M (2012) Celiac disease, wheat allergy, and gluten sensitivity: when gluten free is not a fad. J Parenter Enter Nutr 36(99):1_suppl–75S
Plenge RM (2010) Unlocking the pathogenesis of celiac disease. Nature Genet 42(4):281
Rasheed A, Mahmood T, Kazi AG, Ghafoor A, Mujeeb-Kazi A (2012) Allelic variation and composition of HMW-GS in advanced lines derived from D-genome synthetic hexaploid/bread wheat (Triticum aestivum L.). J Crop Sci 15(1):1–7
Roy N, Islam S, Ma J, Lu M, Torok K, Tomoskozi S, Bekes F, Lafiandra D, Appels R, Ma W (2018) Expressed Ay HMW glutenin subunit in Australian wheat cultivars indicates a positive effect on wheat quality. J Cereal Sci 79:494–500
Rozbicki J, Ceglińska A, Gozdowski D, Jakubczak M, Cacak-Pietrzak G, Mądry W, Golba J, Piechociński M, Sobczyński G, Studnicki M, Drzazga T (2015) Influence of the cultivar, environment and management on the grain yield and bread-making quality in winter wheat. J Cereal Sci 61:126–132
Rustgi S, Wettstein DV, Ankrah N, Brew-Appiah RAT, Wen N, Mitchell SM, Gemini R, Rei-senauer P (2015) Celiac-safe wheat genotypes: A dietary solution to the gluten-induced disorders. Ann Wheat Newslett 61:99–103
Sharma S, Ram S, Gupta R (2012) Relationship of high and low molecular weight glutenins with chemical and rheological properties of wheat flour. J Wheat Res 4(1):74–78
Sharma A, Sheikh I, Kumar R, Kumar K, Vyas P, Dhaliwal HS (2018) Evaluation of end-use quality and root traits in wheat cultivars associated with 1RS.1BL translocation. Euphytica 214(4):62
Sherman JD, Varella AC, Lanning SP, Martin JM, Heo HY, Nash D, Talbert LE (2018) Effect of a gene for high dough strength on whole wheat baking parameters of hard white spring wheat. Cereal Chem 95(3):411–417
Shewry PR, Halford NG, Tatham AS (1992) The high molecular weight subunits of wheat glutenin. J Cereal Sci 15:105–120
Shewry P, Gilbert S, Savage A, Tatham A, Wan YF, Belton P, Wellner N, D'ovidio R, Bekes F, Halford N (2003) Sequence and properties of HMW subunit 1Bx20 from pasta wheat (Triticum durum) which is associated with poor end use properties. Theor Appl Genet 106(4):744–750
Si H, Zhao M, He F, Ma C (2013) Effect of Glu-B3 allelic variation on sodium dodecyl sulfate sedimentation volume in common wheat (Triticum aestivum L.). Sci World J 9:99. https://doi.org/10.1155/2013/848549
Skylas DJ, Mackintosh JA, Cordwell SJ, Walsh BJ, Harry J, Blumenthal C, Copeland L, Wrigley CW, Rathmell WG (2000) Proteome approach to the characterisation of protein composition in the developing and mature wheat-grain endosperm. J Cereal Sci 52:169–188
Tanaka K, Yamauchi H, Nishio Z, Kuwabara T (2000) Effect of high molecular weight glutenin subunits on bread-making quality using near-isogenic lines. Breed Sci 50(4):303–308
Tatham AS, Drake AF, Shewry PR (1990) Conformational studies of synthetic peptides corresponding to the repetitive region of the high molecular weight (HMW) glutenin subunits of wheat. J Cereal Sci 11:189–200
Thomson NH, Miles MJ, Tatham AS, Shewry PR (1992) Molecular images of cereal proteins by STM. Ultramicroscopy 4244:1118–1122
Vader W, Kooy Y, van Veelen P, de Ru A, Harris D, Benckhuijsen W, Koning F (2002) The gluten response in children with celiac disease is directed toward multiple gliadin and glutenin peptides. Gastroenterology 122(7):1729–1737
Vojdani A (2015) Lectins, Agglutinins, and their roles in autoimmune reactivities. Altern Ther 21:42–47
Wrigley CW (2009) Wheat: a unique grain for the world. Romania 7:2–9
Yegin S, Altinel B, Tuluk K (2018) A novel extremophilic xylanase produced on wheat bran from Aureobasidium pullulans NRRL Y-2311-1: effects on dough rheology and bread quality. Food Hydrocoll 81:389–397
Yu Z, Peng Y, Islam MS, She M, Lu M, Lafiandra D, Roy N, Juhasz A, Yan G, Ma W (2019) Molecular characterization and phylogenetic analysis of active y-type high molecular weight glutenin subunit genes at Glu-A1 locus in wheat. J Cereal Sci. https://doi.org/10.1016/j.jcs.2019.01.003
Zannini E, Jones JM, Renzetti S, Arendt EK (2012) Functional replacements for gluten. Ann Rev Food Sci Technol 3:227–245
Zarkti H, Ouabbou H, Udupa SM, Gaboun F, Hilali A (2012) Agro-morphological variability in durum wheat landraces of Morocco. Aus J Crop Sci 7:1172
Zhang X, Liu D, Yang W, Liu K, Sun J, Guo X, Li Y, Wang D, Ling H, Zhang A (2011) Development of a new marker system for identifying the complex members of the low-molecular-weight glutenin subunit gene family in bread wheat (Triticum aestivum L.). Theor Appl Genet 122(8):1503–16
Žilić S, Barać M, Pešić M, Hadži-Tašković-Šukalović V, Dodiga D, Mladenović-Drinić S, Janković M (2011) Genetic variability of albumin-globulin content, and lipoxygenase, peroxidase activities among bread and durum wheat genotypes. Genetika 43(3):503–516
Acknowledgements
The authors acknowledge Department of Biotechnology, Government of India (BT/PR10886/AGII/106/934/2014) for providing financial support. The authors also acknowledge Akal College of Agriculture, Eternal University for arranging required infrastructure and research amenities.
Conflict of interest The authors declare no conflict of interest for this work.
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Sharma, A., Garg, S., Sheikh, I. et al. Effect of wheat grain protein composition on end-use quality. J Food Sci Technol 57, 2771–2785 (2020). https://doi.org/10.1007/s13197-019-04222-6
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DOI: https://doi.org/10.1007/s13197-019-04222-6