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The Importance of Wheat

  • Gilberto IgrejasEmail author
  • Gérard Branlard
Chapter
  • 35 Downloads

Abstract

The history of wheat domestication and use is closely linked to the efforts of humans to protect themselves from hunger and gain control over their food supply. Now grown worldwide wheat has become the most important source of food. For centuries bread wheat (Triticum aestivum) and durum wheat (Triticum durum) have been cultivated in the West to provide humans with energy and essential nutrients. Today China and India are the top two wheat-producing countries, largely because wheat has the advantage of requiring less water for cultivation than other comparable crops while being the main ingredient of a variety of processed foods valued in modern, mainly urban life. For more than a century, breeders have continuously improved wheat focusing on factors affecting grain yield and, more recently, technological quality. The properties of wheat that are ideal for processing into different food products have been greatly improved since the 1960s thanks to detailed research on storage proteins, which constitute the gluten. Most of these genetic successes are referred to in this book but many important goals remain to be achieved. Today further progress is crucial in the use of shared genetic resources, common analytical protocols for allele identification and technological processing, and dedicated tools for analysing polymer formation and characterisation particularly in response to climatic and other environmental factors. Technological properties are not the only wheat quality attributes, as consumers are increasingly aware and concerned about the nutritional value (the content in fiber, minerals, macro- and micro-nutrients, vitamins) and the health impact, whether positive or negative. For example, research on several pathologies associated with the consumption of gluten-based products will require collaboration between allergy specialists and wheat protein geneticists.

Keywords

Wheat dissemination World production Gluten Industrial uses Some questions 

References

  1. Alessio F, Sapone A, Zevallos V, Schuppan D (2015). Nonceliac gluten sensitivity, Gastroenterology 148: 1195–1204.CrossRefGoogle Scholar
  2. Bailey C 1941 A translation of Beccari’s lecture ‘Concerning Grain’ (1728). Cereal Chem 18:555–561.Google Scholar
  3. Biesiekierski JR (2017) What is gluten? J Gastroenterol Hepatol 32:78–81.CrossRefGoogle Scholar
  4. Bonjean AP (2016). The saga of wheat the successful story of wheat and human interaction. The world wheat book: A history of wheat breeding, volume 3,” Alain P. Bonjean, William J. Angus, Maarten Van Ginkel eds. Edition Lavoisier Tec&Doc, ISBN 978-2-7430-2091-0, pp. 1672, Chapter 1, 1–90.Google Scholar
  5. Bonjean AP, Angus WJ, van Ginkel M (2011). The world wheat book volume 2. A history of wheat breeding (Bonjean AP, Angus WJ, van Ginkel M eds) Lavoisier Publishing. ISBN: 978-2-7430-1102-4, pp. 1201.Google Scholar
  6. Branlard G, Chiron H (2016). History and milestones of wheat processing and end-uses around the world (East Asia excepted): past, present and prospectives. In: “The world wheat book: a history of wheat breeding, volume 3,” Alain P. Bonjean, William J. Angus, Maarten Van Ginkel eds. Edition Lavoisier Tec&Doc, ISBN 978-2-7430-2091-0, pp. 1672, Chapter 42, 1297–1343.Google Scholar
  7. Branlard G, Faye A, Méléard B, Le Gouis J, Oury F-X, Ravel C (2019a). Quelle hypothèse approfondir pour appréhender la sensibilité non céliaque au gluten: 1. L’abondance du gluten et la diversité des prolamines Industries des Céréales 211: 34–37.Google Scholar
  8. Branlard G, Rhazi L, Méléard B, Le Gouis J, Ravel C (2019b). Quelle hypothèse approfondir pour appréhender la sensibilité non céliaque au gluten: 2. Les polymères des gluténines. Industries des Céréales 212: 26–29.Google Scholar
  9. Braudel F (1985). Civilisation matérielle, économie et capitalisme XV, XVIII siècles,1. Les structures du quotidien. Poche Editions. Bruneton – Governatori, 1984. Le pain de bois, ethnohistoire de la châtaigne et du châtaignier; Eché Editions. pp. 547.Google Scholar
  10. Bruyérin C (1560). De re Cibaria, L’alimentation de tous les peuples et de tous les temps jusqu’au XVI siècle. Traduit du latin par Sigurd Amundsen, 1998. Editions Intermédiaire des Chercheurs et curieux. pp. 666.Google Scholar
  11. Bushuk W, Rasper VF (Eds.) (1994). Wheat. Production, properties and quality. Springer: Blackie/Chapman and Hall, London, 239 pp.Google Scholar
  12. FAO (2018). World food and agriculture – Statistical pocketbook 2018. Rome. 254 pp.Google Scholar
  13. FAOSTAT (2014). Food and agriculture organization of the United Nations. Statistics Division, Crops data. http://faostat3.fao.org/download/Q/QC/E
  14. Flandrin JL, Montanari M (1996). Histoire de l’alimentation. Fayard Editions, Paris. 392–426.Google Scholar
  15. Igbinedion SO, Ansari J, Vasikaran A, Gavins FN, Jordan P, Boktor M, Alexander JS (2017) Non-celiac gluten sensitivity: all wheat attack is not celiac. World J Gastroenterol. 23(40): 7201–7210.CrossRefGoogle Scholar
  16. Johansson E, Malik AH, Hussain A, Rasheed F, Newson WR, Plivelic T,. Hedenqvist MS, Gällstedt M, Kuktaite R (2013). Wheat gluten polymer structures: the impact of genotype, environment, and processing on their functionality in various applications. Cereal Chem 90: 367–376.CrossRefGoogle Scholar
  17. Laurière M, Pecquet C, Boulenc E, Bouchez-Mahiout I, Snégaroff J, Choudat D, Raison-Peyron N, Vigan M, Branlard G (2007). Genetic differences in omega-gliadins involved in two different immediate food hypersensitivities to wheat. Allergy, 62. 890–896.CrossRefGoogle Scholar
  18. Osborne TB (1907) The proteins of the wheat kernel, by Thomas B. Osborne, Washington, Carnegie Inst.Google Scholar
  19. Peña-Bautista RJ, Hernandez-Espinosa N, Jones JM, Guzmán C, Braun, HJ (2017). CIMMYT Series on carbohydrates, wheat, grains, and health: wheat-based foods: their global and regional importance in the food supply, nutrition, and health. Cereal Foods World 62(5): 231–249.CrossRefGoogle Scholar
  20. Pomeranz Y (1971). Wheat chemistry and technology. Published by AACC. 1–2.Google Scholar
  21. Saulnier L, Sado P-E, Branlard G, Charmet G, Guillon F (2007). Wheat arabinoxylans: Exploiting variation in amount and composition to develop enhanced varieties. J Cereal Sci. The Contribution of Cereals to a Healthy Diet, 46: 261–281.Google Scholar
  22. Shewry PR, Hey SJ (2015). The contribution of wheat to human diet and health. Food Energy Secur 4(3): 178–202.CrossRefGoogle Scholar
  23. Shewry PR, Charmet G, Branlard G, Lafiandra D, Gergely S, SalgóA, Saulnier L, Bedő Z, Mills C, Ward JL (2012). Developing new types of wheat with enhanced health benefits. Trends Food Sci Technol 25: 70–77.CrossRefGoogle Scholar
  24. Wang Z, Li Y, Yang Y, Liu X, Qin H, Dong Z, Wang D (2017). New insight into the function of wheat glutenin proteins as investigated with two series of genetic mutants. Sci Rep 7(1): 3428.CrossRefGoogle Scholar
  25. Weiss E, Zohary D, 2011 The neolithic Southwest Asian founder crops: their biology and archaeobotany. Curr Anthropol, 52(S4): S239-S240.CrossRefGoogle Scholar
  26. Zevallos VF, Raker V, Tenzer S, Jimenez-Calvente C, Ashfaq-Khan M, Rüssel N, Pickert G, Schild H, Steinbrink K, Schuppan D (2017). Nutritional wheat amylase-trypsin inhibitors promote intestinal inflammation via activation of Myeloid cells. Gastroenterology 152(5): 1100–1113.CrossRefGoogle Scholar

Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  1. 1.Department of Genetics and BiotechnologyUniversity of Trás-os-Montes and Alto DouroVila RealPortugal
  2. 2.Functional Genomics and Proteomics UnitUniversity of Trás-os-Montes and Alto DouroVila RealPortugal
  3. 3.LAQV-REQUIMTE, Faculty of Science and TechnologyNova University of LisbonLisbonPortugal
  4. 4.INRAE, UCA UMR1095 GDECClermont-FerrandFrance

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