Improving wheat to remove coeliac epitopes but retain functionality
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[1] Huw D Jones,et al. Regulatory uncertainty over genome editing , 2015, Nature Plants.
[2] P. Maness,et al. The plasticity of cyanobacterial metabolism supports direct CO2 conversion to ethylene , 2015, Nature Plants.
[3] B. Seabourn,et al. Silencing of omega-5 gliadins in transgenic wheat eliminates a major source of environmental variability and improves dough mixing properties of flour , 2014, BMC Plant Biology.
[4] C. Rosell,et al. Cereals for developing gluten-free products and analytical tools for gluten detection , 2014 .
[5] P. Shewry,et al. Improving cereal grain carbohydrates for diet and health , 2014, Journal of cereal science.
[6] L. Herrera-Estrella,et al. An improved, low-cost, hydroponic system for growing Arabidopsis and other plant species under aseptic conditions , 2014, BMC Plant Biology.
[7] C. Rosell,et al. The Shutdown of Celiac Disease-Related Gliadin Epitopes in Bread Wheat by RNAi Provides Flours with Increased Stability and Better Tolerance to Over-Mixing , 2014, PloS one.
[8] C. Rosell,et al. Reduced-Gliadin Wheat Bread: An Alternative to the Gluten-Free Diet for Consumers Suffering Gluten-Related Pathologies , 2014, PloS one.
[9] D. Lafiandra,et al. Development of a TILLING resource in durum wheat for reverse- and forward-genetic analyses , 2014, Crop and Pasture Science.
[10] L. Gilissen,et al. Quantitative and qualitative differences in celiac disease epitopes among durum wheat varieties identified through deep RNA-amplicon sequencing , 2013, BMC Genomics.
[11] D. Greenwood,et al. Dietary fibre intake and risk of cardiovascular disease: systematic review and meta-analysis , 2013, BMJ.
[12] Y. Gu,et al. The gene space in wheat: the complete γ-gliadin gene family from the wheat cultivar Chinese Spring , 2013, Functional & Integrative Genomics.
[13] Steven S Xu,et al. Synthetic Hexaploids: Harnessing Species of the Primary Gene Pool for Wheat Improvement , 2013 .
[14] Bao Liu,et al. Structural genes of wheat and barley 5-methylcytosine DNA glycosylases and their potential applications for human health , 2012, Proceedings of the National Academy of Sciences.
[15] Nidhi Rawat,et al. A diploid wheat TILLING resource for wheat functional genomics , 2012, BMC Plant Biology.
[16] Karl H. Mühling,et al. Protein composition and techno-functional properties of transgenic wheat with reduced α-gliadin content obtained by RNA interference , 2012 .
[17] Francisco Barro,et al. The Introgression of RNAi Silencing of γ-Gliadins into Commercial Lines of Bread Wheat Changes the Mixing and Technological Properties of the Dough , 2012, PloS one.
[18] C. Rosell,et al. Significant down-regulation of γ-gliadins has minor effect on gluten and starch properties of bread wheat , 2012 .
[19] M. Parry,et al. Development and Characterization of a New TILLING Population of Common Bread Wheat (Triticum aestivum L.) , 2012, PloS one.
[20] Ismael Padioleau,et al. Celiac disease T-cell epitopes from gamma-gliadins: immunoreactivity depends on the genome of origin, transcript frequency, and flanking protein variation , 2012, BMC Genomics.
[21] A. Camarca,et al. Repertoire of gluten peptides active in celiac disease patients: perspectives for translational therapeutic applications. , 2012, Endocrine, metabolic & immune disorders drug targets.
[22] G. Fazio,et al. Development of high amylose wheat through TILLING , 2012, BMC Plant Biology.
[23] F. Koning,et al. Nomenclature and listing of celiac disease relevant gluten T-cell epitopes restricted by HLA-DQ molecules , 2012, Immunogenetics.
[24] Peter HR Green,et al. Spectrum of gluten-related disorders: consensus on new nomenclature and classification , 2012, BMC Medicine.
[25] R. Lau,et al. Dietary fibre, whole grains, and risk of colorectal cancer: systematic review and dose-response meta-analysis of prospective studies , 2011, BMJ : British Medical Journal.
[26] F. Barro,et al. Down-Regulating γ-Gliadins in Bread Wheat Leads to Non-Specific Increases in Other Gluten Proteins and Has No Major Effect on Dough Gluten Strength , 2011, PloS one.
[27] T. Reunala,et al. Prevalence and incidence of dermatitis herpetiformis: a 40‐year prospective study from Finland , 2011, The British journal of dermatology.
[28] P. Shewry,et al. Suppression of gliadins results in altered protein body morphology in wheat. , 2011, Journal of experimental botany.
[29] L. Gilissen,et al. Dough quality of bread wheat lacking α-gliadins with celiac disease epitopes and addition of celiac-safe avenins to improve dough quality , 2011 .
[30] F. Dupont,et al. Deciphering the complexities of the wheat flour proteome using quantitative two-dimensional electrophoresis, three proteases and tandem mass spectrometry , 2011, Proteome Science.
[31] S. Altenbach,et al. Transformation of the US bread wheat ‘Butte 86’ and silencing of omega-5 gliadin genes , 2011, GM crops.
[32] J. Drijfhout,et al. A Universal Approach to Eliminate Antigenic Properties of Alpha-Gliadin Peptides in Celiac Disease , 2010, PloS one.
[33] D. Lafiandra,et al. Production of novel allelic variation for genes involved in starch biosynthesis through mutagenesis , 2010, Molecular Breeding.
[34] D. Balduzzi,et al. Are we not over-estimating the prevalence of coeliac disease in the general population? , 2010, Annals of medicine.
[35] Chen Hongbing,et al. In search of tetraploid wheat accessions reduced in celiac disease-related gluten epitopes. , 2010, Molecular bioSystems.
[36] L. Sollid,et al. Effective shutdown in the expression of celiac disease-related wheat gliadin T-cell epitopes by RNA interference , 2010, Proceedings of the National Academy of Sciences.
[37] M. Smulders,et al. Presence of celiac disease epitopes in modern and old hexaploid wheat varieties: wheat breeding may have contributed to increased prevalence of celiac disease , 2010, Theoretical and Applied Genetics.
[38] D. Jewell,et al. Comprehensive, Quantitative Mapping of T Cell Epitopes in Gluten in Celiac Disease , 2010, Science Translational Medicine.
[39] J. Dubcovsky,et al. A modified TILLING approach to detect induced mutations in tetraploid and hexaploid wheat , 2009, BMC Plant Biology.
[40] P. Qi,et al. The γ-gliadin multigene family in common wheat (Triticum aestivum) and its closely related species , 2009, BMC Genomics.
[41] Y. Gu,et al. The wheat ω-gliadin genes: structure and EST analysis , 2009, Functional & Integrative Genomics.
[42] C. Schuit,et al. Removing celiac disease-related gluten proteins from bread wheat while retaining technological properties: a study with Chinese Spring deletion lines , 2009, BMC Plant Biology.
[43] J. Sidney,et al. Intestinal T Cell Responses to Gluten Peptides Are Largely Heterogeneous: Implications for a Peptide-Based Therapy in Celiac Disease1 , 2009, The Journal of Immunology.
[44] Pat Baird,et al. Health benefits of dietary fiber. , 2009, Nutrition reviews.
[45] L. Gilissen,et al. Tetraploid and hexaploid wheat varieties reveal large differences in expression of alpha-gliadins from homoeologous Gli-2 loci , 2009, BMC Genomics.
[46] P. Shewry,et al. Allergens to wheat and related cereals , 2008, Clinical and experimental allergy : journal of the British Society for Allergy and Clinical Immunology.
[47] P. Shewry,et al. Silencing of γ-gliadins by RNA interference (RNAi) in bread wheat , 2008 .
[48] J. Buttriss,et al. Dietary fibre and health: an overview , 2008 .
[49] D. Topping. Cereal complex carbohydrates and their contribution to human health , 2007 .
[50] J. Dvorak,et al. Erratum: Genome plasticity a key factor in the success of polyploid wheat under domestication (Science (1862)) , 2007 .
[51] T. B. Osborne. The Vegetable Proteins , 2007, Nature.
[52] A. Fasano,et al. Detection of Celiac Disease in Primary Care: A Multicenter Case-Finding Study in North America , 2007, The American Journal of Gastroenterology.
[53] A. Buchman. Second Annual Snowbird Conference on Clinical Management of Inflammatory Bowel Diseases and Intestinal Failure March 9–12, 2006 , 2007, The American Journal of Gastroenterology.
[54] M. Mitreva,et al. Alpha-gliadin genes from the A, B, and D genomes of wheat contain different sets of celiac disease epitopes , 2006, BMC Genomics.
[55] D. Jewell,et al. Antagonists and non-toxic variants of the dominant wheat gliadin T cell epitope in coeliac disease , 2005, Gut.
[56] J. Drijfhout,et al. Natural variation in toxicity of wheat: potential for selection of nontoxic varieties for celiac disease patients. , 2005, Gastroenterology.
[57] M. Ráki,et al. Mapping of gluten T-cell epitopes in the bread wheat ancestors: implications for celiac disease. , 2005, Gastroenterology.
[58] S. Fuerstenberg,et al. A reverse genetic, nontransgenic approach to wheat crop improvement by TILLING , 2005, Nature Biotechnology.
[59] A. Tatham,et al. Identification of the IgE-binding Epitope in ω-5 Gliadin, a Major Allergen in Wheat-dependent Exercise-induced Anaphylaxis* , 2004, Journal of Biological Chemistry.
[60] S. Henikoff,et al. Efficient discovery of DNA polymorphisms in natural populations by Ecotilling. , 2004, The Plant journal : for cell and molecular biology.
[61] J. Drijfhout,et al. The gluten response in children with celiac disease is directed toward multiple gliadin and glutenin peptides. , 2002, Gastroenterology.
[62] S. Henikoff,et al. Targeting induced local lesions IN genomes (TILLING) for plant functional genomics. , 2000, Plant physiology.
[63] D. Jewell,et al. In vivo antigen challenge in celiac disease identifies a single transglutaminase-modified peptide as the dominant A-gliadin T-cell epitope , 2000, Nature Medicine.
[64] J. Dvorak,et al. The wheat low-molecular-weight glutenin genes: characterization of six new genes and progress in understanding gene family structure , 1998, Theoretical and Applied Genetics.
[65] O. Anderson,et al. The α-gliadin gene family. II. DNA and protein sequence variation, subfamily structure, and origins of pseudogenes , 1997, Theoretical and Applied Genetics.
[66] G. Corazza,et al. Wheat deficient in gliadins: promising tool for treatment of coeliac disease. , 1995, Gut.
[67] P. Shewry,et al. Characterization and organization of gene families at the Gli-1 loci of bread and durum wheats by restriction fragment analysis , 1991, Theoretical and Applied Genetics.
[68] P. Shewry,et al. The classification and nomenclature of wheat gluten proteins: A reassessment , 1986 .
[69] P. Ciclitira,et al. Clinical Testing in Coeliac Patients of Bread Made from Wheats Deficient in Some α-Gliadins , 1980 .
[70] P. Ciclitira,et al. CLINICAL TESTING OF BREAD MADE FROM NULLISOMIC 6A WHEATS IN CŒLIAC PATIENTS , 1980, The Lancet.
[71] D. Kasarda,et al. Nullisonmic‐Tetrasomic Wheat for Agronomic and Nutritional Studies 1 , 1978 .
[72] D. Kasarda,et al. Relationship of gliadin protein components to chromosomes in hexaploid wheats (Triticum aestivum L.). , 1976, Proceedings of the National Academy of Sciences of the United States of America.
[73] W. Williams. Evolution of Crop Plants , 1965, Nature.
[74] Tariq Mahmood,et al. Genetic Diversity for Wheat Improvement as a Conduit to Food Security , 2013 .
[75] D. Noto,et al. Searching for wheat plants with low toxicity in celiac disease: Between direct toxicity and immunologic activation. , 2011, Digestive and liver disease : official journal of the Italian Society of Gastroenterology and the Italian Association for the Study of the Liver.
[76] J. Jenkins,et al. Wheat grain proteins. , 2009 .
[77] C. Sparks,et al. Biolistics transformation of wheat. , 2009, Methods in molecular biology.
[78] Huixia Wu,et al. Agrobacterium-mediated transformation of bread and durum wheat using freshly isolated immature embryos. , 2009, Methods in molecular biology.
[79] Mindi Schneider. "We are Hungry!" A Summary Report of Food Riots, Government Responses, and States of Democracy in 2008 , 2008 .
[80] P. Ng,et al. Characterization of wheat with strongly reduced α-gliadin content. , 2007 .
[81] P. Ng,et al. Silencing the α-gliadins in hexaploid bread wheat. , 2007 .
[82] E. Abdel‐Aal,et al. Specialty grains for food and feed. , 2004 .
[83] P. Shewry,et al. Genetics of wheat gluten proteins. , 2003, Advances in genetics.
[84] P. Shewry,et al. The high molecular weight subunits of wheat glutenin and their role in determining wheat processing properties. , 2003, Advances in food and nutrition research.
[85] P. Shewry,et al. The Prolamins of the Triticeae , 1999 .
[86] P. I. Payne. Genetics of Wheat Storage Proteins and the Effect of Allelic Variation on Bread-Making Quality , 1987 .