Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery

Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery

Increasing wheat yield and grain quality is crucial for achieving profitable production systems. Genotype has an important role in determining potential grain end-use quality, because it defines the protein subunits stored in the endosperm. Nitrogen (N) and sulfur (S) availability modulate the expression of the genotype by determining variations in quantitative gluten composition. The aim of this work was to analyse the responses of grain quality to N and S fertilisation and relate them to the relative quantitative composition of different subunits of gliadins and glutenins in 24 Argentinean bread wheat cultivars differing in apparent S recovery (ASR), cycle length and protein pattern. Two field experiments were conducted in the Humid Pampas of Argentina. Gluten composition was analysed by electrophoresis and densitometry, and grain quality by N/S ratio, protein content, sedimentation test, and alveograms. Most genotypes presented high quality potential according to their pattern of high molecular weight glutenin subunits, although they differed in grain quality performance. Under an environment of low soil fertility (i.e. where the soil has a low capacity to supply N and S), N fertilisation reduced the sedimentation test values at low S level (67 vs 54 mm, on average) and increased this parameter at high S level (62 vs 81 mm, on average), with different responses among genotypes. Also, S fertilisation at high N level increased dough strength by 52% for long cycle genotypes and decreased it by 9% for those of short cycle. Genotypes with contrasting ASR, cycle length and protein pattern modified the responses of baking strength to S fertilisation in different ways (positive, neutral or negative), whereas genotype N interaction modified the responses only in their magnitude. Outstanding genotypes (e.g. Klein Proteo) were identified according to baking quality stability. We conclude that S fertilisation had a notable effect on baking quality, especially in long cycle genotypes and a low soil-fertility environment, correcting S deficiency at high N availability. ASR was not a useful classificatory trait for predicting grain quality. Instead, the study of variants for the protein subunits coded by particular genes (e.g. Glu-A3, Glu-B3, Glu-D1x and Glu-D1y) that partially determine baking quality should be intensified, in order to optimise genetic improvement in wheat.

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Bibliographic Details
Main Authors: Arata, Agustin Francisco, Rogers, Willian, Tranquilli, Gabriela, Arrigoni, Adriana C., Rondanini, Deborah Paola
Format: info:ar-repo/semantics/artículo biblioteca
Language:eng
Published: CSIRO 2021-03-12
Subjects:Glutenins, Fertilizer Application, Wheat, Nitrogen, Gluteninas, Aplicación de Abonos, Trigo, Nitrógeno, Argentina, Flour Quality, G E Interaction, Calidad de la Harina, Interacción G E, nutrients in soil, nutrientes en el suelo, SDS-PAGE, Trigo Pan,
Online Access:http://hdl.handle.net/20.500.12123/10180
https://www.publish.csiro.au/cp/CP20406
https://doi.org/10.1071/CP20406
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record_format koha
institution INTA AR
collection DSpace
country Argentina
countrycode AR
component Bibliográfico
access En linea
databasecode dig-inta-ar
tag biblioteca
region America del Sur
libraryname Biblioteca Central del INTA Argentina
language eng
topic Glutenins
Fertilizer Application
Wheat
Nitrogen
Gluteninas
Aplicación de Abonos
Trigo
Nitrógeno
Argentina
Flour Quality
G E Interaction
Calidad de la Harina
Interacción G E
nutrients in soil
nutrientes en el suelo
SDS-PAGE
Trigo Pan
Glutenins
Fertilizer Application
Wheat
Nitrogen
Gluteninas
Aplicación de Abonos
Trigo
Nitrógeno
Argentina
Flour Quality
G E Interaction
Calidad de la Harina
Interacción G E
nutrients in soil
nutrientes en el suelo
SDS-PAGE
Trigo Pan
spellingShingle Glutenins
Fertilizer Application
Wheat
Nitrogen
Gluteninas
Aplicación de Abonos
Trigo
Nitrógeno
Argentina
Flour Quality
G E Interaction
Calidad de la Harina
Interacción G E
nutrients in soil
nutrientes en el suelo
SDS-PAGE
Trigo Pan
Glutenins
Fertilizer Application
Wheat
Nitrogen
Gluteninas
Aplicación de Abonos
Trigo
Nitrógeno
Argentina
Flour Quality
G E Interaction
Calidad de la Harina
Interacción G E
nutrients in soil
nutrientes en el suelo
SDS-PAGE
Trigo Pan
Arata, Agustin Francisco
Rogers, Willian
Tranquilli, Gabriela
Arrigoni, Adriana C.
Rondanini, Deborah Paola
Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery
description Increasing wheat yield and grain quality is crucial for achieving profitable production systems. Genotype has an important role in determining potential grain end-use quality, because it defines the protein subunits stored in the endosperm. Nitrogen (N) and sulfur (S) availability modulate the expression of the genotype by determining variations in quantitative gluten composition. The aim of this work was to analyse the responses of grain quality to N and S fertilisation and relate them to the relative quantitative composition of different subunits of gliadins and glutenins in 24 Argentinean bread wheat cultivars differing in apparent S recovery (ASR), cycle length and protein pattern. Two field experiments were conducted in the Humid Pampas of Argentina. Gluten composition was analysed by electrophoresis and densitometry, and grain quality by N/S ratio, protein content, sedimentation test, and alveograms. Most genotypes presented high quality potential according to their pattern of high molecular weight glutenin subunits, although they differed in grain quality performance. Under an environment of low soil fertility (i.e. where the soil has a low capacity to supply N and S), N fertilisation reduced the sedimentation test values at low S level (67 vs 54 mm, on average) and increased this parameter at high S level (62 vs 81 mm, on average), with different responses among genotypes. Also, S fertilisation at high N level increased dough strength by 52% for long cycle genotypes and decreased it by 9% for those of short cycle. Genotypes with contrasting ASR, cycle length and protein pattern modified the responses of baking strength to S fertilisation in different ways (positive, neutral or negative), whereas genotype N interaction modified the responses only in their magnitude. Outstanding genotypes (e.g. Klein Proteo) were identified according to baking quality stability. We conclude that S fertilisation had a notable effect on baking quality, especially in long cycle genotypes and a low soil-fertility environment, correcting S deficiency at high N availability. ASR was not a useful classificatory trait for predicting grain quality. Instead, the study of variants for the protein subunits coded by particular genes (e.g. Glu-A3, Glu-B3, Glu-D1x and Glu-D1y) that partially determine baking quality should be intensified, in order to optimise genetic improvement in wheat.
format info:ar-repo/semantics/artículo
topic_facet Glutenins
Fertilizer Application
Wheat
Nitrogen
Gluteninas
Aplicación de Abonos
Trigo
Nitrógeno
Argentina
Flour Quality
G E Interaction
Calidad de la Harina
Interacción G E
nutrients in soil
nutrientes en el suelo
SDS-PAGE
Trigo Pan
author Arata, Agustin Francisco
Rogers, Willian
Tranquilli, Gabriela
Arrigoni, Adriana C.
Rondanini, Deborah Paola
author_facet Arata, Agustin Francisco
Rogers, Willian
Tranquilli, Gabriela
Arrigoni, Adriana C.
Rondanini, Deborah Paola
author_sort Arata, Agustin Francisco
title Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery
title_short Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery
title_full Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery
title_fullStr Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery
title_full_unstemmed Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery
title_sort nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in argentinean bread wheat cultivars differing in apparent sulfur recovery
publisher CSIRO
publishDate 2021-03-12
url http://hdl.handle.net/20.500.12123/10180
https://www.publish.csiro.au/cp/CP20406
https://doi.org/10.1071/CP20406
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AT tranquilligabriela nitrogensulfurfertilisationeffectsonglutencompositionandindustrialqualityinargentineanbreadwheatcultivarsdifferinginapparentsulfurrecovery
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spelling oai:localhost:20.500.12123-101802024-05-13T10:43:52Z Nitrogen–sulfur fertilisation effects on gluten composition and industrial quality in Argentinean bread wheat cultivars differing in apparent sulfur recovery Arata, Agustin Francisco Rogers, Willian Tranquilli, Gabriela Arrigoni, Adriana C. Rondanini, Deborah Paola Glutenins Fertilizer Application Wheat Nitrogen Gluteninas Aplicación de Abonos Trigo Nitrógeno Argentina Flour Quality G E Interaction Calidad de la Harina Interacción G E nutrients in soil nutrientes en el suelo SDS-PAGE Trigo Pan Increasing wheat yield and grain quality is crucial for achieving profitable production systems. Genotype has an important role in determining potential grain end-use quality, because it defines the protein subunits stored in the endosperm. Nitrogen (N) and sulfur (S) availability modulate the expression of the genotype by determining variations in quantitative gluten composition. The aim of this work was to analyse the responses of grain quality to N and S fertilisation and relate them to the relative quantitative composition of different subunits of gliadins and glutenins in 24 Argentinean bread wheat cultivars differing in apparent S recovery (ASR), cycle length and protein pattern. Two field experiments were conducted in the Humid Pampas of Argentina. Gluten composition was analysed by electrophoresis and densitometry, and grain quality by N/S ratio, protein content, sedimentation test, and alveograms. Most genotypes presented high quality potential according to their pattern of high molecular weight glutenin subunits, although they differed in grain quality performance. Under an environment of low soil fertility (i.e. where the soil has a low capacity to supply N and S), N fertilisation reduced the sedimentation test values at low S level (67 vs 54 mm, on average) and increased this parameter at high S level (62 vs 81 mm, on average), with different responses among genotypes. Also, S fertilisation at high N level increased dough strength by 52% for long cycle genotypes and decreased it by 9% for those of short cycle. Genotypes with contrasting ASR, cycle length and protein pattern modified the responses of baking strength to S fertilisation in different ways (positive, neutral or negative), whereas genotype N interaction modified the responses only in their magnitude. Outstanding genotypes (e.g. Klein Proteo) were identified according to baking quality stability. We conclude that S fertilisation had a notable effect on baking quality, especially in long cycle genotypes and a low soil-fertility environment, correcting S deficiency at high N availability. ASR was not a useful classificatory trait for predicting grain quality. Instead, the study of variants for the protein subunits coded by particular genes (e.g. Glu-A3, Glu-B3, Glu-D1x and Glu-D1y) that partially determine baking quality should be intensified, in order to optimise genetic improvement in wheat. Fil: Arata, A.F. Universidad Nacional del Centro de la Provincia de Buenos Aires. Facultad de Agronomía. Departamento de Producción Vegetal, Cereales y Oleaginosas, Laboratorio de Valoración de Calidad Industrial de Trigo; Argentina Fil: Rogers, W. J. Universidad Nacional del Centro de la Provincia de Buenos Aires. Facultad de Agronomía; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Fil: Tranquilli, Gabriela. Instituto Nacional de Tecnología Agropecuaria (INTA). Instituto de Recursos Biológicos; Argentina Fil: Arrigoni, A.C. Universidad Nacional del Centro de la Provincia de Buenos Aires. Facultad de Agronomía. Departamento de Producción Vegetal, Cereales y Oleaginosas, Laboratorio de Valoración de Calidad Industrial de Trigo; Argentina Fil: Rondanini, D.P. Universidad de Buenos Aires. Facultad de Agronomía; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina 2021-09-03T17:43:29Z 2021-09-03T17:43:29Z 2021-03-12 info:ar-repo/semantics/artículo info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion http://hdl.handle.net/20.500.12123/10180 https://www.publish.csiro.au/cp/CP20406 1836-5795 1836-0947 https://doi.org/10.1071/CP20406 eng info:eu-repo/semantics/restrictedAccess application/pdf CSIRO Crop & Pasture Science 72 (3) : 183-196 (2021)

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