Impact of Cultivar and Environment on Size Characteristics of Wheat Proteins Using Asymmetrical Flow Field‐Flow Fractionation and Multi‐Angle Laser Light Scattering

Lemelin, E.; Aussenac, Thierry; Violleau, Frédéric; Salvo, Luciana P. Di; Lein, Volker

doi:10.1094/cc-82-0028

Cited by 28 publications

(27 citation statements)

References 21 publications

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“…Starch granules were extracted following Bancel et al (2010) and the volume percentages of A-(diameter > 10 µm), B-(2 µm < diameter < 10 µm), and C-(diameter < 2 µm) granules were determined by using a laser beam scattering apparatus (Debiton et al, 2011). The size distribution and radii of glutenin polymers was analyzed by asymmetric flow field-flow fractionation (AF4) coupled with a multi angle laser light scattering (MALLS) detector (Lemelin et al, 2005). Flour starch content was determined as described by Hendriks et al (2003).…”

Section: Field Experimentsmentioning

confidence: 99%

Wheat response to a wide range of temperatures, as determined from the Hot Serial Cereal (HSC) Experiment

Kimball

2018

ODJAR

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Abstract:Temperatures are warming on a global scale, a phenomenon that likely will affect future crop productivity. Crop growth models are useful tools to predict the likely effects of these global changes on agricultural productivity and to develop strategies to maximize the benefits and minimize the detriments of such changes. However, few such models have been tested at the higher temperatures expected in the future. Therefore, a "Hot Serial Cereal" experiment was conducted on wheat (Triticum aestivum L.), the world's foremost food and feed crop, in order to obtain a dataset appropriate for testing the high temperature performance of wheat growth models. The wheat (Cereal) was planted serially (Serial) about every six weeks for over two years at Maricopa, Arizona, USA, which experiences the whole range of temperatures at which plants grow on Earth. In addition, on six planting dates infrared heaters in a T-FACE (temperature free-air controlled enhancement) system (Hot) were deployed over one-third of the plots to warm the wheat by additional target 1.5°C during daytime and 3.0°C at night. Achieved average degrees of warming were 1.3 and 2.7°C for day and night. Overall, a dataset covering 27 differently treated wheat crops with three replicates each was obtained covering an air temperature range from -2 to 42°C. Herein, the management, soils, weather, physiology, phenology, growth, yield, quality, and other data are presented.

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Section: Field Experimentsmentioning

confidence: 99%

Wheat response to a wide range of temperatures, as determined from the Hot Serial Cereal (HSC) Experiment

Kimball

2018

ODJAR

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“…Flow field-flow fractionation (FFFF) [43][44][45][46], which is a new separation technique without any stationary phase, and which is therefore not hampered by a steric exclusion limit [47][48][49], has been used successfully to separate a number HMW fractions [50][51][52]. Furthermore, the MALLS technique which is one of the most effective means of determining molecular weight, size and conformation of glutenin polymers without reference to standards [48,[53][54][55][56] has been applied in combination with the A-FFFF method to accurately measure size and conformation of wheat glutenins [57] ( Figure 5).…”

Section: Size Distribution Of Polymeric Proteinsmentioning

confidence: 99%

“…Asymmetrical flow field-flow fractionation (A4F) profiles of total solubilized storage proteins of a common French wheat cultivar (Soissons). UV (blue line), light scattering at 90° (red line) and molecular weight in relation to elution time (dark line) (from Lemelin et al[57]). …”

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confidence: 99%

Storage Proteins Accumulation and Aggregation in Developing Wheat Grains

Aussenac¹,

Rhazi²

2018

Global Wheat Production

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The aggregative properties of wheat grain prolamins are largely responsible for the technological functionalities of the flours and doughs. The ability of wheat prolamins to form a plastic three-dimensional network during the mixing depends to a large extent on their ability to interact. These aggregative properties, which can be evaluated by measuring their molecular weight distribution, are dependent on the polymorphism of the protein subunits present but also on the environmental conditions that are applied during grain development. Much progress has been made in the last 30 years at a genetic level to better understand and/or to favour the interaction properties of the storage proteins. However, these improvements can be strongly limited by environmental conditions. Any modification of the redox status of the grain cells in response to an oxidative stress can lead to a decrease in the degree of association of the prolamins by limiting the protein-protein interactions during the grain desiccation. Considering the current and projected environmental impacts (i.e. climate change with increasing heat stress), it is essential to better understand these phenomena to implement new breeding strategies for a sustainable quality.

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“…UPP showed a wide variation among the flours / semolina with DFCF1 (43,3%) having the lowest and DF (47,90%) the highest proportion. The differences in extractability of the polymeric proteins could be attributed to differences in degree of polymerization (Singh et al, 2011).The difference of amount of UPP between samples can be explained from different quaternary structure [7]. 3.3 Rheological properties of flours/semolina Table III give rheological data for flours and semolina.…”

Section: Variation Of Protein Fractionsmentioning

confidence: 99%

Polymeric Proteins, Rheological Properties and BREAD Making Quality of Durum Wheat Flours and Semolina

2015

International Conference on Chemical, Agricultural and Biological Sciences (CABS-2015) Sept. 4-5, 2015 Istanbul (Turkey)

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Impact of Cultivar and Environment on Size Characteristics of Wheat Proteins Using Asymmetrical Flow Field‐Flow Fractionation and Multi‐Angle Laser Light Scattering

Cited by 28 publications

References 21 publications

Wheat response to a wide range of temperatures, as determined from the Hot Serial Cereal (HSC) Experiment

Wheat response to a wide range of temperatures, as determined from the Hot Serial Cereal (HSC) Experiment

Storage Proteins Accumulation and Aggregation in Developing Wheat Grains

Polymeric Proteins, Rheological Properties and BREAD Making Quality of Durum Wheat Flours and Semolina

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