The effect of lipoxygenase action on the mechanical development of doughs from fat‐extracted and reconstituted wheat flours

Frazier, P. J.; Brimblecombe, Felicity A.; Daniels, N. W. R.; Eggitt, P. W. Russell

doi:10.1002/jsfa.2740280305

Cited by 40 publications

(23 citation statements)

References 11 publications

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“…Lipoxygenase is able to act on polyunsaturated fatty acids (PUFA) in the presence of oxygen to form hydroperoxides (Gardner 1988). These reactions explain the bleaching effect of lipoxygenase on crumb color and its improving effect on the rheological properties of dough, such as increasing relaxation time and mixing tolerance (Frazier et al 1977, Nicolas 1978, Hoseney et al 1980, Faubion and Hoseney 1981. These reactions explain the bleaching effect of lipoxygenase on crumb color and its improving effect on the rheological properties of dough, such as increasing relaxation time and mixing tolerance (Frazier et al 1977, Nicolas 1978, Hoseney et al 1980, Faubion and Hoseney 1981.…”

mentioning

confidence: 99%

Effect of Exogenous Lipase on Dough Lipids During Mixing of Wheat Flours

Castello

Jollet²,

Potus

et al. 1998

Cereal Chem

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Cereal Chem. 75(5):595-601In control dough, endogenous wheat lipase was inactive, because the triacylglycerol (TAG), 1,2-diacylglycerol (DAG 1,2 ), and 1,3-diacylglycerol (DAG 1,3 ) fractions of nonpolar lipids were not affected by mixing. Conversely, the free fatty acid (FFA) and monoacylglycerol (MAG) fractions decreased, mainly due to the oxidation of polyunsaturated fatty acids (PUFA) catalyzed by wheat lipoxygenase. Addition of exogenous lipase to flour (15 lipase units [LU] per gram of dry matter) resulted in substantial modification of nonpolar lipids during dough mixing. Due to the 1,3 specificity of the lipase used in this experiment, the TAG and DAG 1,3 fractions decreased, whereas the MAG and FFA fractions increased. The DAG 1,2 fraction increased at the beginning of mixing and decreased after 40 min of mixing. Moreover, part of the PUFA released by lipase activity was oxidized by wheat lipoxygenase, resulting in major losses of PUFA. Conversely, the net content of the saturated and monounsaturated fatty acids (SMUFA) remained constant, because the free SMUFA content increased primarily at the expense of the esterified forms. For a constant mixing time of 20 min, increasing the amount of lipase added to dough (from 2.5 to 25 LU/g of dry matter) resulted in a linear decrease in the TAG fraction and a linear increase in the SMUFA content in the FFA fraction. At the same time, the PUFA content of the FFA fraction increased only for additions of lipase to flour of >5 LU/g of dry matter, due to partial oxidation by wheat lipoxygenase.

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mentioning

confidence: 99%

Effect of Exogenous Lipase on Dough Lipids During Mixing of Wheat Flours

Castello

Jollet²,

Potus

et al. 1998

Cereal Chem

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“…LOX can also co-oxidize SH-groups in proteins resulting in crosslinking or aggregate formation, which in turn affects the structure of the product (Permyakova & Trufanov, 2011). The role of LOXs in bread and pasta quality has been addressed in several studies (Cato et al, 2006;Faubion & Hoseney, 1981;Frazier et al, 1977;Hoseney et al, 1980;Junqueira et al, 2007). The bleaching effect, caused by hydroperoxides, can also be exploited in dairy products, e.g.…”

Section: Use Of Lox In Food Applicationsmentioning

confidence: 95%

“…Oxidation of SH-groups by LOX produced hydroperoxide Faubion & Hoseney, 1981;Frazier et al, 1977;Hoseney et al, 1980 Production of oleochemicals…”

Section: Glycine Maxmentioning

confidence: 98%

Industrial potential of lipoxygenases

Heshof

Graaff

Villaverde

et al. 2015

Critical Reviews in Biotechnology

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Lipoxygenases (LOXs) are iron- or manganese-containing oxidative enzymes found in plants, animals, bacteria and fungi. LOXs catalyze the oxidation of polyunsaturated fatty acids to the corresponding highly reactive hydroperoxides. Production of hydroperoxides by LOX can be exploited in different applications such as in bleaching of colored components, modification of lipids originating from different raw materials, production of lipid derived chemicals and production of aroma compounds. Most application research has been carried out using soybean LOX, but currently the use of microbial LOXs has also been reported. Development of LOX composition with high activity by heterologous expression in suitable production hosts would enable full exploitation of the potential of LOX derived reactions in different applications. Here, we review the biological role of LOXs, their heterologous production, as well as potential use in different applications. LOXs may fulfill an important role in the design of processes that are far more environmental friendly than currently used chemical reactions. Difficulties in screening for the optimal enzymes and producing LOX enzymes in sufficient amounts prevent large-scale application so far. With this review, we summarize current knowledge of LOX enzymes and the way in which they can be produced and applied.

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“…Lipid-starch complexes include lipids of starch, grain, and flours as well as lipids added as surfactants and emulsifiers. They may form during starch processing such as heating and cooling of starch gels [3][4][5], dough mixing [6][7][8][9], extrusion [10][11][12][13], microencapsulating [14] and manufacture of edible starch-based film, etc. [15,16].…”

Section: Introductionmentioning

confidence: 99%

Effects of thermal treatment on fish lipids‐amylose interaction

Bieńkiewicz

Kołakowska

2004

Euro J Lipid Sci & Tech

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The paper describes a study on effects of thermal treatments (microwave heating and freezing) on fish lipids-amylose starch interactions. Particular attention was paid to lipid availability (extractability from the system) and contribution of fatty acids to various groups of lipids after interactions produced by mixing, microwave heating and storage. Analyses were made on model systems containing fish lipids at different oxidation levels and gelatinised with 10% aqueous solution of amylose starch. The lipid:starch ratio was 1:1. The systems were assayed before and after mixing, microwave heating (4 min, 90 W), freezing (30 d, 218 7C), and heating followed by freezing. Lipid extractability (selective extraction), peroxide value (PV), anisidine value (AsV), fluorescence, and fatty acid profiles (GC/MS) were determined. Mixing of fish lipids with amylose was shown to result in lipid-amylose interaction. The thermal treatments applied (microwave heating or freezing at 219 7C for 30 d) were observed to exert different, significant effects on fish lipids-amylose starch interactions. The effects depended also on the extent of lipid oxidation. Fatty acids of the lipids were bound selectively, PUFA, and particularly DHA, were subjected to stronger binding and higher amounts of those acids were bound.

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The effect of lipoxygenase action on the mechanical development of doughs from fat‐extracted and reconstituted wheat flours

Cited by 40 publications

References 11 publications

Effect of Exogenous Lipase on Dough Lipids During Mixing of Wheat Flours

Effect of Exogenous Lipase on Dough Lipids During Mixing of Wheat Flours

Industrial potential of lipoxygenases

Effects of thermal treatment on fish lipids‐amylose interaction

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