Pork proteins oxidative modifications under the influence of varied time-temperature thermal treatments: A chemical and redox proteomics assessment.

The impact of thermal processing on meat proteins oxidation was investigated. Cooking treatments included 58 °C for either 72 min or 17 h (mimicking low temperature-long time sous vide cooking), 80, 98 and 160 °C for 72 min (mimicking common cooked meat products, stewing and roasting, respectively) and 118 °C for 8 min (autoclaving). Tryptophan degradation, fluorescent oxidation products, free thiol content and α-aminoadipic and γ-glutamic semialdehydes were tracked. For all of them, there was a consistent trend to increased levels of oxidative damage with higher cooking temperatures and longer cooking times, although the extent varied from one indicator to another. Through proteomics, peptide oxidative modifications like carbonylation, malonaldehyde adducts and hydroxykynurenin (tryptophan oxidation products) were also detected at residue level. Our findings indicate that protein oxidation is dependent upon the heat treatment, which point out to a different effect on the nutritional quality of proteins in meat products.

[1]  E. Puolanne,et al.  Fluorescence spectroscopy as a novel approach for the assessment of myofibrillar protein oxidation in oil-in-water emulsions. , 2008, Meat science.

[2]  Jolon M. Dyer,et al.  Cooking-Induced Protein Modifications in Meat. , 2017, Comprehensive reviews in food science and food safety.

[3]  M. Estévez,et al.  Formation of lysine-derived oxidation products and loss of tryptophan during processing of porcine patties with added avocado byproducts. , 2012, Journal of agricultural and food chemistry.

[4]  S. De Smet,et al.  Apple phenolics as inhibitors of the carbonylation pathway during in vitro metal-catalyzed oxidation of myofibrillar proteins. , 2016, Food chemistry.

[5]  V. Parra,et al.  Oxidative and nitrosative stress induced in myofibrillar proteins by a hydroxyl-radical-generating system: impact of nitrite and ascorbate. , 2014, Journal of agricultural and food chemistry.

[6]  V. Santé-Lhoutellier,et al.  Effect of meat cooking on physicochemical state and in vitro digestibility of myofibrillar proteins. , 2008, Journal of agricultural and food chemistry.

[7]  E. Tornberg,et al.  Effects of heat on meat proteins - Implications on structure and quality of meat products. , 2005, Meat science.

[8]  V. Santé-Lhoutellier,et al.  Use of meat fluorescence emission as a marker of oxidation promoted by cooking. , 2009, Meat science.

[9]  F. Leroy,et al.  Protein oxidation affects proteolysis in a meat model system. , 2015, Meat science.

[10]  M. Davies,et al.  Key role of cysteine residues and sulfenic acids in thermal- and H2O2-mediated modification of β-lactoglobulin. , 2016, Free radical biology & medicine.

[11]  Søren Balling Engelsen,et al.  Raman spectroscopic study of effect of the cooking temperature and time on meat proteins , 2014 .

[12]  S. De Smet,et al.  Protein thiols undergo reversible and irreversible oxidation during chill storage of ground beef as detected by 4,4'-dithiodipyridine. , 2014, Journal of agricultural and food chemistry.

[13]  Jiangang Ling,et al.  Proteomic study of the effect of different cooking methods on protein oxidation in fish fillets , 2017 .

[14]  S. De Smet,et al.  Protein oxidation and proteolysis during storage and in vitro digestion of pork and beef patties. , 2016, Food chemistry.

[15]  J. Hofkens,et al.  Basic Principles of Fluorescence Spectroscopy , 2011 .

[16]  Mouming Zhao,et al.  Physicochemical changes of myofibrillar proteins during processing of Cantonese sausage in relation to their aggregation behaviour and in vitro digestibility. , 2011, Food chemistry.

[17]  Jolon M. Dyer,et al.  Proteomic Investigation of Protein Profile Changes and Amino Acid Residue Level Modification in Cooked Lamb Meat: The Effect of Boiling. , 2015, Journal of agricultural and food chemistry.

[18]  V. Santé-Lhoutellier,et al.  Nutritional value and digestion rate of rhea meat proteins in association with storage and cooking processes. , 2011, Meat science.

[19]  C. Luna,et al.  Dietary protein oxidation: A silent threat to human health? , 2017, Critical reviews in food science and nutrition.

[20]  V. Parra,et al.  Protein oxidation during frozen storage and subsequent processing of different beef muscles. , 2014, Meat science.

[21]  M. Estévez,et al.  Oxidation of myofibrillar proteins and impaired functionality: underlying mechanisms of the carbonylation pathway. , 2012, Journal of agricultural and food chemistry.

[22]  V. Santé-Lhoutellier,et al.  Effect of heat treatment on protein oxidation in pig meat. , 2012, Meat science.

[23]  M. Estévez,et al.  Oxidative damage to poultry, pork, and beef during frozen storage through the analysis of novel protein oxidation markers. , 2013, Journal of agricultural and food chemistry.

[24]  F. Toldrá,et al.  Analysis of protein carbonyls in meat products by using the DNPH-method, fluorescence spectroscopy and liquid chromatography-electrospray ionisation-mass spectrometry (LC-ESI-MS). , 2009, Meat science.

[25]  J. Ruiz-Carrascal,et al.  Tracking hydrophobicity state, aggregation behaviour and structural modifications of pork proteins under the influence of assorted heat treatments. , 2017, Food research international.

[26]  J. Ventanas,et al.  Nitrite promotes protein carbonylation and Strecker aldehyde formation in experimental fermented sausages: are both events connected? , 2014, Meat science.

[27]  F. Leroy,et al.  Effect of sodium ascorbate and sodium nitrite on protein and lipid oxidation in dry fermented sausages. , 2016, Meat science.

[28]  M. Estévez,et al.  Pre-freezing raw hams affects quality traits in cooked hams: potential influence of protein oxidation. , 2012, Meat science.

[29]  M. Estévez,et al.  Temperature of frozen storage affects the nature and consequences of protein oxidation in beef patties. , 2014, Meat science.

[30]  S. Clerens,et al.  Effect of cooking on meat proteins: mapping hydrothermal protein modification as a potential indicator of bioavailability. , 2014, Journal of agricultural and food chemistry.

[31]  M. Estévez,et al.  Impact of trolox, quercetin, genistein and gallic acid on the oxidative damage to myofibrillar proteins: the carbonylation pathway. , 2013, Food chemistry.

[32]  E. Vossen,et al.  Dog rose (Rosa canina L.) as a functional ingredient in porcine frankfurters without added sodium ascorbate and sodium nitrite. , 2012, Meat science.

[33]  V. Santé-Lhoutellier,et al.  Characterisation of fluorescent Schiff bases formed during oxidation of pig myofibrils. , 2007, Meat science.

[34]  K. Olsen,et al.  The effect of high pressure on the functional properties of pork myofibrillar proteins. , 2016, Food chemistry.

[35]  M. Estévez,et al.  Fluorescent HPLC for the detection of specific protein oxidation carbonyls - α-aminoadipic and γ-glutamic semialdehydes - in meat systems. , 2011, Meat science.

[36]  L. Skibsted,et al.  Components of wheat flour as activator of commercial enzymes for bread improvement , 2016, European Food Research and Technology.

[37]  M. Aaslyng,et al.  Protein denaturation and water-protein interactions as affected by low temperature long time treatment of porcine longissimus dorsi. , 2011, Meat science.

[38]  J. Ruiz-Carrascal,et al.  Advanced glycation end products, physico-chemical and sensory characteristics of cooked lamb loins affected by cooking method and addition of flavour precursors. , 2015, Food chemistry.

[39]  J. Lepetit,et al.  Front-face fluorescence spectroscopy as a tool to classify seven bovine muscles according to their chemical and rheological characteristics. , 2009, Meat science.

[40]  L. Skibsted,et al.  Thiol oxidation and protein cross-link formation during chill storage of pork patties added essential oil of oregano, rosemary, or garlic. , 2013, Meat science.

[41]  T. Antequera,et al.  Effect of different temperature-time combinations on lipid and protein oxidation of sous-vide cooked lamb loins. , 2014, Food chemistry.

[42]  Søren Balling Engelsen,et al.  Accurate determination of endpoint temperature of cooked meat after storage by Raman spectroscopy and chemometrics , 2015 .

[43]  M. Heinonen,et al.  Protein oxidation in muscle foods: a review. , 2011, Molecular nutrition & food research.

[44]  M. Heinonen,et al.  Formation of Strecker aldehydes between protein carbonyls – α-Aminoadipic and γ-glutamic semialdehydes – and leucine and isoleucine , 2011 .