The unique composition of milk makes this basic foodstuff into an exceptional raw material for the production of new ingredients with desired properties and diverse applications in the food industry. The fractionation...The unique composition of milk makes this basic foodstuff into an exceptional raw material for the production of new ingredients with desired properties and diverse applications in the food industry. The fractionation of milk is the key in the development of those ingredients and products;hence continuous research and development on this field, especially various levels of fractionation and separation by filtration, have been carried out. This review focuses on the production of milk fractions as well as their particular properties, applications and processes that increase their exploitation. Whey proteins and caseins from the protein fraction are excellent emulsifiers and protein supplements. Besides, they can be chemically or enzymatically modified to obtain bioactive peptides with numerous functional and nutritional properties. In this context, valorization techniques of cheese-whey proteins, by-product of dairy industry that constitutes both economic and environmental problems, are being developed. Phospholipids from the milk fat fraction are powerful emulsifiers and also have exclusive nutraceutical properties. In addition, enzyme modification of milk phospholipids makes it possible to tailor emulsifiers with particular properties. However, several aspects remain to be overcome;those refer to a deeper understanding of the healthy, functional and nutritional properties of these new ingredients that might be barriers for its use and acceptability. Additionally, in this review, alternative applications of milk constituents in the non-food area such as in the manufacture of plastic materials and textile fibers are also introduced. The unmet needs, the cross-fertilization in between various protein domains,the carbon footprint requirements, the environmental necessities, the health and wellness new demand, etc., are dominant factors in the search for innovation approaches;these factors are also outlining the further innovation potential deriving from those “apparent” constrains obliging science and technology to take them into account.展开更多
Food components possessing zinc ligands can be used to inhibit zinc-dependent enzymes.In this study,zinc-binding peptides were derived from whey protein hydrolysates,and their ultrafiltration(>1 and<1 kDa)fracti...Food components possessing zinc ligands can be used to inhibit zinc-dependent enzymes.In this study,zinc-binding peptides were derived from whey protein hydrolysates,and their ultrafiltration(>1 and<1 kDa)fractions,produced with Esperase(WPH-Esp),Everlase and Savinase.Immobilized metal affinity chromatography(IMAC-Zn^(2+))increased the zinc-binding capacity of the peptide fraction(83%)when compared to WPH-Esp(23%)and its<1 kDa fraction(40%).The increased zinc-binding capacity of the sample increased the inhibitory activity against the zinc-dependent“a disintegrin and metalloproteinase 17”.LC-MS/MS analysis using a shotgun peptidomics approach resulted in the identification of 24 peptides originating from bovineβ-lactoglobulin,α-lactalbumin,serum albumin,β-casein,κ-casein,osteopontin-k,and folate receptor-αin the fraction.The identified peptides contained different combinations of the strong zinc-binding group of residues,His+Cys,Asp+Glu and Phe+Tyr,although Cys residues were absent in the sequences.In silico predictions showed that the IMAC-Zn^(2+)peptides were non-toxins.However,the peptides possessed poor drug-like and pharmacokinetic properties;this was possibly due to their long chain lengths(5–19 residues).Taken together,this work provided an array of food peptide-based zinc ligands for further investigation of structure-function relationships and development of nutraceuticals against inflammatory and other zinc-related diseases.展开更多
文摘The unique composition of milk makes this basic foodstuff into an exceptional raw material for the production of new ingredients with desired properties and diverse applications in the food industry. The fractionation of milk is the key in the development of those ingredients and products;hence continuous research and development on this field, especially various levels of fractionation and separation by filtration, have been carried out. This review focuses on the production of milk fractions as well as their particular properties, applications and processes that increase their exploitation. Whey proteins and caseins from the protein fraction are excellent emulsifiers and protein supplements. Besides, they can be chemically or enzymatically modified to obtain bioactive peptides with numerous functional and nutritional properties. In this context, valorization techniques of cheese-whey proteins, by-product of dairy industry that constitutes both economic and environmental problems, are being developed. Phospholipids from the milk fat fraction are powerful emulsifiers and also have exclusive nutraceutical properties. In addition, enzyme modification of milk phospholipids makes it possible to tailor emulsifiers with particular properties. However, several aspects remain to be overcome;those refer to a deeper understanding of the healthy, functional and nutritional properties of these new ingredients that might be barriers for its use and acceptability. Additionally, in this review, alternative applications of milk constituents in the non-food area such as in the manufacture of plastic materials and textile fibers are also introduced. The unmet needs, the cross-fertilization in between various protein domains,the carbon footprint requirements, the environmental necessities, the health and wellness new demand, etc., are dominant factors in the search for innovation approaches;these factors are also outlining the further innovation potential deriving from those “apparent” constrains obliging science and technology to take them into account.
基金supported by the Natural Sciences and Engineering Research Council of Canada(NSERC)Discovery Grants(RGPIN-435865-2013 and RGPIN-2018-06839)Canada Foundation for Innovation(CFI)John R.Evans Leaders Fund Infrastructure Grant(Project number:31305).
文摘Food components possessing zinc ligands can be used to inhibit zinc-dependent enzymes.In this study,zinc-binding peptides were derived from whey protein hydrolysates,and their ultrafiltration(>1 and<1 kDa)fractions,produced with Esperase(WPH-Esp),Everlase and Savinase.Immobilized metal affinity chromatography(IMAC-Zn^(2+))increased the zinc-binding capacity of the peptide fraction(83%)when compared to WPH-Esp(23%)and its<1 kDa fraction(40%).The increased zinc-binding capacity of the sample increased the inhibitory activity against the zinc-dependent“a disintegrin and metalloproteinase 17”.LC-MS/MS analysis using a shotgun peptidomics approach resulted in the identification of 24 peptides originating from bovineβ-lactoglobulin,α-lactalbumin,serum albumin,β-casein,κ-casein,osteopontin-k,and folate receptor-αin the fraction.The identified peptides contained different combinations of the strong zinc-binding group of residues,His+Cys,Asp+Glu and Phe+Tyr,although Cys residues were absent in the sequences.In silico predictions showed that the IMAC-Zn^(2+)peptides were non-toxins.However,the peptides possessed poor drug-like and pharmacokinetic properties;this was possibly due to their long chain lengths(5–19 residues).Taken together,this work provided an array of food peptide-based zinc ligands for further investigation of structure-function relationships and development of nutraceuticals against inflammatory and other zinc-related diseases.
