Fluorescent Labeling Study of Plasminogen Concentration and Location in Simulated Bovine Milk Systems

A fluorescent labeling method was developed to study plasminogen (PG) concentration and location in simulated bovine milk. Activity and stability of PG labeled with Alexa Fluor 594 (PG-594) were comparable to those of native PG. The fluorescent signal of PG-594 exhibited pH, temperature, and storage...

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Veröffentlicht in:	Journal of dairy science 2006-01, Vol.89 (1), p.58-70
Hauptverfasser:	Wang, L, Hayes, K. D, Mauer, L. J
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Sprache:	eng
Schlagworte:	Animal productions Animals Biological and medical sciences Blotting, Western bovine milk Caseins - chemistry Caseins - metabolism Cattle chemical bonding Disulfides - chemistry Female Fluorescent Dyes - metabolism fluorescent labeling Food industries Fundamental and applied biological sciences. Psychology Hot Temperature Lactoglobulins - pharmacology Mercaptoethanol - pharmacology Micelles Microscopy, Confocal Milk - enzymology Milk and cheese industries. Ice creams Milk Proteins - analysis Milk Proteins - metabolism Organic Chemicals - metabolism plasmin plasminogen Plasminogen - analysis Plasminogen - antagonists & inhibitors Plasminogen - metabolism Protein Denaturation Protein Folding Solubility Spectrometry, Fluorescence Terrestrial animal productions Vertebrates Whey Proteins β-lactoglobulin
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description	A fluorescent labeling method was developed to study plasminogen (PG) concentration and location in simulated bovine milk. Activity and stability of PG labeled with Alexa Fluor 594 (PG-594) were comparable to those of native PG. The fluorescent signal of PG-594 exhibited pH, temperature, and storage stability, and remained stable throughout typical sample treatments (stirring, heating, and ultracentrifugation). These characteristics indicate broad applicability of the fluorescent labeling technique for milk protease characterization. In an example application, PG-594 was added to simulated milk samples to study effects of heat and β-lactoglobulin (β-LG) on the distribution of PG. Before heating, about one-third of the PG-594 remained soluble in the whey fraction (supernatant) whereas the rest became associated with the casein micelle. Addition of β-LG to the system slightly shifted PG-594 distribution toward the whey fraction. Heat-induced PG-594 binding to micelles in whey-protein-free systems was evidenced by a decrease of PG-594 from 31 to 15% in the whey fraction accompanied by an increase of PG-594 from 69 to 85% in casein micelle fractions. When β-LG was present during heating, more than 95% of PG-594 became associated with the micelle. A comparison with the distribution pattern of PG-derived activities revealed that heat-induced PG binding to micelles accompanies heat-induced PG inactivation in the micelle fraction. Incubation of the casein micelles with the reducing agent β-mercaptoethanol revealed that disulfide bonds formed between PG and casein or between PG and casein-bound β-LG are the mechanisms for heat-induced PG binding to casein micelles. Western blotting and zymography results correlated well with fluorescent labeling studies and activity studies, respectively. Theoretically important findings are: 1) when heated, serum PG is capable of covalently binding to micellar casein or complexing with β-LG in whey and then coadhering to micelles, and 2) PG that associated with micellar casein through lysine binding sites before heating is capable of developing heat-induced disulfide bonds with casein. The overall results are PG covalently binding to micelles and inactivation thereafter. Our results suggest that, instead of thermal denaturation through irreversible unfolding, covalent bond formation between PG and other milk proteins is the mechanism of PG inhibition during thermal processing.
doi_str_mv	10.3168/jds.S0022-0302(06)72069-0
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D ; Mauer, L. J</creator><creatorcontrib>Wang, L ; Hayes, K. D ; Mauer, L. J</creatorcontrib><description>A fluorescent labeling method was developed to study plasminogen (PG) concentration and location in simulated bovine milk. Activity and stability of PG labeled with Alexa Fluor 594 (PG-594) were comparable to those of native PG. The fluorescent signal of PG-594 exhibited pH, temperature, and storage stability, and remained stable throughout typical sample treatments (stirring, heating, and ultracentrifugation). These characteristics indicate broad applicability of the fluorescent labeling technique for milk protease characterization. In an example application, PG-594 was added to simulated milk samples to study effects of heat and β-lactoglobulin (β-LG) on the distribution of PG. Before heating, about one-third of the PG-594 remained soluble in the whey fraction (supernatant) whereas the rest became associated with the casein micelle. Addition of β-LG to the system slightly shifted PG-594 distribution toward the whey fraction. Heat-induced PG-594 binding to micelles in whey-protein-free systems was evidenced by a decrease of PG-594 from 31 to 15% in the whey fraction accompanied by an increase of PG-594 from 69 to 85% in casein micelle fractions. When β-LG was present during heating, more than 95% of PG-594 became associated with the micelle. A comparison with the distribution pattern of PG-derived activities revealed that heat-induced PG binding to micelles accompanies heat-induced PG inactivation in the micelle fraction. Incubation of the casein micelles with the reducing agent β-mercaptoethanol revealed that disulfide bonds formed between PG and casein or between PG and casein-bound β-LG are the mechanisms for heat-induced PG binding to casein micelles. Western blotting and zymography results correlated well with fluorescent labeling studies and activity studies, respectively. Theoretically important findings are: 1) when heated, serum PG is capable of covalently binding to micellar casein or complexing with β-LG in whey and then coadhering to micelles, and 2) PG that associated with micellar casein through lysine binding sites before heating is capable of developing heat-induced disulfide bonds with casein. The overall results are PG covalently binding to micelles and inactivation thereafter. Our results suggest that, instead of thermal denaturation through irreversible unfolding, covalent bond formation between PG and other milk proteins is the mechanism of PG inhibition during thermal processing.</description><identifier>ISSN: 0022-0302</identifier><identifier>EISSN: 1525-3198</identifier><identifier>DOI: 10.3168/jds.S0022-0302(06)72069-0</identifier><identifier>PMID: 16357268</identifier><identifier>CODEN: JDSCAE</identifier><language>eng</language><publisher>Savoy, IL: Elsevier Inc</publisher><subject>Animal productions ; Animals ; Biological and medical sciences ; Blotting, Western ; bovine milk ; Caseins - chemistry ; Caseins - metabolism ; Cattle ; chemical bonding ; Disulfides - chemistry ; Female ; Fluorescent Dyes - metabolism ; fluorescent labeling ; Food industries ; Fundamental and applied biological sciences. Psychology ; Hot Temperature ; Lactoglobulins - pharmacology ; Mercaptoethanol - pharmacology ; Micelles ; Microscopy, Confocal ; Milk - enzymology ; Milk and cheese industries. Ice creams ; Milk Proteins - analysis ; Milk Proteins - metabolism ; Organic Chemicals - metabolism ; plasmin ; plasminogen ; Plasminogen - analysis ; Plasminogen - antagonists & inhibitors ; Plasminogen - metabolism ; Protein Denaturation ; Protein Folding ; Solubility ; Spectrometry, Fluorescence ; Terrestrial animal productions ; Vertebrates ; Whey Proteins ; β-lactoglobulin</subject><ispartof>Journal of dairy science, 2006-01, Vol.89 (1), p.58-70</ispartof><rights>2006 American Dairy Science Association</rights><rights>2006 INIST-CNRS</rights><rights>Copyright American Dairy Science Association Jan 2006</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c536t-41d9eb8b08ba68e7fb42eee7045a7366ce083206e7b46320ec889e4c469c61a13</citedby><cites>FETCH-LOGICAL-c536t-41d9eb8b08ba68e7fb42eee7045a7366ce083206e7b46320ec889e4c469c61a13</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://www.sciencedirect.com/science/article/pii/S0022030206720690$$EHTML$$P50$$Gelsevier$$Hfree_for_read</linktohtml><link.rule.ids>314,776,780,3537,4010,27900,27901,27902,65306</link.rule.ids><backlink>$$Uhttp://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=17383550$$DView record in Pascal Francis$$Hfree_for_read</backlink><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/16357268$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Wang, L</creatorcontrib><creatorcontrib>Hayes, K. D</creatorcontrib><creatorcontrib>Mauer, L. J</creatorcontrib><title>Fluorescent Labeling Study of Plasminogen Concentration and Location in Simulated Bovine Milk Systems</title><title>Journal of dairy science</title><addtitle>J Dairy Sci</addtitle><description>A fluorescent labeling method was developed to study plasminogen (PG) concentration and location in simulated bovine milk. Activity and stability of PG labeled with Alexa Fluor 594 (PG-594) were comparable to those of native PG. The fluorescent signal of PG-594 exhibited pH, temperature, and storage stability, and remained stable throughout typical sample treatments (stirring, heating, and ultracentrifugation). These characteristics indicate broad applicability of the fluorescent labeling technique for milk protease characterization. In an example application, PG-594 was added to simulated milk samples to study effects of heat and β-lactoglobulin (β-LG) on the distribution of PG. Before heating, about one-third of the PG-594 remained soluble in the whey fraction (supernatant) whereas the rest became associated with the casein micelle. Addition of β-LG to the system slightly shifted PG-594 distribution toward the whey fraction. Heat-induced PG-594 binding to micelles in whey-protein-free systems was evidenced by a decrease of PG-594 from 31 to 15% in the whey fraction accompanied by an increase of PG-594 from 69 to 85% in casein micelle fractions. When β-LG was present during heating, more than 95% of PG-594 became associated with the micelle. A comparison with the distribution pattern of PG-derived activities revealed that heat-induced PG binding to micelles accompanies heat-induced PG inactivation in the micelle fraction. Incubation of the casein micelles with the reducing agent β-mercaptoethanol revealed that disulfide bonds formed between PG and casein or between PG and casein-bound β-LG are the mechanisms for heat-induced PG binding to casein micelles. Western blotting and zymography results correlated well with fluorescent labeling studies and activity studies, respectively. Theoretically important findings are: 1) when heated, serum PG is capable of covalently binding to micellar casein or complexing with β-LG in whey and then coadhering to micelles, and 2) PG that associated with micellar casein through lysine binding sites before heating is capable of developing heat-induced disulfide bonds with casein. The overall results are PG covalently binding to micelles and inactivation thereafter. Our results suggest that, instead of thermal denaturation through irreversible unfolding, covalent bond formation between PG and other milk proteins is the mechanism of PG inhibition during thermal processing.</description><subject>Animal productions</subject><subject>Animals</subject><subject>Biological and medical sciences</subject><subject>Blotting, Western</subject><subject>bovine milk</subject><subject>Caseins - chemistry</subject><subject>Caseins - metabolism</subject><subject>Cattle</subject><subject>chemical bonding</subject><subject>Disulfides - chemistry</subject><subject>Female</subject><subject>Fluorescent Dyes - metabolism</subject><subject>fluorescent labeling</subject><subject>Food industries</subject><subject>Fundamental and applied biological sciences. Psychology</subject><subject>Hot Temperature</subject><subject>Lactoglobulins - pharmacology</subject><subject>Mercaptoethanol - pharmacology</subject><subject>Micelles</subject><subject>Microscopy, Confocal</subject><subject>Milk - enzymology</subject><subject>Milk and cheese industries. Ice creams</subject><subject>Milk Proteins - analysis</subject><subject>Milk Proteins - metabolism</subject><subject>Organic Chemicals - metabolism</subject><subject>plasmin</subject><subject>plasminogen</subject><subject>Plasminogen - analysis</subject><subject>Plasminogen - antagonists & inhibitors</subject><subject>Plasminogen - metabolism</subject><subject>Protein Denaturation</subject><subject>Protein Folding</subject><subject>Solubility</subject><subject>Spectrometry, Fluorescence</subject><subject>Terrestrial animal productions</subject><subject>Vertebrates</subject><subject>Whey Proteins</subject><subject>β-lactoglobulin</subject><issn>0022-0302</issn><issn>1525-3198</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2006</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>BENPR</sourceid><recordid>eNqNkV-P1CAUxRujccfRr6Bo1OhDV_4USh914qrJGE3GfSaU3s4yUlihXTPfXrqduIlPPsFNfpzLOaconhN8zoiQ7w5dOt9hTGmJGaZvsHhbUyyaEt8rVoRTXjLSyPvF6i9yVjxK6ZBHQjF_WJwRwXhNhVwVcOGmECEZ8CPa6hac9Xu0G6fuiEKPvjudBuvDHjzaBD9TUY82eKR9h7bBLIP1aGeHyekROvQh3FgP6Kt1P9HumEYY0uPiQa9dgienc11cXnz8sflcbr99-rJ5vy0NZ2IsK9I10MoWy1YLCXXfVhQAalxxXTMhDGDJslOo20rkCxgpG6hMJRojiCZsXbxedK9j-DVBGtVgszXntIcwJSVqXldNTTP44h_wEKbo898UabjEmZqhZoFMDClF6NV1tIOOR0WwmotQuQh1W4SaU1ZYqNsi8rQunp4WTO0A3d3LU_IZeHUCdDLa9VF7Y9MdVzPJOJ-FXi7cld1f_bYRVBq0c1mWzOtlo4jis9yzBet1UHofs9TljmLCMMnpVZRnYrMQkAu4sRBVMhZypV0WNaPqgv0PX38AD9q9lA</recordid><startdate>200601</startdate><enddate>200601</enddate><creator>Wang, L</creator><creator>Hayes, K. 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D ; Mauer, L. J</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c536t-41d9eb8b08ba68e7fb42eee7045a7366ce083206e7b46320ec889e4c469c61a13</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2006</creationdate><topic>Animal productions</topic><topic>Animals</topic><topic>Biological and medical sciences</topic><topic>Blotting, Western</topic><topic>bovine milk</topic><topic>Caseins - chemistry</topic><topic>Caseins - metabolism</topic><topic>Cattle</topic><topic>chemical bonding</topic><topic>Disulfides - chemistry</topic><topic>Female</topic><topic>Fluorescent Dyes - metabolism</topic><topic>fluorescent labeling</topic><topic>Food industries</topic><topic>Fundamental and applied biological sciences. Psychology</topic><topic>Hot Temperature</topic><topic>Lactoglobulins - pharmacology</topic><topic>Mercaptoethanol - pharmacology</topic><topic>Micelles</topic><topic>Microscopy, Confocal</topic><topic>Milk - enzymology</topic><topic>Milk and cheese industries. Ice creams</topic><topic>Milk Proteins - analysis</topic><topic>Milk Proteins - metabolism</topic><topic>Organic Chemicals - metabolism</topic><topic>plasmin</topic><topic>plasminogen</topic><topic>Plasminogen - analysis</topic><topic>Plasminogen - antagonists & inhibitors</topic><topic>Plasminogen - metabolism</topic><topic>Protein Denaturation</topic><topic>Protein Folding</topic><topic>Solubility</topic><topic>Spectrometry, Fluorescence</topic><topic>Terrestrial animal productions</topic><topic>Vertebrates</topic><topic>Whey Proteins</topic><topic>β-lactoglobulin</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Wang, L</creatorcontrib><creatorcontrib>Hayes, K. 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D</au><au>Mauer, L. J</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Fluorescent Labeling Study of Plasminogen Concentration and Location in Simulated Bovine Milk Systems</atitle><jtitle>Journal of dairy science</jtitle><addtitle>J Dairy Sci</addtitle><date>2006-01</date><risdate>2006</risdate><volume>89</volume><issue>1</issue><spage>58</spage><epage>70</epage><pages>58-70</pages><issn>0022-0302</issn><eissn>1525-3198</eissn><coden>JDSCAE</coden><abstract>A fluorescent labeling method was developed to study plasminogen (PG) concentration and location in simulated bovine milk. Activity and stability of PG labeled with Alexa Fluor 594 (PG-594) were comparable to those of native PG. The fluorescent signal of PG-594 exhibited pH, temperature, and storage stability, and remained stable throughout typical sample treatments (stirring, heating, and ultracentrifugation). These characteristics indicate broad applicability of the fluorescent labeling technique for milk protease characterization. In an example application, PG-594 was added to simulated milk samples to study effects of heat and β-lactoglobulin (β-LG) on the distribution of PG. Before heating, about one-third of the PG-594 remained soluble in the whey fraction (supernatant) whereas the rest became associated with the casein micelle. Addition of β-LG to the system slightly shifted PG-594 distribution toward the whey fraction. Heat-induced PG-594 binding to micelles in whey-protein-free systems was evidenced by a decrease of PG-594 from 31 to 15% in the whey fraction accompanied by an increase of PG-594 from 69 to 85% in casein micelle fractions. When β-LG was present during heating, more than 95% of PG-594 became associated with the micelle. A comparison with the distribution pattern of PG-derived activities revealed that heat-induced PG binding to micelles accompanies heat-induced PG inactivation in the micelle fraction. Incubation of the casein micelles with the reducing agent β-mercaptoethanol revealed that disulfide bonds formed between PG and casein or between PG and casein-bound β-LG are the mechanisms for heat-induced PG binding to casein micelles. Western blotting and zymography results correlated well with fluorescent labeling studies and activity studies, respectively. Theoretically important findings are: 1) when heated, serum PG is capable of covalently binding to micellar casein or complexing with β-LG in whey and then coadhering to micelles, and 2) PG that associated with micellar casein through lysine binding sites before heating is capable of developing heat-induced disulfide bonds with casein. The overall results are PG covalently binding to micelles and inactivation thereafter. Our results suggest that, instead of thermal denaturation through irreversible unfolding, covalent bond formation between PG and other milk proteins is the mechanism of PG inhibition during thermal processing.</abstract><cop>Savoy, IL</cop><pub>Elsevier Inc</pub><pmid>16357268</pmid><doi>10.3168/jds.S0022-0302(06)72069-0</doi><tpages>13</tpages><oa>free_for_read</oa></addata></record>
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subjects	Animal productions Animals Biological and medical sciences Blotting, Western bovine milk Caseins - chemistry Caseins - metabolism Cattle chemical bonding Disulfides - chemistry Female Fluorescent Dyes - metabolism fluorescent labeling Food industries Fundamental and applied biological sciences. Psychology Hot Temperature Lactoglobulins - pharmacology Mercaptoethanol - pharmacology Micelles Microscopy, Confocal Milk - enzymology Milk and cheese industries. Ice creams Milk Proteins - analysis Milk Proteins - metabolism Organic Chemicals - metabolism plasmin plasminogen Plasminogen - analysis Plasminogen - antagonists & inhibitors Plasminogen - metabolism Protein Denaturation Protein Folding Solubility Spectrometry, Fluorescence Terrestrial animal productions Vertebrates Whey Proteins β-lactoglobulin
title	Fluorescent Labeling Study of Plasminogen Concentration and Location in Simulated Bovine Milk Systems
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