Characterization of the direct interaction between apple condensed tannins and cholesterol in vitro

•CH quenched the fluorescence of ACT via a static mechanism.•The interaction between ACT and CH was a spontaneous process.•ACT were capable of binding with CH directly in vitro.•ACT were able to precipitate CH mainly via non-covalent bonds.•The characteristics of ACT-CH coprecipitates confirmed the...

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Published inFood chemistry Vol. 309; p. 125762
Main Authors Zeng, Xiangquan, Du, Zhenjiao, Ding, Xiaomeng, Jiang, Weibo
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 30.03.2020
Subjects
Apple condensed tannins
apples
Cholesterol
Cholesterol - chemistry
Cholesterol - metabolism
Cholesterol-lowering effects
Direct interaction
fluorescence
humans
Hydrogen Bonding
Hydrophobic and Hydrophilic Interactions
hydrophobic bonding
Kinetics
Malus - chemistry
Malus - metabolism
Non-covalent bonds
Particle Size
proanthocyanidins
Spectrometry, Fluorescence
spectroscopy
Tannin-cholesterol coprecipitates
tannins
Tannins - chemistry
Tannins - metabolism
Apple condensed tannins
Tannin-cholesterol coprecipitates
Non-covalent bonds
Cholesterol
Direct interaction
Cholesterol-lowering effects
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Abstract •CH quenched the fluorescence of ACT via a static mechanism.•The interaction between ACT and CH was a spontaneous process.•ACT were capable of binding with CH directly in vitro.•ACT were able to precipitate CH mainly via non-covalent bonds.•The characteristics of ACT-CH coprecipitates confirmed the interaction of ACT with CH. To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with cholesterol (CH) was investigated in the present study. Our results suggested that the quenching of ACT fluorescence by CH was carried out according to a static mechanism, while the interaction between ACT and CH in vitro was a spontaneous process. ACT were capable of binding with CH directly, and the CH-binding capacity (35.9–43.9%) of ACT remarkably enhanced with the increase of ACT concentration (0.5–2.0 mg proanthocyanidin B2 equivalent/mL). Besides, spectroscopic methods and morphological analysis were used to characterize the ACT-CH coprecipitates, the findings indicated that ACT were able to precipitate CH via ionic interactions, hydrophobic interactions and intermolecular hydrogen bonds rather than covalent bonds. In conclusion, the direct interaction of ACT with CH might play a role in their CH-lowering effects in humans and animals.
AbstractList To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with cholesterol (CH) was investigated in the present study. Our results suggested that the quenching of ACT fluorescence by CH was carried out according to a static mechanism, while the interaction between ACT and CH in vitro was a spontaneous process. ACT were capable of binding with CH directly, and the CH-binding capacity (35.9–43.9%) of ACT remarkably enhanced with the increase of ACT concentration (0.5–2.0 mg proanthocyanidin B₂ equivalent/mL). Besides, spectroscopic methods and morphological analysis were used to characterize the ACT-CH coprecipitates, the findings indicated that ACT were able to precipitate CH via ionic interactions, hydrophobic interactions and intermolecular hydrogen bonds rather than covalent bonds. In conclusion, the direct interaction of ACT with CH might play a role in their CH-lowering effects in humans and animals.
To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with cholesterol (CH) was investigated in the present study. Our results suggested that the quenching of ACT fluorescence by CH was carried out according to a static mechanism, while the interaction between ACT and CH in vitro was a spontaneous process. ACT were capable of binding with CH directly, and the CH-binding capacity (35.9-43.9%) of ACT remarkably enhanced with the increase of ACT concentration (0.5-2.0 mg proanthocyanidin B equivalent/mL). Besides, spectroscopic methods and morphological analysis were used to characterize the ACT-CH coprecipitates, the findings indicated that ACT were able to precipitate CH via ionic interactions, hydrophobic interactions and intermolecular hydrogen bonds rather than covalent bonds. In conclusion, the direct interaction of ACT with CH might play a role in their CH-lowering effects in humans and animals.
To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with cholesterol (CH) was investigated in the present study. Our results suggested that the quenching of ACT fluorescence by CH was carried out according to a static mechanism, while the interaction between ACT and CH in vitro was a spontaneous process. ACT were capable of binding with CH directly, and the CH-binding capacity (35.9-43.9%) of ACT remarkably enhanced with the increase of ACT concentration (0.5-2.0 mg proanthocyanidin B2 equivalent/mL). Besides, spectroscopic methods and morphological analysis were used to characterize the ACT-CH coprecipitates, the findings indicated that ACT were able to precipitate CH via ionic interactions, hydrophobic interactions and intermolecular hydrogen bonds rather than covalent bonds. In conclusion, the direct interaction of ACT with CH might play a role in their CH-lowering effects in humans and animals.To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with cholesterol (CH) was investigated in the present study. Our results suggested that the quenching of ACT fluorescence by CH was carried out according to a static mechanism, while the interaction between ACT and CH in vitro was a spontaneous process. ACT were capable of binding with CH directly, and the CH-binding capacity (35.9-43.9%) of ACT remarkably enhanced with the increase of ACT concentration (0.5-2.0 mg proanthocyanidin B2 equivalent/mL). Besides, spectroscopic methods and morphological analysis were used to characterize the ACT-CH coprecipitates, the findings indicated that ACT were able to precipitate CH via ionic interactions, hydrophobic interactions and intermolecular hydrogen bonds rather than covalent bonds. In conclusion, the direct interaction of ACT with CH might play a role in their CH-lowering effects in humans and animals.
•CH quenched the fluorescence of ACT via a static mechanism.•The interaction between ACT and CH was a spontaneous process.•ACT were capable of binding with CH directly in vitro.•ACT were able to precipitate CH mainly via non-covalent bonds.•The characteristics of ACT-CH coprecipitates confirmed the interaction of ACT with CH. To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with cholesterol (CH) was investigated in the present study. Our results suggested that the quenching of ACT fluorescence by CH was carried out according to a static mechanism, while the interaction between ACT and CH in vitro was a spontaneous process. ACT were capable of binding with CH directly, and the CH-binding capacity (35.9–43.9%) of ACT remarkably enhanced with the increase of ACT concentration (0.5–2.0 mg proanthocyanidin B2 equivalent/mL). Besides, spectroscopic methods and morphological analysis were used to characterize the ACT-CH coprecipitates, the findings indicated that ACT were able to precipitate CH via ionic interactions, hydrophobic interactions and intermolecular hydrogen bonds rather than covalent bonds. In conclusion, the direct interaction of ACT with CH might play a role in their CH-lowering effects in humans and animals.
ArticleNumber 125762
Author Zeng, Xiangquan
Ding, Xiaomeng
Jiang, Weibo
Du, Zhenjiao
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  givenname: Xiaomeng
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  givenname: Weibo
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Keywords Apple condensed tannins
Tannin-cholesterol coprecipitates
Non-covalent bonds
Cholesterol
Direct interaction
Cholesterol-lowering effects
Language English
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SSID ssj0002018
Score 2.422429
Snippet •CH quenched the fluorescence of ACT via a static mechanism.•The interaction between ACT and CH was a spontaneous process.•ACT were capable of binding with CH...
To provide the scientific evidences for a possible new hypocholesterolemic mechanism of apple condensed tannins (ACT), the direct interaction of ACT with...
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StartPage 125762
SubjectTerms Apple condensed tannins
apples
Cholesterol
Cholesterol - chemistry
Cholesterol - metabolism
Cholesterol-lowering effects
Direct interaction
fluorescence
humans
Hydrogen Bonding
Hydrophobic and Hydrophilic Interactions
hydrophobic bonding
Kinetics
Malus - chemistry
Malus - metabolism
Non-covalent bonds
Particle Size
proanthocyanidins
Spectrometry, Fluorescence
spectroscopy
Tannin-cholesterol coprecipitates
tannins
Tannins - chemistry
Tannins - metabolism
Title Characterization of the direct interaction between apple condensed tannins and cholesterol in vitro
URI https://dx.doi.org/10.1016/j.foodchem.2019.125762
https://www.ncbi.nlm.nih.gov/pubmed/31670123
https://www.proquest.com/docview/2310717664
https://www.proquest.com/docview/2352431739
Volume 309
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