The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery

The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery

Protein nanocapsules have exhibited promising potential applications in the field of protein drug delivery. A major issue with various promising nano-sized biotherapeutics including protein nanocapsules is that owing to their particle size they are subject to cellular uptake via endocytosis, and bec...

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Main Authors: Lijuan Jiang, Xin Liang, Gan Liu, Yun Zhou, Xinyu Ye, Xiuli Chen, Qianwei Miao, Li Gao, Xudong Zhang, Lin Mei
Format: Article
Language:English
Published: Taylor & Francis Group 2018-01-01
Series:Drug Delivery
Subjects:
lauric acid
protein nanocapsules
endocytosis
autophagy
drug delivery
Online Access:http://dx.doi.org/10.1080/10717544.2018.1461954
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spelling doaj-477f239d10a64020b8964351e1a6df8c2020-11-25T02:06:36ZengTaylor & Francis GroupDrug Delivery1071-75441521-04642018-01-0125198599410.1080/10717544.2018.14619541461954The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug deliveryLijuan Jiang0Xin Liang1Gan Liu2Yun Zhou3Xinyu Ye4Xiuli Chen5Qianwei Miao6Li Gao7Xudong Zhang8Lin Mei9Tsinghua UniversitySun Yat-sen UniversitySun Yat-sen UniversitySun Yat-sen UniversityTsinghua UniversityTsinghua UniversityTsinghua UniversityThe Affiliated Hospital of Guilin Medical CollegeTsinghua UniversitySun Yat-sen UniversityProtein nanocapsules have exhibited promising potential applications in the field of protein drug delivery. A major issue with various promising nano-sized biotherapeutics including protein nanocapsules is that owing to their particle size they are subject to cellular uptake via endocytosis, and become entrapped and then degraded within endolysosomes, which can significantly impair their therapeutic efficacy. In addition, many nano-sized biotherapeutics could be also sequestered by autophagosomes and degraded through the autolysosomal pathway. Thus, a limiting step in achieving an effective protein therapy is to facilitate the endosomal escape and auto-lysosomal escape to ensure cytosolic delivery of the protein drugs. Here, we prepared a protein nanocapsule based on BSA (nBSA) and the BSA nanocapsules modified with a bilayer of lauric acid (LA-nBSA) to investigate the escape effects from the endosome and autophagosome. The size distribution of nBSA and LA-nBSA analyzed using DLS presents a uniform diameter centered at 10 nm and 16 nm. The data also showed that FITC-labeled nBSA and LA-nBSA were taken up by the cells mainly through Arf-6-dependent endocytosis and Rab34-mediated macropinocytosis. In addition, LA-nBSA could efficiently escape from endosomal before the degradation in endo-lysosomes. Autophagy could also sequester the LA-nBSA through p62 autophagosome vesicles. These two types of nanocapsules underwent different intracellular destinies and lauric acid (LA) coating played a vital role in intracellular particle retention. In conclusion, the protein nanocapsules modified with LA could enhance the protein nanocapsules escape from intercellular trafficking vesicles, and protect the protein from degradation by the lysosomes.http://dx.doi.org/10.1080/10717544.2018.1461954lauric acidprotein nanocapsulesendocytosisautophagydrug delivery
collection DOAJ
language English
format Article
sources DOAJ
author Lijuan Jiang
Xin Liang
Gan Liu
Yun Zhou
Xinyu Ye
Xiuli Chen
Qianwei Miao
Li Gao
Xudong Zhang
Lin Mei
spellingShingle Lijuan Jiang
Xin Liang
Gan Liu
Yun Zhou
Xinyu Ye
Xiuli Chen
Qianwei Miao
Li Gao
Xudong Zhang
Lin Mei
The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
Drug Delivery
lauric acid
protein nanocapsules
endocytosis
autophagy
drug delivery
author_facet Lijuan Jiang
Xin Liang
Gan Liu
Yun Zhou
Xinyu Ye
Xiuli Chen
Qianwei Miao
Li Gao
Xudong Zhang
Lin Mei
author_sort Lijuan Jiang
title The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
title_short The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
title_full The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
title_fullStr The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
title_full_unstemmed The mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
title_sort mechanism of lauric acid-modified protein nanocapsules escape from intercellular trafficking vesicles and its implication for drug delivery
publisher Taylor & Francis Group
series Drug Delivery
issn 1071-7544
1521-0464
publishDate 2018-01-01
description Protein nanocapsules have exhibited promising potential applications in the field of protein drug delivery. A major issue with various promising nano-sized biotherapeutics including protein nanocapsules is that owing to their particle size they are subject to cellular uptake via endocytosis, and become entrapped and then degraded within endolysosomes, which can significantly impair their therapeutic efficacy. In addition, many nano-sized biotherapeutics could be also sequestered by autophagosomes and degraded through the autolysosomal pathway. Thus, a limiting step in achieving an effective protein therapy is to facilitate the endosomal escape and auto-lysosomal escape to ensure cytosolic delivery of the protein drugs. Here, we prepared a protein nanocapsule based on BSA (nBSA) and the BSA nanocapsules modified with a bilayer of lauric acid (LA-nBSA) to investigate the escape effects from the endosome and autophagosome. The size distribution of nBSA and LA-nBSA analyzed using DLS presents a uniform diameter centered at 10 nm and 16 nm. The data also showed that FITC-labeled nBSA and LA-nBSA were taken up by the cells mainly through Arf-6-dependent endocytosis and Rab34-mediated macropinocytosis. In addition, LA-nBSA could efficiently escape from endosomal before the degradation in endo-lysosomes. Autophagy could also sequester the LA-nBSA through p62 autophagosome vesicles. These two types of nanocapsules underwent different intracellular destinies and lauric acid (LA) coating played a vital role in intracellular particle retention. In conclusion, the protein nanocapsules modified with LA could enhance the protein nanocapsules escape from intercellular trafficking vesicles, and protect the protein from degradation by the lysosomes.
topic lauric acid
protein nanocapsules
endocytosis
autophagy
drug delivery
url http://dx.doi.org/10.1080/10717544.2018.1461954
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