Selective regulation of macrophage lipid metabolism via nanomaterials’ surface chemistry

Junguang Wu; Xuan Bai; Liang Yan; Didar Baimanov; Yalin Cong; Peiyu Quan; Rui Cai; Yong Guan; Wei Bu; Binhua Lin; Jing Wang; Shengtao Yu; Shijiao Li; Yu Chong; Yang Li; Guoqing Hu; Yuliang Zhao; Chunying Chen; Liming Wang

doi:10.1038/s41467-024-52609-7

Selective regulation of macrophage lipid metabolism via nanomaterials’ surface chemistry

Junguang Wu, Xuan Bai, Liang Yan, Didar Baimanov, Yalin Cong, Peiyu Quan, Rui Cai, Yong Guan, Wei Bu, Binhua Lin, Jing Wang, Shengtao Yu, Shijiao Li, Yu Chong, Yang Li, Guoqing Hu, Yuliang Zhao, Chunying Chen, Liming Wang

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Understanding the interface between nanomaterials and lipoproteins is crucial for gaining insights into their impact on lipoprotein structure and lipid metabolism. Here, we use graphene oxide (GOs) nanosheets as a controlled carbon nanomaterial model to study how surface properties influence lipoprotein corona formation and show that GOs have strong binding affinity with low-density lipoprotein (LDL). We use advanced techniques including X-ray reflectivity, circular dichroism, and molecular simulations to explore the interfacial interactions between GOs and LDL. Specifically, hydrophobic GOs preferentially associate with LDL’s lipid components, whereas hydrophilic GOs tend to bind with apolipoproteins. Furthermore, these GOs distinctly modulate a variety of lipid metabolism pathways, including LDL recognition, uptake, hydrolysis, efflux, and lipid droplet formation. This study underscores the importance of structure analysis at the nano-biomolecule interface, emphasizing how nanomaterials’ surface properties critically influence cellular lipid metabolism. These insights will inspire the design and application of future biocompatible nanomaterials and nanomedicines.

Original language	English (US)
Article number	8349
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-52609-7
State	Published - Dec 2024

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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title = "Selective regulation of macrophage lipid metabolism via nanomaterials{\textquoteright} surface chemistry",

abstract = "Understanding the interface between nanomaterials and lipoproteins is crucial for gaining insights into their impact on lipoprotein structure and lipid metabolism. Here, we use graphene oxide (GOs) nanosheets as a controlled carbon nanomaterial model to study how surface properties influence lipoprotein corona formation and show that GOs have strong binding affinity with low-density lipoprotein (LDL). We use advanced techniques including X-ray reflectivity, circular dichroism, and molecular simulations to explore the interfacial interactions between GOs and LDL. Specifically, hydrophobic GOs preferentially associate with LDL{\textquoteright}s lipid components, whereas hydrophilic GOs tend to bind with apolipoproteins. Furthermore, these GOs distinctly modulate a variety of lipid metabolism pathways, including LDL recognition, uptake, hydrolysis, efflux, and lipid droplet formation. This study underscores the importance of structure analysis at the nano-biomolecule interface, emphasizing how nanomaterials{\textquoteright} surface properties critically influence cellular lipid metabolism. These insights will inspire the design and application of future biocompatible nanomaterials and nanomedicines.",

author = "Junguang Wu and Xuan Bai and Liang Yan and Didar Baimanov and Yalin Cong and Peiyu Quan and Rui Cai and Yong Guan and Wei Bu and Binhua Lin and Jing Wang and Shengtao Yu and Shijiao Li and Yu Chong and Yang Li and Guoqing Hu and Yuliang Zhao and Chunying Chen and Liming Wang",

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doi = "10.1038/s41467-024-52609-7",

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T1 - Selective regulation of macrophage lipid metabolism via nanomaterials’ surface chemistry

AU - Wu, Junguang

AU - Bai, Xuan

AU - Yan, Liang

AU - Baimanov, Didar

AU - Cong, Yalin

AU - Quan, Peiyu

AU - Cai, Rui

AU - Guan, Yong

AU - Bu, Wei

AU - Lin, Binhua

AU - Wang, Jing

AU - Yu, Shengtao

AU - Li, Shijiao

AU - Chong, Yu

AU - Li, Yang

AU - Hu, Guoqing

AU - Zhao, Yuliang

AU - Chen, Chunying

AU - Wang, Liming

PY - 2024/12

Y1 - 2024/12

N2 - Understanding the interface between nanomaterials and lipoproteins is crucial for gaining insights into their impact on lipoprotein structure and lipid metabolism. Here, we use graphene oxide (GOs) nanosheets as a controlled carbon nanomaterial model to study how surface properties influence lipoprotein corona formation and show that GOs have strong binding affinity with low-density lipoprotein (LDL). We use advanced techniques including X-ray reflectivity, circular dichroism, and molecular simulations to explore the interfacial interactions between GOs and LDL. Specifically, hydrophobic GOs preferentially associate with LDL’s lipid components, whereas hydrophilic GOs tend to bind with apolipoproteins. Furthermore, these GOs distinctly modulate a variety of lipid metabolism pathways, including LDL recognition, uptake, hydrolysis, efflux, and lipid droplet formation. This study underscores the importance of structure analysis at the nano-biomolecule interface, emphasizing how nanomaterials’ surface properties critically influence cellular lipid metabolism. These insights will inspire the design and application of future biocompatible nanomaterials and nanomedicines.

AB - Understanding the interface between nanomaterials and lipoproteins is crucial for gaining insights into their impact on lipoprotein structure and lipid metabolism. Here, we use graphene oxide (GOs) nanosheets as a controlled carbon nanomaterial model to study how surface properties influence lipoprotein corona formation and show that GOs have strong binding affinity with low-density lipoprotein (LDL). We use advanced techniques including X-ray reflectivity, circular dichroism, and molecular simulations to explore the interfacial interactions between GOs and LDL. Specifically, hydrophobic GOs preferentially associate with LDL’s lipid components, whereas hydrophilic GOs tend to bind with apolipoproteins. Furthermore, these GOs distinctly modulate a variety of lipid metabolism pathways, including LDL recognition, uptake, hydrolysis, efflux, and lipid droplet formation. This study underscores the importance of structure analysis at the nano-biomolecule interface, emphasizing how nanomaterials’ surface properties critically influence cellular lipid metabolism. These insights will inspire the design and application of future biocompatible nanomaterials and nanomedicines.

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Selective regulation of macrophage lipid metabolism via nanomaterials’ surface chemistry

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