Your search keyword '"Nianyin Lv"' showing total 8 results

1. Defective Lamtor5 Leads to Autoimmunity by Deregulating v‐ATPase and Lysosomal Acidification

Author

Wei Zhang, Zhou Sha, Yunzhe Tang, Cuiyuan Jin, Wenhua Gao, Changmai Chen, Lang Yu, Nianyin Lv, Shijia Liu, Feng Xu, Dandan Wang, and Liyun Shi

Subjects

autoimmunity, lamtor5, lysosome, v‐ATPase, Science

Abstract

Abstract Despite accumulating evidence linking defective lysosome function with autoimmune diseases, how the catabolic machinery is regulated to maintain immune homeostasis remains unknown. Late endosomal/lysosomal adaptor, MAPK and mTOR activator 5 (Lamtor5) is a subunit of the Ragulator mediating mechanistic target of rapamycin complex 1 (mTORC1) activation in response to amino acids, but its action mode and physiological role are still unclear. Here it is demonstrated that Lamtor5 level is markedly decreased in peripheral blood mononuclear cells (PBMCs) of patients with systemic lupus erythematosus (SLE). In parallel, the mice with myeloid Lamtor5 ablation developed SLE‐like manifestation. Impaired lysosomal function and aberrant activation of mTORC1 are evidenced in Lamtor5 deficient macrophages and PBMCs of SLE patients, accompanied by blunted autolysosomal pathway and undesirable inflammatory responses. Mechanistically, it is shown that Lamtor5 is physically associated with ATP6V1A, an essential subunit of vacuolar H+‐ATPase (v‐ATPase), and promoted the V0/V1 holoenzyme assembly to facilitate lysosome acidification. The binding of Lamtor5 to v‐ATPase affected the lysosomal tethering of Rag GTPase and weakened its interaction with mTORC1 for activation. Overall, Lamtor5 is identified as a critical factor for immune homeostasis by intergrading v‐ATPase activity, lysosome function, and mTOR pathway. The findings provide a potential therapeutic target for SLE and/or other autoimmune diseases.

Published

2024

2. Medicinal plant-derived mtDNA via nanovesicles induces the cGAS-STING pathway to remold tumor-associated macrophages for tumor regression

Author

Jinfeng Liu, Jiaxin Xiang, Cuiyuan Jin, Lusha Ye, Lei Wang, Yanan Gao, Nianyin Lv, Junfeng Zhang, Fuping You, Hongzhi Qiao, and Liyun Shi

Subjects

Artemisia-derived nanovesicles, Tumor-associated macrophages, mtDNA, cGAS-STING, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Abstract Plant-derived nanovesicles (PDNVs) have been proposed as a major mechanism for the inter-kingdom interaction and communication, but the effector components enclosed in the vesicles and the mechanisms involved are largely unknown. The plant Artemisia annua is known as an anti-malaria agent that also exhibits a wide range of biological activities including the immunoregulatory and anti-tumor properties with the mechanisms to be further addressed. Here, we isolated and purified the exosome-like particles from A. annua, which were characterized by nano-scaled and membrane-bound shape and hence termed artemisia-derived nanovesicles (ADNVs). Remarkably, the vesicles demonstrated to inhibit tumor growth and boost anti-tumor immunity in a mouse model of lung cancer, primarily through remolding the tumor microenvironment and reprogramming tumor-associated macrophages (TAMs). We identified plant-derived mitochondrial DNA (mtDNA), upon internalized into TAMs via the vesicles, as a major effector molecule to induce the cGAS-STING pathway driving the shift of pro-tumor macrophages to anti-tumor phenotype. Furthermore, our data showed that administration of ADNVs greatly improved the efficacy of PD-L1 inhibitor, a prototypic immune checkpoint inhibitor, in tumor-bearing mice. Together, the present study, for the first time, to our knowledge, unravels an inter-kingdom interaction wherein the medical plant-derived mtDNA, via the nanovesicles, induces the immunostimulatory signaling in mammalian immune cells for resetting anti-tumor immunity and promoting tumor eradication. Graphical Abstract

Published

2023

3. Exploring the total flavones of Abelmoschus manihot against IAV-induced lung inflammation by network pharmacology

Author

Yanan Gao, Zihao Liang, Nianyin Lv, Jinjun Shan, Huihui Zhou, Junfeng Zhang, and Liyun Shi

Subjects

Network pharmacology, IAV, TFA, Anti-inflammation, Anti-virus, Other systems of medicine, RZ201-999

Abstract

Abstract Background Abelmoschus manihot (L.) Medicus (AM) is a medicinal plant with various biological activities, including anti-inflammatory, antioxidant, antiviral and immunomodulatory. Previous studies have identified total flavones as the primary bioactive ingredient of AM (termed TFA). However, its role and mechanism in counteracting Influenza A virus (IAV) infection are yet to be explored. Therefore, the study aims to study the antiviral and anti-inflammatory effects of TFA on IAV in vitro and in vivo. Methods A network pharmacology-based approach was applied to identify the antiviral mechanism of TFA against IAV. For the mechanism validation, the cytopathic effect reduction assay evaluated the antiviral activity of TFA in vitro. Meanwhile, the mice were intranasally infected with IAV to induce lung infection. The antiviral effect of TFA was observed in vivo. Further investigation whether the reprogramming microbiome in the TFA treatment group affected antiviral, we conducted a microbial-transfer study with co-housing experiments. Results By applying the network pharmacology-based methods (PPI, GO, and KEGG), we identified 167 potential targets of TFA action, among which 62 targets were related to IAV pathogenesis. A core network containing the pro-inflammatory TNFα, IL-6, IL-1β, MAPKs, and RIG-I receptor signaling pathway was further confirmed as the crucial targets for anti-influenza efficacy of TFA. We demonstrate that TFA provided profound protection against pulmonary IAV infection, which alleviated inflammatory responses, decreased MAPK signaling pathway and expedited viral eradiation. Conclusions Our study unveils a pivotal role for TFA in controlling viral infection and dampening pathology, making it a promising strategy for treating IAV-induced pneumonia.

Published

2022

4. PP2Cδ Controls the Differentiation and Function of Dendritic Cells Through Regulating the NSD2/mTORC2/ACLY Pathway

Author

Nianyin Lv, Sufeng Jin, Zihao Liang, Xiaohui Wu, Yanhua Kang, Lan Su, Yeping Dong, Bingwei Wang, Tonghui Ma, and Liyun Shi

Subjects

autoimmunity, dendritic cells, differentiation, PP2Cδ, mTORC2, Immunologic diseases. Allergy, RC581-607

Abstract

Dendritic cells (DCs) are recognized as a key orchestrator of immune response and homeostasis, deregulation of which may lead to autoimmunity such as experimental autoimmune encephalomyelitis (EAE). Herein we show that the phosphatase PP2Cδ played a pivotal role in regulating DC activation and function, as PP2Cδ ablation caused aberrant maturation, activation, and Th1/Th17-priming of DCs, and hence induced onset of exacerbated EAE. Mechanistically, PP2Cδ restrained the expression of the essential subunit of mTORC2, Rictor, primarily through de-phosphorylating and proteasomal degradation of the methyltransferase NSD2 via CRL4DCAF2 E3 ligase. Loss of PP2Cδ in DCs accordingly sustained activation of the Rictor/mTORC2 pathway and boosted glycolytic and mitochondrial metabolism. Consequently, ATP-citrate lyse (ACLY) was increasingly activated and catalyzed acetyl-CoA for expression of the genes compatible with hyperactivated DCs under PP2Cδ deletion. Collectively, our findings demonstrate that PP2Cδ has an essential role in controlling DCs activation and function, which is critical for prevention of autoimmunity.

Published

2022

5. AdMSC-derived exosomes alleviate acute lung injury via transferring mitochondrial component to improve homeostasis of alveolar macrophages

Author

Liangjun Xia, Chunli Zhang, Nianyin Lv, Zihao Liang, Tonghui Ma, Haibo Cheng, Youbing Xia, and Liyun Shi

Subjects

Lipopolysaccharides, Mice, Inbred C57BL, Mice, Acute Lung Injury, Macrophages, Alveolar, Animals, Homeostasis, Medicine (miscellaneous), Exosomes, Pharmacology, Toxicology and Pharmaceutics (miscellaneous)

Published

2022

6. Medicinal plant-derived mtDNA via nanovesicles induces the cGAS-STING pathway to remold tumor-associated macrophages for tumor regression

Author

Jinfeng Liu, Jiaxin Xiang, Cuiyuan Jin, Lusha Ye, Yanan Gao, Nianyin Lv, Junfeng Zhang, Fuping You, Hongzhi Qiao, and Liyun Shi

Abstract

Plant-derived nanovesicles (PDNVs) have been proposed as a major mechanism for inter-kingdom interaction and communication, but the effector components enclosed and the mechanisms involved are largely unknown. The plant Artemisia annua, known for its anti-malaria properties, exhibits a wide range of biological activities including the immunoregulatory and anti-tumor properties with the mechanisms to be further addressed. Here, we isolated and purified the exosome-like particles from Artemisia annua, and characterized them as nano-scaled and membrane-bound, which were therefore termed artemisia-derived nanovesicles (ADNVs). Remarkably, the vesicles displayed a potential to inhibit tumor growth and boost anti-tumor immunity, primarily through remolding tumor microenvironment and reprogramming tumor-associated macrophages (TAMs). More importantly, we identified plant-derived mitochondrial DNA (mtDNA), upon internalized into TAMs via the vesicles, as a major effector mechanism to induce the cGAS-STING pathway driving the shift of pro-tumor macrophages to anti-tumor phenotype. Furthermore, our data showed that administration of ADNVs greatly improved the efficacy of PD-L1 inhibitor, a prototypic immune checkpoint inhibitor (ICI), in a murine lung cancer model. Together, the present study, for the first time, to our knowledge, unravels an inter-kingdom interaction wherein medical plant-derived mtDNA, via the nanovesicles, induces the immunostimulatory signaling in mammal immune cells for resetting anti-tumor immunity.

Published

2022

7. Exploring the total flavones of Abelmoschus manihot against IAV-induced lung inflammation by network pharmacology

Author

Yanan Gao, Zihao Liang, Nianyin Lv, Jinjun Shan, Huihui Zhou, Junfeng Zhang, and Liyun Shi

Subjects

TFA, Anti-virus, Research, Pneumonia, Network Pharmacology, Flavones, Other systems of medicine, IAV, Mice, Complementary and alternative medicine, Abelmoschus, Influenza A virus, Anti-inflammation, Animals, RZ201-999

Abstract

Background Abelmoschus manihot (L.) Medicus (AM) is a medicinal plant with various biological activities, including anti-inflammatory, antioxidant, antiviral and immunomodulatory. Previous studies have identified total flavones as the primary bioactive ingredient of AM (termed TFA). However, its role and mechanism in counteracting Influenza A virus (IAV) infection are yet to be explored. Therefore, the study aims to study the antiviral and anti-inflammatory effects of TFA on IAV in vitro and in vivo. Methods A network pharmacology-based approach was applied to identify the antiviral mechanism of TFA against IAV. For the mechanism validation, the cytopathic effect reduction assay evaluated the antiviral activity of TFA in vitro. Meanwhile, the mice were intranasally infected with IAV to induce lung infection. The antiviral effect of TFA was observed in vivo. Further investigation whether the reprogramming microbiome in the TFA treatment group affected antiviral, we conducted a microbial-transfer study with co-housing experiments. Results By applying the network pharmacology-based methods (PPI, GO, and KEGG), we identified 167 potential targets of TFA action, among which 62 targets were related to IAV pathogenesis. A core network containing the pro-inflammatory TNFα, IL-6, IL-1β, MAPKs, and RIG-I receptor signaling pathway was further confirmed as the crucial targets for anti-influenza efficacy of TFA. We demonstrate that TFA provided profound protection against pulmonary IAV infection, which alleviated inflammatory responses, decreased MAPK signaling pathway and expedited viral eradiation. Conclusions Our study unveils a pivotal role for TFA in controlling viral infection and dampening pathology, making it a promising strategy for treating IAV-induced pneumonia.

Published

2021

8. Bcl6 Drives Stem-Like Memory Macrophages Differentiation by Coordinating Transcriptional and Metabolic Programs

Author

Weiwei Zhang, Qin Han, Yina Ding, Huihui Zhou, Zhipeng Chen, Jingjing Wang, Nianyin Lv, Yin Lu, Tonghui Ma, Haibo Cheng, and Liyun Shi

Published

2021