从肝衰竭患者循环细胞外囊泡中发现的染色体外环状DNA的特征和功能分析

IF 7.9 1区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL Clinical and Translational Medicine Pub Date : 2024-10-15 DOI:10.1002/ctm2.70059
Yongbing Qian, Xiaoning Hong, Yang Yu, Cong Du, Jing Li, Jiaying Yu, Wenjun Xiao, Chen Chen, Defa Huang, Tianyu Zhong, Jiang Li, Xi Xiang, Zhigang Li
{"title":"从肝衰竭患者循环细胞外囊泡中发现的染色体外环状DNA的特征和功能分析","authors":"Yongbing Qian,&nbsp;Xiaoning Hong,&nbsp;Yang Yu,&nbsp;Cong Du,&nbsp;Jing Li,&nbsp;Jiaying Yu,&nbsp;Wenjun Xiao,&nbsp;Chen Chen,&nbsp;Defa Huang,&nbsp;Tianyu Zhong,&nbsp;Jiang Li,&nbsp;Xi Xiang,&nbsp;Zhigang Li","doi":"10.1002/ctm2.70059","DOIUrl":null,"url":null,"abstract":"<p>Extrachromosomal circular DNA (eccDNA) is a mobile, circular DNA molecule that originates from but exists independently of linear chromosomes.<span><sup>1</sup></span> Its characteristics and potential function in liver failure remain elusive. Herein, we established a reliable workflow for purifying the internal eccDNAs harboured by plasma-derived extracellular vesicles (EVs) and characterization of these EVs-eccDNAs in liver failure. Additionally, the impact of liver failure-specific circulating EVs-eccDNAs on the hepatocytes was evaluated by synthetic eccDNAs transfection and RNAseq analysis.</p><p>This study recruited 22 participants, including 13 patients with liver failure and nine healthy individuals. Detailed information is provided in Table S1 and Material S1. Patients were diagnosed with liver failure using established criteria, and their hepatic function was matched accordingly.<span><sup>2-4</sup></span> Subsequently, we isolated plasma-derived EVs from both healthy control individuals and liver failure.<span><sup>5, 6</sup></span> Electron microscopy images showed that both healthy control EVs (HCEVs) and liver failure patient EVs (LFEVs) exhibited the typical “cup-shaped” morphology with similar average diameters around 100 nm (Figure 1A). Nano-flow cytometry indicated that the concentration of LFEVs was significantly higher than that of HCEVs, but no significant difference in size was found (Figure 1B). Western blot analysis confirmed small EV markers CD9, CD81 and TSG101 were present, while the negative marker Mitofilin was absent (Figure 1C). Notably, LFEVs had a higher level of CD9 than HCEVs. Our data revealed an increased presence of EVs in the peripheral circulation of liver failure patients.</p><p>We then isolated eccDNA from HCEVs and LFEVs using the process illustrated in Figure 2A. Specifically, eccDNAs with &gt; 75 bp overlap of a certain gene were defined as “eccGenes” in the study.<span><sup>7</sup></span> The read sizes for HCEVs and LFEVs were similar (Figure 2B and Table S2). We then identified that LFEVs had a significantly higher number of eccDNAs compared to HCEVs (Figure 2C and Table S2). The normalized eccDNA count per million mapped reads (EPM) was significantly higher in LFEVs (Figure 2D). Additionally, the GC content and flanking regions of eccDNAs from LFEVs were higher than those from HCEVs (Figure 2E,F). The percentage of EPM across all chromosomes was similar for both LFEVs and HCEVs (Figure 2G, Figure S1A and Material S2). Overall, these data indicate that LFEVs carry a higher abundance of eccDNAs than HCEVs.</p><p>We then analyzed the eccDNA lengths in HCEVs and LFEVs. Figure 3A shows five enriched peaks in LFEVs at 370, 566, 751, 946 and 1124 bp, with a noticeably higher density of eccDNAs in LFEVs compared to HCEVs. We calculated the cumulative frequency of HCEVs and LFEVs containing eccDNAs and found that eccDNA lengths in LFEVs were much shorter than those in HCEVs (Figure 3B). Additionally, we found that LFEVs contained a higher ratio of 0.5–1 Kb length eccDNA but a lower ratio of &gt; 2 Kb length eccDNA compared to HCEVs (Figure 3C). Therefore, these findings indicated that LFEVs contained eccDNA with shorter lengths than those in HCEVs. Based on the currently proposed mechanisms of eccDNA formation triggered by genomic stress,<span><sup>8</sup></span> we speculate that this may be related to the increased stress experienced by the genome during the progression of liver failure, which leads to the formation of more and shorter eccDNA into the EVs. Then, we found 75 eccDNAs with common start-end sites in two groups (Figure 3D). As shown in Figure 3E,F, four eccDNAs were more frequently present in LFEVs than in HCEVs among these common start-end eccDNAs. Subsequently, we discovered that these four over-represented LFEVs-eccDNAs carried specific regulatory genes, transposable elements and candidate cis-regulatory elements (Figure 3F). These eccDNAs carried the genes ZMIZ1-AS1 and ZMYM6, which may further influence liver cell functions.</p><p>Using the LAMA method,<span><sup>7</sup></span> we synthesized artificial eccDNA<sup>[chr10:78950400-78950928]</sup> and eccDNA<sup>[chr1:35004981-35005600]</sup>, referred to as eccZMIZ1-AS1 and eccZMYM6, respectively (Figure 4A and Tables S3 and S4). Digestion of the linear A fragment with NdeI or SacI produced two lower DNA bands, while artificial eccZMIZ1-AS1 and eccZMYM6 showed only one higher band, indicating successful synthesis of both (Figure 4B). The synthesized eccZMIZ1-AS1, eccZMYM6 and a random control eccDNA (eccRandom) were transfected into HepG2 cells via electroporation (Figure S2A), and the cells were collected for genome-wide messenger RNA (mRNA) sequencing to assess expression changes. The RNAseq results show that 212 mRNAs upregulated and 50 mRNAs downregulated in eccZMIZ1-AS1 (Figure 4C and Material S3). However, the eccZMYM6 group exhibited no significant changes in mRNA expression (Figure 4D). Subsequently, we analyzed the Kyoto Encyclopedia of Genes and Genomes (KEGG) signalling pathways of differentially expressed genes and found that eccZMIZ1-AS1 primarily regulated the PI3K-Akt and HIF-1 signalling pathways (Figure 4E). Gene Ontology (GO) enrichment analysis showed that eccZMIZ1-AS1 primarily promotes cellular responses to hypoxia, with regulated genes mainly located in the vesicle membrane and associated with calcium-dependent phospholipid binding (Figure 4F). Finally, we found that the genes regulated by eccZMIZ1-AS1 were primarily centred around the cellular processes including response to hypoxia, regulation of lipid metabolic process and exocytic vesicle membrane (Figure 4G). Previous evidence indicated that HIF-1α mediates acute liver failure induced by LPS/D-GalN.<span><sup>9</sup></span> Also, previous studies show that lipid metabolism influences intrahepatic macrophage reprogramming, regulating acute-on-chronic liver failure caused by the hepatitis B virus.<span><sup>10</sup></span> Currently, no studies have established a direct link between liver failure and the exocytic vesicle membrane. These findings suggest that the liver failure-specific circulating EVs-eccDNAs may exert divergent molecular effects on cells, implying that some of them may accelerate the progression of liver failure through systemic impacts on various organs.</p><p>In conclusion, our study presents a reliable method for isolating and characterizing EVs-eccDNAs, offering insights into their disease-associated features in liver failure. The activation of specific signalling pathways by eccDNA in HepG2 cells implies its role in liver failure pathogenesis, suggesting its potential as a diagnostic marker and target for therapeutic interventions. However, limitations include the exclusive use of the HepG2 cell line to validate eccZMIZ1-AS1's functions and the lack of exploration into the specific mechanisms by which it influences liver failure. These aspects require further investigation in future studies.</p><p>Zhigang Li and Xi Xiang planned the project and conceived the experiments. Yongbing Qian, Xiaoning Hong, Yang Yu, Cong Du, Chen Chen, Wenjun Xiao, Jing Li, Jiaying Yu, Tianyu Zhong, and Jiang Li performed the experimental works and analyzed the data. Yongbing Qian, Xiaoning Hong, Yang Yu, Xi Xiang and Zhigang Li conceived the data and wrote the manuscript. All authors approved the final version of the manuscript.</p><p>The authors declare no conflict of interest.</p><p>This work was supported by the National Natural Science Foundation of China (32200638 to Z.L.); Basic and Applied Basic Research Fund of Guangdong Province (2021A1515110512 to Z.L., 2023A1515010090 to Z.L. and 2022A1515110137 to Y.Y.); Shenzhen Science and Technology Innovation Program (JCYJ20230807110316034 to Z.L., JCYJ20210324134612035 to Z.L. and JCYJ20220530145014033 to X.X.); Research Start-up Fund of the Seventh Affiliated Hospital of Sun Yat-sen University (ZSQYBRJH0021 to Z.L. and 592026 to X.X.); Guangdong Provincial Key Laboratory of Digestive Cancer Research (2021B1212040006 to X.X.); The Open Fund of Guangdong Provincial Key Laboratory of Digestive Cancer Research (GPKLDCR202206M to X.X.); Fundamental Research Funds for the Central Universities of Sun Yat-sen University (Grant 2023KYPT02 to X.X.).</p><p>All subjects gave their informed consent for inclusion before they participated in the study. The human ethics of this study was approved by Shanghai Jiao Tong University School of Medicine, Renji Hospital Ethics Committee (KY2021-063-B).</p>","PeriodicalId":10189,"journal":{"name":"Clinical and Translational Medicine","volume":"14 10","pages":""},"PeriodicalIF":7.9000,"publicationDate":"2024-10-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/ctm2.70059","citationCount":"0","resultStr":"{\"title\":\"Characterization and functional analysis of extrachromosomal circular DNA discovered from circulating extracellular vesicles in liver failure\",\"authors\":\"Yongbing Qian,&nbsp;Xiaoning Hong,&nbsp;Yang Yu,&nbsp;Cong Du,&nbsp;Jing Li,&nbsp;Jiaying Yu,&nbsp;Wenjun Xiao,&nbsp;Chen Chen,&nbsp;Defa Huang,&nbsp;Tianyu Zhong,&nbsp;Jiang Li,&nbsp;Xi Xiang,&nbsp;Zhigang Li\",\"doi\":\"10.1002/ctm2.70059\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Extrachromosomal circular DNA (eccDNA) is a mobile, circular DNA molecule that originates from but exists independently of linear chromosomes.<span><sup>1</sup></span> Its characteristics and potential function in liver failure remain elusive. 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Patients were diagnosed with liver failure using established criteria, and their hepatic function was matched accordingly.<span><sup>2-4</sup></span> Subsequently, we isolated plasma-derived EVs from both healthy control individuals and liver failure.<span><sup>5, 6</sup></span> Electron microscopy images showed that both healthy control EVs (HCEVs) and liver failure patient EVs (LFEVs) exhibited the typical “cup-shaped” morphology with similar average diameters around 100 nm (Figure 1A). Nano-flow cytometry indicated that the concentration of LFEVs was significantly higher than that of HCEVs, but no significant difference in size was found (Figure 1B). Western blot analysis confirmed small EV markers CD9, CD81 and TSG101 were present, while the negative marker Mitofilin was absent (Figure 1C). Notably, LFEVs had a higher level of CD9 than HCEVs. Our data revealed an increased presence of EVs in the peripheral circulation of liver failure patients.</p><p>We then isolated eccDNA from HCEVs and LFEVs using the process illustrated in Figure 2A. Specifically, eccDNAs with &gt; 75 bp overlap of a certain gene were defined as “eccGenes” in the study.<span><sup>7</sup></span> The read sizes for HCEVs and LFEVs were similar (Figure 2B and Table S2). We then identified that LFEVs had a significantly higher number of eccDNAs compared to HCEVs (Figure 2C and Table S2). The normalized eccDNA count per million mapped reads (EPM) was significantly higher in LFEVs (Figure 2D). Additionally, the GC content and flanking regions of eccDNAs from LFEVs were higher than those from HCEVs (Figure 2E,F). The percentage of EPM across all chromosomes was similar for both LFEVs and HCEVs (Figure 2G, Figure S1A and Material S2). Overall, these data indicate that LFEVs carry a higher abundance of eccDNAs than HCEVs.</p><p>We then analyzed the eccDNA lengths in HCEVs and LFEVs. Figure 3A shows five enriched peaks in LFEVs at 370, 566, 751, 946 and 1124 bp, with a noticeably higher density of eccDNAs in LFEVs compared to HCEVs. We calculated the cumulative frequency of HCEVs and LFEVs containing eccDNAs and found that eccDNA lengths in LFEVs were much shorter than those in HCEVs (Figure 3B). Additionally, we found that LFEVs contained a higher ratio of 0.5–1 Kb length eccDNA but a lower ratio of &gt; 2 Kb length eccDNA compared to HCEVs (Figure 3C). Therefore, these findings indicated that LFEVs contained eccDNA with shorter lengths than those in HCEVs. Based on the currently proposed mechanisms of eccDNA formation triggered by genomic stress,<span><sup>8</sup></span> we speculate that this may be related to the increased stress experienced by the genome during the progression of liver failure, which leads to the formation of more and shorter eccDNA into the EVs. Then, we found 75 eccDNAs with common start-end sites in two groups (Figure 3D). As shown in Figure 3E,F, four eccDNAs were more frequently present in LFEVs than in HCEVs among these common start-end eccDNAs. Subsequently, we discovered that these four over-represented LFEVs-eccDNAs carried specific regulatory genes, transposable elements and candidate cis-regulatory elements (Figure 3F). These eccDNAs carried the genes ZMIZ1-AS1 and ZMYM6, which may further influence liver cell functions.</p><p>Using the LAMA method,<span><sup>7</sup></span> we synthesized artificial eccDNA<sup>[chr10:78950400-78950928]</sup> and eccDNA<sup>[chr1:35004981-35005600]</sup>, referred to as eccZMIZ1-AS1 and eccZMYM6, respectively (Figure 4A and Tables S3 and S4). Digestion of the linear A fragment with NdeI or SacI produced two lower DNA bands, while artificial eccZMIZ1-AS1 and eccZMYM6 showed only one higher band, indicating successful synthesis of both (Figure 4B). The synthesized eccZMIZ1-AS1, eccZMYM6 and a random control eccDNA (eccRandom) were transfected into HepG2 cells via electroporation (Figure S2A), and the cells were collected for genome-wide messenger RNA (mRNA) sequencing to assess expression changes. The RNAseq results show that 212 mRNAs upregulated and 50 mRNAs downregulated in eccZMIZ1-AS1 (Figure 4C and Material S3). However, the eccZMYM6 group exhibited no significant changes in mRNA expression (Figure 4D). Subsequently, we analyzed the Kyoto Encyclopedia of Genes and Genomes (KEGG) signalling pathways of differentially expressed genes and found that eccZMIZ1-AS1 primarily regulated the PI3K-Akt and HIF-1 signalling pathways (Figure 4E). Gene Ontology (GO) enrichment analysis showed that eccZMIZ1-AS1 primarily promotes cellular responses to hypoxia, with regulated genes mainly located in the vesicle membrane and associated with calcium-dependent phospholipid binding (Figure 4F). Finally, we found that the genes regulated by eccZMIZ1-AS1 were primarily centred around the cellular processes including response to hypoxia, regulation of lipid metabolic process and exocytic vesicle membrane (Figure 4G). Previous evidence indicated that HIF-1α mediates acute liver failure induced by LPS/D-GalN.<span><sup>9</sup></span> Also, previous studies show that lipid metabolism influences intrahepatic macrophage reprogramming, regulating acute-on-chronic liver failure caused by the hepatitis B virus.<span><sup>10</sup></span> Currently, no studies have established a direct link between liver failure and the exocytic vesicle membrane. These findings suggest that the liver failure-specific circulating EVs-eccDNAs may exert divergent molecular effects on cells, implying that some of them may accelerate the progression of liver failure through systemic impacts on various organs.</p><p>In conclusion, our study presents a reliable method for isolating and characterizing EVs-eccDNAs, offering insights into their disease-associated features in liver failure. The activation of specific signalling pathways by eccDNA in HepG2 cells implies its role in liver failure pathogenesis, suggesting its potential as a diagnostic marker and target for therapeutic interventions. However, limitations include the exclusive use of the HepG2 cell line to validate eccZMIZ1-AS1's functions and the lack of exploration into the specific mechanisms by which it influences liver failure. These aspects require further investigation in future studies.</p><p>Zhigang Li and Xi Xiang planned the project and conceived the experiments. Yongbing Qian, Xiaoning Hong, Yang Yu, Cong Du, Chen Chen, Wenjun Xiao, Jing Li, Jiaying Yu, Tianyu Zhong, and Jiang Li performed the experimental works and analyzed the data. Yongbing Qian, Xiaoning Hong, Yang Yu, Xi Xiang and Zhigang Li conceived the data and wrote the manuscript. All authors approved the final version of the manuscript.</p><p>The authors declare no conflict of interest.</p><p>This work was supported by the National Natural Science Foundation of China (32200638 to Z.L.); Basic and Applied Basic Research Fund of Guangdong Province (2021A1515110512 to Z.L., 2023A1515010090 to Z.L. and 2022A1515110137 to Y.Y.); Shenzhen Science and Technology Innovation Program (JCYJ20230807110316034 to Z.L., JCYJ20210324134612035 to Z.L. and JCYJ20220530145014033 to X.X.); Research Start-up Fund of the Seventh Affiliated Hospital of Sun Yat-sen University (ZSQYBRJH0021 to Z.L. and 592026 to X.X.); Guangdong Provincial Key Laboratory of Digestive Cancer Research (2021B1212040006 to X.X.); The Open Fund of Guangdong Provincial Key Laboratory of Digestive Cancer Research (GPKLDCR202206M to X.X.); Fundamental Research Funds for the Central Universities of Sun Yat-sen University (Grant 2023KYPT02 to X.X.).</p><p>All subjects gave their informed consent for inclusion before they participated in the study. 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引用次数: 0

摘要

随后,我们分析了差异表达基因的京都基因组百科全书(KEGG)信号通路,发现ccZMIZ1-AS1主要调控PI3K-Akt和HIF-1信号通路(图4E)。基因本体(GO)富集分析显示,ccZMIZ1-AS1主要促进细胞对缺氧的反应,受调控基因主要位于囊膜,与钙依赖性磷脂结合相关(图4F)。最后,我们发现受ccZMIZ1-AS1调控的基因主要围绕细胞过程,包括对缺氧的反应、脂质代谢过程的调控和外细胞囊膜(图4G)。以前的证据表明,HIF-1α 介导了 LPS/D-GalN 诱导的急性肝衰竭。9 以前的研究还表明,脂质代谢影响肝内巨噬细胞的重编程,调节乙型肝炎病毒引起的急性-慢性肝衰竭。这些发现表明,肝衰竭特异性循环EVs-eccDNAs可能会对细胞产生不同的分子效应,这意味着其中一些EVs-eccDNAs可能会通过对不同器官的全身性影响加速肝衰竭的进展。总之,我们的研究提出了一种分离和表征EVs-eccDNAs的可靠方法,有助于深入了解它们在肝衰竭中与疾病相关的特征。eccDNA在HepG2细胞中激活了特定的信号通路,这意味着eccDNA在肝衰竭的发病机制中扮演了重要角色,这表明eccDNA具有作为诊断标志物和治疗干预靶点的潜力。然而,研究的局限性包括:仅使用 HepG2 细胞系来验证 eccZMIZ1-AS1 的功能,以及缺乏对其影响肝衰竭的具体机制的探索。这些方面都需要在今后的研究中进一步探讨。钱永兵、洪小宁、于洋、杜聪、陈晨、肖文军、李静、于佳颖、钟天宇和李江进行了实验工作并分析了数据。钱永兵、洪小宁、于洋、向曦和李志刚构思了数据并撰写了手稿。JCYJ20210324134612035给Z.L.,JCYJ20220530145014033给X.X.);中山大学附属第七医院科研启动基金(ZSQYBRJH0021给Z.L.,592026给X.X.);广东省消化系统肿瘤研究重点实验室(2021B1212040006给X.X.X.X.获得广东省消化系统肿瘤研究重点实验室开放基金资助(GPKLDCR202206M,X.X.获得);中山大学中央高校基本科研业务费资助(2023KYPT02,X.X.获得)。本研究的人类伦理学研究获得了上海交通大学医学院附属仁济医院伦理委员会的批准(KY2021-063-B)。
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Characterization and functional analysis of extrachromosomal circular DNA discovered from circulating extracellular vesicles in liver failure

Extrachromosomal circular DNA (eccDNA) is a mobile, circular DNA molecule that originates from but exists independently of linear chromosomes.1 Its characteristics and potential function in liver failure remain elusive. Herein, we established a reliable workflow for purifying the internal eccDNAs harboured by plasma-derived extracellular vesicles (EVs) and characterization of these EVs-eccDNAs in liver failure. Additionally, the impact of liver failure-specific circulating EVs-eccDNAs on the hepatocytes was evaluated by synthetic eccDNAs transfection and RNAseq analysis.

This study recruited 22 participants, including 13 patients with liver failure and nine healthy individuals. Detailed information is provided in Table S1 and Material S1. Patients were diagnosed with liver failure using established criteria, and their hepatic function was matched accordingly.2-4 Subsequently, we isolated plasma-derived EVs from both healthy control individuals and liver failure.5, 6 Electron microscopy images showed that both healthy control EVs (HCEVs) and liver failure patient EVs (LFEVs) exhibited the typical “cup-shaped” morphology with similar average diameters around 100 nm (Figure 1A). Nano-flow cytometry indicated that the concentration of LFEVs was significantly higher than that of HCEVs, but no significant difference in size was found (Figure 1B). Western blot analysis confirmed small EV markers CD9, CD81 and TSG101 were present, while the negative marker Mitofilin was absent (Figure 1C). Notably, LFEVs had a higher level of CD9 than HCEVs. Our data revealed an increased presence of EVs in the peripheral circulation of liver failure patients.

We then isolated eccDNA from HCEVs and LFEVs using the process illustrated in Figure 2A. Specifically, eccDNAs with > 75 bp overlap of a certain gene were defined as “eccGenes” in the study.7 The read sizes for HCEVs and LFEVs were similar (Figure 2B and Table S2). We then identified that LFEVs had a significantly higher number of eccDNAs compared to HCEVs (Figure 2C and Table S2). The normalized eccDNA count per million mapped reads (EPM) was significantly higher in LFEVs (Figure 2D). Additionally, the GC content and flanking regions of eccDNAs from LFEVs were higher than those from HCEVs (Figure 2E,F). The percentage of EPM across all chromosomes was similar for both LFEVs and HCEVs (Figure 2G, Figure S1A and Material S2). Overall, these data indicate that LFEVs carry a higher abundance of eccDNAs than HCEVs.

We then analyzed the eccDNA lengths in HCEVs and LFEVs. Figure 3A shows five enriched peaks in LFEVs at 370, 566, 751, 946 and 1124 bp, with a noticeably higher density of eccDNAs in LFEVs compared to HCEVs. We calculated the cumulative frequency of HCEVs and LFEVs containing eccDNAs and found that eccDNA lengths in LFEVs were much shorter than those in HCEVs (Figure 3B). Additionally, we found that LFEVs contained a higher ratio of 0.5–1 Kb length eccDNA but a lower ratio of > 2 Kb length eccDNA compared to HCEVs (Figure 3C). Therefore, these findings indicated that LFEVs contained eccDNA with shorter lengths than those in HCEVs. Based on the currently proposed mechanisms of eccDNA formation triggered by genomic stress,8 we speculate that this may be related to the increased stress experienced by the genome during the progression of liver failure, which leads to the formation of more and shorter eccDNA into the EVs. Then, we found 75 eccDNAs with common start-end sites in two groups (Figure 3D). As shown in Figure 3E,F, four eccDNAs were more frequently present in LFEVs than in HCEVs among these common start-end eccDNAs. Subsequently, we discovered that these four over-represented LFEVs-eccDNAs carried specific regulatory genes, transposable elements and candidate cis-regulatory elements (Figure 3F). These eccDNAs carried the genes ZMIZ1-AS1 and ZMYM6, which may further influence liver cell functions.

Using the LAMA method,7 we synthesized artificial eccDNA[chr10:78950400-78950928] and eccDNA[chr1:35004981-35005600], referred to as eccZMIZ1-AS1 and eccZMYM6, respectively (Figure 4A and Tables S3 and S4). Digestion of the linear A fragment with NdeI or SacI produced two lower DNA bands, while artificial eccZMIZ1-AS1 and eccZMYM6 showed only one higher band, indicating successful synthesis of both (Figure 4B). The synthesized eccZMIZ1-AS1, eccZMYM6 and a random control eccDNA (eccRandom) were transfected into HepG2 cells via electroporation (Figure S2A), and the cells were collected for genome-wide messenger RNA (mRNA) sequencing to assess expression changes. The RNAseq results show that 212 mRNAs upregulated and 50 mRNAs downregulated in eccZMIZ1-AS1 (Figure 4C and Material S3). However, the eccZMYM6 group exhibited no significant changes in mRNA expression (Figure 4D). Subsequently, we analyzed the Kyoto Encyclopedia of Genes and Genomes (KEGG) signalling pathways of differentially expressed genes and found that eccZMIZ1-AS1 primarily regulated the PI3K-Akt and HIF-1 signalling pathways (Figure 4E). Gene Ontology (GO) enrichment analysis showed that eccZMIZ1-AS1 primarily promotes cellular responses to hypoxia, with regulated genes mainly located in the vesicle membrane and associated with calcium-dependent phospholipid binding (Figure 4F). Finally, we found that the genes regulated by eccZMIZ1-AS1 were primarily centred around the cellular processes including response to hypoxia, regulation of lipid metabolic process and exocytic vesicle membrane (Figure 4G). Previous evidence indicated that HIF-1α mediates acute liver failure induced by LPS/D-GalN.9 Also, previous studies show that lipid metabolism influences intrahepatic macrophage reprogramming, regulating acute-on-chronic liver failure caused by the hepatitis B virus.10 Currently, no studies have established a direct link between liver failure and the exocytic vesicle membrane. These findings suggest that the liver failure-specific circulating EVs-eccDNAs may exert divergent molecular effects on cells, implying that some of them may accelerate the progression of liver failure through systemic impacts on various organs.

In conclusion, our study presents a reliable method for isolating and characterizing EVs-eccDNAs, offering insights into their disease-associated features in liver failure. The activation of specific signalling pathways by eccDNA in HepG2 cells implies its role in liver failure pathogenesis, suggesting its potential as a diagnostic marker and target for therapeutic interventions. However, limitations include the exclusive use of the HepG2 cell line to validate eccZMIZ1-AS1's functions and the lack of exploration into the specific mechanisms by which it influences liver failure. These aspects require further investigation in future studies.

Zhigang Li and Xi Xiang planned the project and conceived the experiments. Yongbing Qian, Xiaoning Hong, Yang Yu, Cong Du, Chen Chen, Wenjun Xiao, Jing Li, Jiaying Yu, Tianyu Zhong, and Jiang Li performed the experimental works and analyzed the data. Yongbing Qian, Xiaoning Hong, Yang Yu, Xi Xiang and Zhigang Li conceived the data and wrote the manuscript. All authors approved the final version of the manuscript.

The authors declare no conflict of interest.

This work was supported by the National Natural Science Foundation of China (32200638 to Z.L.); Basic and Applied Basic Research Fund of Guangdong Province (2021A1515110512 to Z.L., 2023A1515010090 to Z.L. and 2022A1515110137 to Y.Y.); Shenzhen Science and Technology Innovation Program (JCYJ20230807110316034 to Z.L., JCYJ20210324134612035 to Z.L. and JCYJ20220530145014033 to X.X.); Research Start-up Fund of the Seventh Affiliated Hospital of Sun Yat-sen University (ZSQYBRJH0021 to Z.L. and 592026 to X.X.); Guangdong Provincial Key Laboratory of Digestive Cancer Research (2021B1212040006 to X.X.); The Open Fund of Guangdong Provincial Key Laboratory of Digestive Cancer Research (GPKLDCR202206M to X.X.); Fundamental Research Funds for the Central Universities of Sun Yat-sen University (Grant 2023KYPT02 to X.X.).

All subjects gave their informed consent for inclusion before they participated in the study. The human ethics of this study was approved by Shanghai Jiao Tong University School of Medicine, Renji Hospital Ethics Committee (KY2021-063-B).

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来源期刊
CiteScore
15.90
自引率
1.90%
发文量
450
审稿时长
4 weeks
期刊介绍: Clinical and Translational Medicine (CTM) is an international, peer-reviewed, open-access journal dedicated to accelerating the translation of preclinical research into clinical applications and fostering communication between basic and clinical scientists. It highlights the clinical potential and application of various fields including biotechnologies, biomaterials, bioengineering, biomarkers, molecular medicine, omics science, bioinformatics, immunology, molecular imaging, drug discovery, regulation, and health policy. With a focus on the bench-to-bedside approach, CTM prioritizes studies and clinical observations that generate hypotheses relevant to patients and diseases, guiding investigations in cellular and molecular medicine. The journal encourages submissions from clinicians, researchers, policymakers, and industry professionals.
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