{"title":"黑质下噬菌体的发现及其对帕金森病的影响","authors":"Yun Zhao, Changxian Xiong, Bingwei Wang, Daotong Li, Jiarui Liu, Shizhang Wei, Yujia Hou, Yuan Zhou, Ruimao Zheng","doi":"10.1101/2024.07.13.603353","DOIUrl":null,"url":null,"abstract":"Background: A century ago, a mystery between virus and Parkinson’s disease (PD) was described. Owing to the limitation of human brain biopsy and the challenge of electron microscopy in observing virions in human brain tissue, it has been difficult to study the viral etiology of PD. Recent discovery of virobiota reveals that viruses coexist with humans as symbionts. Newly-developed transcriptomic sequencing and novel bioinformatic approaches for mining the encrypted virome in human transcriptome make it possible to study the relationship between symbiotic viruses and PD. Nevertheless, whether viruses exist in the human substantial nigra (SN), and whether symbiotic viruses underlie PD pathogenesis remain unknown. Methods: We collected current worldwide human SN transcriptomic datasets from the United States, the United Kingdom, the Netherlands and Switzerland. We used bioinformatic approaches including viruSITE and the Virus-Track to identify the existence of viruses in the SN of patients. The comprehensive RNA sequencing-based virome analysis pipeline was used to characterize the virobiota in the SN. The Pearson’s correlation analysis was used to examine the association between the viral RNA fragment counts (VRFC) and PD-related human gene sequencing reads in the SN. The differentially expressed genes (DEGs) in the SN between PD patients and non-PD individuals were used to examine the molecular signatures of PD and also evaluate the impact of symbiotic viruses on the SN. Findings: We observed the existence of viruses in the human SN. A dysbiosis of virobiota was found in the SN of PD patients. A significant correlation between VRFC and PD-related human gene expression was detected in the SN of PD patients. These PD-related human genes correlated to VRFC were named as the virus-correlated PD-related genes (VPGs). We identified three bacteriophages (phages), including the Proteus phage VB_PmiS-Isfahan, the Escherichia phage phiX174 and the Lactobacillus phage Sha1, that might impair the gene expression of neural cells in the SN of PD patients. The Proteus phage VB_PmiS-Isfahan was a common virus in the SN of patients from the UK, the Netherlands, and Switzerland. VPGs and DEGs together highlighted that the phages might dampen dopamine biosynthesis and weaken cGAS-STING function. Interpretation: This is the first study to discover the involvement of phages in PD pathogenesis. A life-long low symbiotic viral load in the SN may be a contributor to PD pathogenesis. Our findings unlocked the black box between brain virobiota and PD, providing a novel insight into PD etiology from the perspective of phages-human symbiosis.","PeriodicalId":9124,"journal":{"name":"bioRxiv","volume":"87 21","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-07-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"The discovery of phages in the Substantia Nigra and its implication for Parkinson’s Disease\",\"authors\":\"Yun Zhao, Changxian Xiong, Bingwei Wang, Daotong Li, Jiarui Liu, Shizhang Wei, Yujia Hou, Yuan Zhou, Ruimao Zheng\",\"doi\":\"10.1101/2024.07.13.603353\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Background: A century ago, a mystery between virus and Parkinson’s disease (PD) was described. Owing to the limitation of human brain biopsy and the challenge of electron microscopy in observing virions in human brain tissue, it has been difficult to study the viral etiology of PD. Recent discovery of virobiota reveals that viruses coexist with humans as symbionts. Newly-developed transcriptomic sequencing and novel bioinformatic approaches for mining the encrypted virome in human transcriptome make it possible to study the relationship between symbiotic viruses and PD. Nevertheless, whether viruses exist in the human substantial nigra (SN), and whether symbiotic viruses underlie PD pathogenesis remain unknown. Methods: We collected current worldwide human SN transcriptomic datasets from the United States, the United Kingdom, the Netherlands and Switzerland. We used bioinformatic approaches including viruSITE and the Virus-Track to identify the existence of viruses in the SN of patients. The comprehensive RNA sequencing-based virome analysis pipeline was used to characterize the virobiota in the SN. The Pearson’s correlation analysis was used to examine the association between the viral RNA fragment counts (VRFC) and PD-related human gene sequencing reads in the SN. The differentially expressed genes (DEGs) in the SN between PD patients and non-PD individuals were used to examine the molecular signatures of PD and also evaluate the impact of symbiotic viruses on the SN. Findings: We observed the existence of viruses in the human SN. A dysbiosis of virobiota was found in the SN of PD patients. A significant correlation between VRFC and PD-related human gene expression was detected in the SN of PD patients. These PD-related human genes correlated to VRFC were named as the virus-correlated PD-related genes (VPGs). We identified three bacteriophages (phages), including the Proteus phage VB_PmiS-Isfahan, the Escherichia phage phiX174 and the Lactobacillus phage Sha1, that might impair the gene expression of neural cells in the SN of PD patients. The Proteus phage VB_PmiS-Isfahan was a common virus in the SN of patients from the UK, the Netherlands, and Switzerland. VPGs and DEGs together highlighted that the phages might dampen dopamine biosynthesis and weaken cGAS-STING function. Interpretation: This is the first study to discover the involvement of phages in PD pathogenesis. A life-long low symbiotic viral load in the SN may be a contributor to PD pathogenesis. 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引用次数: 0
摘要
背景:一个世纪前,病毒与帕金森病(PD)之间的神秘关系被描述出来。由于人脑活检的局限性和电子显微镜观察人脑组织中病毒的挑战性,研究帕金森病的病毒病因一直很困难。最近发现的病毒生物群揭示了病毒作为共生体与人类共存。新开发的转录组测序技术和挖掘人类转录组中加密病毒组的新型生物信息学方法使研究共生病毒与帕金森病之间的关系成为可能。然而,病毒是否存在于人类黑质(SN)中,以及共生病毒是否是白内障发病机制的基础仍是未知数。方法:我们从美国、英国、荷兰和瑞士收集了当前全球人类SN转录组数据集。我们使用生物信息学方法(包括 viruSITE 和 Virus-Track)来确定患者 SN 中是否存在病毒。基于 RNA 测序的病毒组综合分析管道用于描述 SN 中的病毒生物群特征。皮尔逊相关性分析用于研究SN中病毒RNA片段计数(VRFC)与PD相关人类基因测序读数之间的关联。利用腹股沟淋巴结核患者与非腹股沟淋巴结核患者之间的差异表达基因(DEGs)来研究腹股沟淋巴结核的分子特征,同时评估共生病毒对腹股沟淋巴结核的影响。研究结果我们观察到人类SN中存在病毒。在帕金森氏症患者的SN中发现了病毒群的菌群失调。在帕金森氏症患者的SN中发现了VRFC与帕金森氏症相关人类基因表达之间的明显相关性。这些与 VRFC 相关的 PD 相关人类基因被命名为与病毒相关的 PD 相关基因(VPGs)。我们发现了三种噬菌体(包括变形杆菌噬菌体VB_PmiS-Isfahan、埃希氏菌噬菌体phiX174和乳酸杆菌噬菌体Sha1)可能会损害PD患者SN中神经细胞的基因表达。变形杆菌噬菌体VB_PmiS-Isfahan是英国、荷兰和瑞士患者SN中的常见病毒。VPGs和DEGs共同表明,噬菌体可能会抑制多巴胺的生物合成并削弱cGAS-STING的功能。解读:这是首次发现噬菌体参与帕金森病发病机制的研究。SN中终生低共生病毒载量可能是导致帕金森病发病的一个因素。我们的研究结果揭开了脑部生物群与帕金森病之间的黑匣子,从噬菌体与人类共生的角度为帕金森病的病因学提供了新的见解。
The discovery of phages in the Substantia Nigra and its implication for Parkinson’s Disease
Background: A century ago, a mystery between virus and Parkinson’s disease (PD) was described. Owing to the limitation of human brain biopsy and the challenge of electron microscopy in observing virions in human brain tissue, it has been difficult to study the viral etiology of PD. Recent discovery of virobiota reveals that viruses coexist with humans as symbionts. Newly-developed transcriptomic sequencing and novel bioinformatic approaches for mining the encrypted virome in human transcriptome make it possible to study the relationship between symbiotic viruses and PD. Nevertheless, whether viruses exist in the human substantial nigra (SN), and whether symbiotic viruses underlie PD pathogenesis remain unknown. Methods: We collected current worldwide human SN transcriptomic datasets from the United States, the United Kingdom, the Netherlands and Switzerland. We used bioinformatic approaches including viruSITE and the Virus-Track to identify the existence of viruses in the SN of patients. The comprehensive RNA sequencing-based virome analysis pipeline was used to characterize the virobiota in the SN. The Pearson’s correlation analysis was used to examine the association between the viral RNA fragment counts (VRFC) and PD-related human gene sequencing reads in the SN. The differentially expressed genes (DEGs) in the SN between PD patients and non-PD individuals were used to examine the molecular signatures of PD and also evaluate the impact of symbiotic viruses on the SN. Findings: We observed the existence of viruses in the human SN. A dysbiosis of virobiota was found in the SN of PD patients. A significant correlation between VRFC and PD-related human gene expression was detected in the SN of PD patients. These PD-related human genes correlated to VRFC were named as the virus-correlated PD-related genes (VPGs). We identified three bacteriophages (phages), including the Proteus phage VB_PmiS-Isfahan, the Escherichia phage phiX174 and the Lactobacillus phage Sha1, that might impair the gene expression of neural cells in the SN of PD patients. The Proteus phage VB_PmiS-Isfahan was a common virus in the SN of patients from the UK, the Netherlands, and Switzerland. VPGs and DEGs together highlighted that the phages might dampen dopamine biosynthesis and weaken cGAS-STING function. Interpretation: This is the first study to discover the involvement of phages in PD pathogenesis. A life-long low symbiotic viral load in the SN may be a contributor to PD pathogenesis. Our findings unlocked the black box between brain virobiota and PD, providing a novel insight into PD etiology from the perspective of phages-human symbiosis.