人体肠道病毒组学研究进展

人体微生物组计划开展近10年来,大量的研究显示人体微生物通过各种方式深刻地影响着人体健康。人体肠道内丰富多样的病毒构成了肠道病毒组,是人体微生物组的重要组成部分,和人体健康密切相关。本文综述了近些年国际上人体肠道病毒组研究的最新进展,分别从人体肠道病毒组的组成特征、肠道病毒组-细菌组-人体间的相互作用及其对人体健康的影响、病毒组研究的技术策略及挑战等方面进行了论述,探讨了肠道病毒组在人体疾病预防和治疗领域应用的可行性。     

Viral metagenomics analysis of feces from coronary heart disease patients reveals the genetic diversity of the Microviridae

Recent studies have declared that members of the ss DNA virus family Microviridae play an important role in multiple environments, as they have been found taking a dominant position in the human gut. The aim of this study was to analyze the overall composition of the gut virome in coronary heart disease(CHD) patients, and try to discover the potential link between the human gut virome and CHD. Viral metagenomics methods were performed to detect the viral sequences in fecal samples collected from CHD inpatients and healthy persons as controls. We present the analysis of the virome composition in these CHD patients and controls. Our data shows that the virome composition may be linked to daily living habits and the medical therapy of CHD.Virgaviridae and Microviridae were the two dominant types of viruses found in the enteric virome of CHD patients. Fourteen divergent viruses belonging to the family Microviridae were found, twelve of which were grouped into the subfamily Gokushovirinae, while the remaining two strains might represent two new subfamilies within Microviridae, according to the phylogenetic analysis. In addition, the genomic organization of these viruses has been characterized.     

Human retroviral env and gag polypeptides: serologic assays to measure infection

Humoral antiviral responses to human retrovirus infections identify persistently infected individuals and can be used to characterize virus-host interactions. Antibodies to native viral polypeptides have been reliably measured, although quantitation of env antibodies is difficult due to a lack of purified antigens. To quantitate antibodies to env antigens, bacterially expressed cloned env polypeptides from the transmembrane regions of human T lymphotropic virus types I and III were applied to nitrocellulose filters in an immunodot assay. A combination of the sensitivity of the Western blot procedure and the specificity of peptides from defined viral sequences was used to detect 49/49 HTLV-III/LAV-infected individuals previously defined as seropositive by radioimmunoprecipitation sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Of these HTLV-III/LAV envelope seropositive people, 22% lacked antibody to p24 in a radioimmunoassay. In contrast, the sensitivity of antibody detection to HTLV-I env antigens and p24 were comparable. Antibodies to HTLV-I and HTLV-III/LAV env transmembrane peptides were not cross-reactive. Levels of antibody to env antigens of both HTLV-I and HTLV-III/LAV persisted without change for at least 26 mo, suggesting that most infections represent stable virus-host interactions. The use of bacterially expressed env peptides offers a rapid serologic approach for distinguishing human retroviral infections and can be used to define immune responses to specific regions of the viral genome.     

Environmental bacteriophage-host interactions: factors contribution to natural transduction

Over the past two decades the potential for the exchange of bacterial genes in natural environments through transduction (bacteriophage-mediated gene transfer) has been well established. Studies carried out by various laboratories throughout the world have demonstrated that both chromosomal and plasmid DNA can be successfully transduced in natural environments ranging from sewer plants to rivers and lakes. Transduction has been shown to take place in the gills of oysters and the kidneys of mice. Model studies have demonstrated the ability of transduction to maintain genetic material in bacterial gene pools that would otherwise be lost because of negative fitness. Thus, transduction may affect the course of bacterial evolution. Identification of natural transduction has led to the investigation of the dynamics of bacteriophage host interactions in natural aquatic environments and to the exploration of various environmental factors that affect virus-host interactions. Two important environmental factors which affect virus-host interactions are the metabolic state of the host and the exposure of the host to DNA-damaging stresses such as solar UV light. Recent researches on these two areas of virus-host relationships are reviewed.     

Genome-virome interactions: examining the role of common viral infections in complex disease

New technologies have widened our view of 'complex diseases': those with both genetic and environmental risk factors. In this Review, we explore recent genetic and virological evidence implicating host-virus interactions in three diseases: type 1 diabetes, inflammatory bowel disease and asthma. The viruses implicated in these diseases cause mucosal infections that affect most of the population but are asymptomatic or mild in many hosts. These findings place a new emphasis on common viral infections as important environmental factors in the pathogenesis of complex diseases, and they compel the field to pursue a better understanding of host interactions with the human virome.     

Poxvirus Proteomics and Virus-Host Protein Interactions

Summary: Studies of the functional proteins encoded by the poxvirus genome provide information about the composition of the virus as well as individual virus-virus protein and virus-host protein interactions, which provides insight into viral pathogenesis and drug discovery. Widely used proteomic techniques to identify and characterize specific protein-protein interactions include yeast two-hybrid studies and coimmunoprecipitations. Recently, various mass spectrometry techniques have been employed to identify viral protein components of larger complexes. These methods, combined with structural studies, can provide new information about the putative functions of viral proteins as well as insights into virus-host interaction dynamics. For viral proteins of unknown function, identification of either viral or host binding partners provides clues about their putative function. In this review, we discuss poxvirus proteomics, including the use of proteomic methodologies to identify viral components and virus-host protein interactions. High-throughput global protein expression studies using protein chip technology as well as new methods for validating putative protein-protein interactions are also discussed.     

Proteome analysis of plant-virus interactome: comprehensive data for virus multiplication inside their hosts

Known host-parasite molecular interactions are widespread among parasite families, but these interactions have to be particularly large considering that viruses generally encode few proteins. Although some particular virus-host interactions are well described, no global study has yet shown multiple and simultaneous interactions in a host-parasite biological system. To prove that these multiple interactions occur in biological conditions, the complexes formed by a plant virus (rice yellow mottle virus) and the proteins of its natural host (rice) were extracted and purified from infected tissue sample. Remarkably mass spectrometry permitted the identification of a large number of proteins from the complexes that are involved in different functions not encoded by the virus but probably essential for its biological life cycle. This recruiting of proteins was strongly confirmed by the repetition of experiments using different pairs of virus-host and the use of high salt concentration to extract the complexes. We mainly identified proteins involved in plant defense, metabolism, translation, and protein synthesis and some proteins involved in transport. This study demonstrates that viruses are able to recruit many proteins from their hosts to ensure their development. Among different pairs of virus-host, similar protein functions were identified suggesting a particular importance of these proteins for viruses. The identification of particular paralog proteins among multigenic families suggests the high specificity of the recruiting for some protein functions.     

肠道病毒组在疾病中的治疗潜力及其机制研究进展

肠道病毒组是人体肠道微生态系统中的重要组成部分。近年来,肠道微生态与疾病的关系受到广泛关注,越来越多的证据表明粪菌移植过程中病毒组的转移对粪菌移植的疗效起到了不可忽视的作用。本文根据近些年的相关研究,综述粪菌移植中肠道病毒组在疾病中的治疗潜力,总结肠道病毒组在疾病治疗中的可能机制,同时对肠道病毒组在未来疾病治疗中的应用作出展望。     

Characterization of the viral microbiome in patients with severe lower respiratory tract infections, using metagenomic sequencing

The human respiratory tract is heavily exposed to microorganisms. Viral respiratory tract pathogens, like RSV, influenza and rhinoviruses cause major morbidity and mortality from respiratory tract disease. Furthermore, as viruses have limited means of transmission, viruses that cause pathogenicity in other tissues may be transmitted through the respiratory tract. It is therefore important to chart the human virome in this compartment. We have studied nasopharyngeal aspirate samples submitted to the Karolinska University Laboratory, Stockholm, Sweden from March 2004 to May 2005 for diagnosis of respiratory tract infections. We have used a metagenomic sequencing strategy to characterize viruses, as this provides the most unbiased view of the samples. Virus enrichment followed by 454 sequencing resulted in totally 703,790 reads and 110,931 of these were found to be of viral origin by using an automated classification pipeline. The snapshot of the respiratory tract virome of these 210 patients revealed 39 species and many more strains of viruses. Most of the viral sequences were classified into one of three major families; Paramyxoviridae, Picornaviridae or Orthomyxoviridae. The study also identified one novel type of Rhinovirus C, and identified a number of previously undescribed viral genetic fragments of unknown origin.     

Virus-host interactions: new insights from the small RNA world

RNA silencing has a known role in the antiviral responses of plants and insects. Recent evidence, including the finding that the Tat protein of human immunodeficiency virus (HIV) can suppress the host's RNA-silencing pathway and may thus counteract host antiviral RNAs, suggests that RNA-silencing pathways could also have key roles in mammalian virus-host interactions.     

Metagenomic Exploration of Viruses throughout the Indian Ocean

The characterization of global marine microbial taxonomic and functional diversity is a primary goal of the Global Ocean Sampling Expedition. As part of this study, 19 water samples were collected aboard the Sorcerer II sailing vessel from the southern Indian Ocean in an effort to more thoroughly understand the lifestyle strategies of the microbial inhabitants of this ultra-oligotrophic region. No investigations of whole virioplankton assemblages have been conducted on waters collected from the Indian Ocean or across multiple size fractions thus far. Therefore, the goals of this study were to examine the effect of size fractionation on viral consortia structure and function and understand the diversity and functional potential of the Indian Ocean virome. Five samples were selected for comprehensive metagenomic exploration; and sequencing was performed on the microbes captured on 3.0-, 0.8- and 0.1 µm membrane filters as well as the viral fraction (<0.1 µm). Phylogenetic approaches were also used to identify predicted proteins of viral origin in the larger fractions of data from all Indian Ocean samples, which were included in subsequent metagenomic analyses. Taxonomic profiling of viral sequences suggested that size fractionation of marine microbial communities enriches for specific groups of viruses within the different size classes and functional characterization further substantiated this observation. Functional analyses also revealed a relative enrichment for metabolic proteins of viral origin that potentially reflect the physiological condition of host cells in the Indian Ocean including those involved in nitrogen metabolism and oxidative phosphorylation. A novel classification method, MGTAXA, was used to assess virus-host relationships in the Indian Ocean by predicting the taxonomy of putative host genera, with Prochlorococcus, Acanthochlois and members of the SAR86 cluster comprising the most abundant predictions. This is the first study to holistically explore virioplankton dynamics across multiple size classes and provides unprecedented insight into virus diversity, metabolic potential and virus-host interactions.     

The human papillomavirus 16 E6 protein can either protect or further sensitize cells to TNF: effect of dose

High-risk strains of human papillomavirus, including HPV 16, cause human cervical carcinomas, due in part to the activity of their E6 oncogene. E6 interacts with a number of cellular proteins involved in host-initiated apoptotic responses. Paradoxically, literature reports show that E6 can both protect cells from and sensitize cells to tumor necrosis factor (TNF). To examine this apparent contradiction, E6 was transfected into U2OS cells and stable clones were treated with TNF. Intriguingly, clones with a high level of E6 expression displayed an increased sensitivity to TNF by undergoing apoptosis, while those with low expression were resistant. Furthermore, TNF treatment of cells in which the expression of E6 was regulated by the addition of doxycycline demonstrated clearly that while low levels of E6 protect cells from TNF, high levels sensitize cells. Together, these results demonstrate that virus-host interactions can be complex and that both quantitative and qualitative aspects are important in determining outcome.     

Functional similarity analysis of human virus-encoded miRNAs

miRNAs are a class of small RNAs that regulate gene expression via RNA silencing machinery. Some viruses also encode miRNAs, contributing to the complex virus-host interactions. A better understanding of viral miRNA functions would be useful in designing new preventive strategies for treating diseases induced by viruses. To meet the challenge for how viruses module host gene expression by their encoded miRNAs, we measured the functional similarities among human viral miRNAs by using a method we reported previously. Higher order functions regulated by viral miRNAs were also identified by KEGG pathway analysis on their targets. Our study demonstrated the biological processes involved in virus-host interactions via viral miRNAs. Phylogenetic analysis suggested that viral miRNAs have distinct evolution rates compared with their corresponding genome.     

The viral killer system in yeast: from molecular biology to application

Since the initial discovery of the yeast killer system almost 40 years ago, intensive studies have substantially strengthened our knowledge in many areas of biology and provided deeper insights into basic aspects of eukaryotic cell biology as well as into virus-host cell interactions and general yeast virology. Analysis of killer toxin structure, synthesis and secretion has fostered understanding of essential cellular mechanisms such as post-translational prepro-protein processing in the secretory pathway. Furthermore, investigation of the receptor-mediated mode of toxin action proved to be an effective means for dissecting the molecular structure and in vivo assembly of yeast and fungal cell walls, providing important insights relevant to combating infections by human pathogenic yeasts. Besides their general importance in understanding eukaryotic cell biology, killer yeasts, killer toxins and killer viruses are also becoming increasingly interesting with respect to possible applications in biomedicine and gene technology. This review will try to address all these aspects.     

Viruses and interactomes in translation

A decade of high-throughput screenings for intraviral and virus-host protein-protein interactions led to the accumulation of data and to the development of theories on laws governing interactome organization for many viruses. We present here a computational analysis of intraviral protein networks (EBV, FLUAV, HCV, HSV-1, KSHV, SARS-CoV, VACV, and VZV) and virus-host protein networks (DENV, EBV, FLUAV, HCV, and VACV) from up-to-date interaction data, using various mathematical approaches. If intraviral networks seem to behave similarly, they are clearly different from the human interactome. Viral proteins target highly central human proteins, which are precisely the Achilles' heel of the human interactome. The intrinsic structural disorder is a distinctive feature of viral hubs in virus-host interactomes. Overlaps between virus-host data sets identify a core of human proteins involved in the cellular response to viral infection and in the viral capacity to hijack the cell machinery for viral replication. Host proteins that are strongly targeted by a virus seem to be particularly attractive for other viruses. Such protein-protein interaction networks and their analysis represent a powerful resource from a therapeutic perspective.     

Quantitative four-dimensional tracking of cytoplasmic and nuclear HIV-1 complexes

Emerging real-time techniques for imaging viral infections provide powerful tools for understanding the dynamics of virus-host cell interactions. Here we labeled human immunodeficiency virus-1 (HIV-1) integrase with a small tetracysteine tag, which preserved the virus' infectivity while allowing it to be labeled with the bis-arsenical fluorescein derivative FlAsH. This labeling allowed us to image both intracytoplasmic and intranuclear HIV-1 complexes in three dimensions over time (4D) in human cells and enabled us to analyze HIV-1 kinetics by automated 4D quantitative particle tracking. In the cytoplasm, HIV-1 complexes underwent directed movements toward the nuclear compartment, kinetically characteristic of both microtubule- and actin-dependent transport. The complexes then adopted smaller movements in a very confined volume once associated with the nuclear membrane and more diffuse movements once inside the nucleus. This work contributes new insight into the various movements of HIV-1 complexes within infected cells and provides a useful tool for the study of virus-host cell interactions during infection.     

病毒组研究：微生物组研究新热点

病毒组是指分布在各种环境中病毒的集合或病毒宏基因组的统称。病毒可以分布于水体、冰川、动植物甚至某些病毒当中,主要分为真核病毒、原核病毒和亚病毒。其在维持环境内稳态、生态系统平衡等方面起着非常重要的作用,并且与人类的健康密切相关。近年来,随着测序技术和数据分析水平的进步,人们能够采用宏基因组测序的方式研究病毒组并探究其在生态位中的潜在作用。人们在冰川、海洋、各种动植物中都得到了大量的病毒组数据,发现了众多未知病毒。人们研究病毒组主要是通过宏基因组数据挖掘和病毒样粒子 (Virus-like particles,VLPs) 分离富集测序两种方式进行分析处理。迄今为止,已存在多种不同的病毒组分离富集方法,并且针对病毒组的生物信息分析也数不胜数。然而,针对病毒组的富集和数据分析方法还缺少具体、完整的综述。文中将对病毒组的分离富集方法和数据分析进行整理与总结,并列举出部分采用病毒组分离富集方法进行的重要研究,旨在为相关人员提供参考,进一步促进病毒组研究领域的发展。     

Measures and countermeasures in the modulation of initiation factor activities by viruses

Animal viruses have co-evolved with their hosts for millions of years. During this time, the viruses have developed intricate mechanisms to utilize efficiently their host's metabolic pathways, especially those involving macromolecular synthesis, for virus propagation. In particular, many different viruses modulate and usurp their host's translational machinery for use in the synthesis of their own proteins. However, the infected hosts have developed or adapted cellular mechanisms to interdict virus infection. One of these mechanisms is the interferon response, which entails in part a translational regulatory activity that inhibits virus growth. Viruses, in turn, have devised strategies that act as countermeasures to some aspects of the interferon response. These complex virus-host interactions occur at the level of initiation of translation. Two initiation factors, eIF-2 and eIF-4F, play a significant role in a number of virus-host interactions. The recent advances in our understanding of the mode of action of these translation initiation factors have facilitated research on virus-cell interactions at the level of translation. This review is not intended to summarize the general knowledge in this field, but rather to limit the analysis to several examples of virus-host interactions and to speculate on the interplay between the molecular mechanisms involved in these phenomena.