Over the last 30 years,aquaculture has become the fastest growing form of agriculture production in the world,but its development has been hampered by a diverse range of pathogenic viruses.During the last decade,a lar...Over the last 30 years,aquaculture has become the fastest growing form of agriculture production in the world,but its development has been hampered by a diverse range of pathogenic viruses.During the last decade,a large number of viruses from aquatic animals have been identified,and more than 100 viral genomes have been sequenced and genetically characterized.These advances are leading to better understanding about antiviral mechanisms and the types of interaction occurring between aquatic viruses and their hosts.Here,based on our research experience of more than 20 years,we review the wealth of genetic and genomic information from studies on a diverse range of aquatic viruses,including iridoviruses,herpesviruses,reoviruses,and rhabdoviruses,and outline some major advances in our understanding of virus–host interactions in animals used in aquaculture.展开更多
Micro RNAs(mi RNAs) are small noncoding RNAs. More than 2500 mature mi RNAs are detected in plants, animals and several types of viruses. Hepatitis C virus(HCV), which is a positive-sense, singlestranded RNA virus, do...Micro RNAs(mi RNAs) are small noncoding RNAs. More than 2500 mature mi RNAs are detected in plants, animals and several types of viruses. Hepatitis C virus(HCV), which is a positive-sense, singlestranded RNA virus, does not encode viral mi RNA. However, HCV infection alters the expression of host mi RNAs, either in cell culture or in patients with liver disease progression, such as liver fibrosis, cirrhosis, and hepatocellular carcinoma. In turn, host mi RNAs regulate HCV life cycle through directly binding to HCV RNAs or indirectly targeting cellular m RNAs. Increasing evidence demonstrates that mi RNAs are one of the centered factors in the interaction network between virus and host. The competitive viral and host RNA hypothesis proposes a latent cross-regulation pattern between host m RNAs and HCV RNAs. High loads of HCV RNA sequester and de-repress host mi RNAs from their normal host targets and thus disturb host gene expression, indicating a means of adaptation for HCV to establish a persistent infection. Some special mi RNAs are closely correlated with liver-specific disease progression and the changed levels of mi RNAs are even higher sensitivity and specificity than those of traditional proteins. Therefore, some of them can serve as novel diagnostic/prognostic biomarkers in HCVinfected patients with liver diseases. They are also attractive therapeutic targets for development of new anti-HCV agents.展开更多
基金supported by grants from the National Natural Science Foundation of China(31430091)the National Key Basic Research Program(2010CB126303)the Project of State Key Laboratory of Freshwater Ecology and Biotechnology(2011FBZ12)
文摘Over the last 30 years,aquaculture has become the fastest growing form of agriculture production in the world,but its development has been hampered by a diverse range of pathogenic viruses.During the last decade,a large number of viruses from aquatic animals have been identified,and more than 100 viral genomes have been sequenced and genetically characterized.These advances are leading to better understanding about antiviral mechanisms and the types of interaction occurring between aquatic viruses and their hosts.Here,based on our research experience of more than 20 years,we review the wealth of genetic and genomic information from studies on a diverse range of aquatic viruses,including iridoviruses,herpesviruses,reoviruses,and rhabdoviruses,and outline some major advances in our understanding of virus–host interactions in animals used in aquaculture.
基金Supported by National Natural Science Foundation of China No.81321004 and No.81322050National Mega-Project for“R&D for Innovative Drugs”+3 种基金Ministry of Science and TechnologyChina No.2012ZX09301-002-001Ministry of EducationChina No.NCET-12-0072
文摘Micro RNAs(mi RNAs) are small noncoding RNAs. More than 2500 mature mi RNAs are detected in plants, animals and several types of viruses. Hepatitis C virus(HCV), which is a positive-sense, singlestranded RNA virus, does not encode viral mi RNA. However, HCV infection alters the expression of host mi RNAs, either in cell culture or in patients with liver disease progression, such as liver fibrosis, cirrhosis, and hepatocellular carcinoma. In turn, host mi RNAs regulate HCV life cycle through directly binding to HCV RNAs or indirectly targeting cellular m RNAs. Increasing evidence demonstrates that mi RNAs are one of the centered factors in the interaction network between virus and host. The competitive viral and host RNA hypothesis proposes a latent cross-regulation pattern between host m RNAs and HCV RNAs. High loads of HCV RNA sequester and de-repress host mi RNAs from their normal host targets and thus disturb host gene expression, indicating a means of adaptation for HCV to establish a persistent infection. Some special mi RNAs are closely correlated with liver-specific disease progression and the changed levels of mi RNAs are even higher sensitivity and specificity than those of traditional proteins. Therefore, some of them can serve as novel diagnostic/prognostic biomarkers in HCVinfected patients with liver diseases. They are also attractive therapeutic targets for development of new anti-HCV agents.