ABSTRACT
Measles is a human infectious disease of global concern that is caused by the measles virus. In this study, we report the complete genome sequencing of one measles virus isolate, genotype D8, that was obtained directly from a urine sample in Boa Vista city, the capital of Roraima state in Brazil. Phylogenetic reconstruction grouped the genome described in this study with that of samples from Australia, South Korea, and Italy. To our knowledge, this is the first complete genome sequence of a wild-type measles virus reported from Latin America. Therefore, the present data strengthen the current knowledge on the molecular epidemiology of measles worldwide.
Subject(s)
Humans , Genotype , Measles virus , Brazil/epidemiologyABSTRACT
Zika virus (ZIKV) is an enveloped RNA virus belonging to the genus Flavivirus, family Flaviviridae, which can be transmitted to humans by Aedes spp. mosquitoes. The virus was first identified in Uganda in 1947 in rhesus monkeys. Hereafter, Zika virus disease has been recorded in Africa, the Americas, Asia and the Pacific. The outbreak of this epidemic began in 2015 in Brazil, and has spread rapidly to other countries. Clinical features of ZIKV infection range from asymptomatic cases to an influenza-like syndrome associated with fever, cutaneous rash, arthralgia, and conjunctivitis. Current observational studies suggest that ZIKV may cause more severe neurological sequelae such as Guillain-Barré syndrome and birthdefects, mainly microcephaly. The diagnosis is confirmed by viral RNA detection by genomic amplification (real-time PCR) and serological detection of IgM. Up to now, there is neither a vaccine nor prophylactic medications available to prevent and treat ZIKV infection. The effective prevention is protection against mosquito bites and to improve self-protection awareness. In this paper we summarized the epidemiology, biology, pathogenesis and detection of Zika virus, hoping to benefit the control of ongoing outbreaks as well as the development of vaccines and therapeutics.
ABSTRACT
Objective To find out the physical state of the human papillomavirus ( HPV) genome in hepatoma cell line HepG2 cells and the regulation of HPV late capsid protein 1 ( L1) expression and to explore the nature of the cytoryctes in HepG2 cells.Methods E2 and E6 in HPV18 were detected by PCR to evaluate the physical state of HPV18 genome .HepG2 L1 expression was detected by ELISA , light microscropy and electron microscrope immu-nohistochemistry assays , Western blot assay using HPV L 1 mice monoclonal antibody .L1 mRNA in HepG2 cells was detected by reverse transcriptional PCR ( RT-PCR) .Results PCR assay displayed that HPV DNA was inte-grated with HepG2 genome.ELISA assay showed that HPV L1 was present in lysate of HepG2 cells.Light micros-cropy demonstrated strong positive reaction in HepG2 cells.In microscopy, in the cytoplasm of partial HepG2 cells, there were lumpish cytorrhyctes materials which consists of very small and uniform particles and these parti -cles were marked by HPV L1 antibody labeled by colloidal gold .Western blot analysis showed a band at 56 ku dis-trict and it was L1 specific strap which demonstrated HPV 18 L1 was present in HepG2 cells.RT-PCR assay demon-strated the presence of L1 mRNA in HepG2 cells.Conclusions HepG2 cells are HPV18-positive HPV DNA ge-nome is integrated with HepG2 cells.HepG2 cells can express L1.The cytorrhyctes in HepG2 cells are composed of HPV18 L1 indicating that L1 can be expressed in HepG2.
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Objective To determine the maintenance and loss of Epstein-Barr virus (EBV) genome during the clonal expansion of the EBV-infected epithelial cells. Methods The epithelial tumor cell line, 293-EBV, in which the EBV genome was observed with green fluorescent protein (GFP) readout. After a dozen of passages, it contained cells with strong or weak GFP expression, and some with complete loss of EBV genome. The cell growth was then continuously observed under a confocal microscope. The cell dividing and GFP expression were also observed during the clonal expansion by being made into very low density. Results The cells moved around due to adherence and mobility, while the GFP expression remained unchanged in the undivided cells. The cells could form compact or loosen clones. The EBV genome easily persisted in those clones when cells were growing compactly. As the cell number increased, the GFP expression became weak or even died away at the sites of low density in the loosen clones. Conclusion EBV-positive epithelial cells are able to sustain the EBV genome during its clonal expansion. The cells maintain EBV genomes by passing them to the daughter cells after replication. When the cells unsuccessfully inherit the EBV genome, the daughter cells may lose them which is related to the low cell density as well as the epithelial environment.
ABSTRACT
The genetic analysis of herpesviruses has been a constant challenge, due to the large, complex genomes of herpesviruses and mutagenesis of viral genes by conventional recombination methods in cell culture. Recently, a completely new approach for full-length infectious clones of herpesviruses based on bacterial artificial chromosomes (BACs) has been developed. This technique allows the maintenance, propagation and genetic modification of the viral genome as a BAC plasmid in E.coli, thus making the procedures fast, safe and effective in prokaryotic cells. This technique also makes it possible for the reconstitution of viral progeny or mutants by transfection of the BAC plasmid into eukaryotic cells, thereby facilitating the analysis of viral gene functions in the context of genome. In this presentation, Epstein-Barr virus was used as an example to describe the principle, establishment of the technique and mutation introduction into the BAC plasmid, and to discuss the perspective in the use of BAC-cloned herpesviruses.