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Humanity is constantly confronted with the emergence and reemergence of infectious diseases. Many of them produce large or devastating epidemics, like AIDS (HIV) and Ebola. Others have been long neglected, yet pose immediate threats to global public health as evidences the abrupt emergence of Zika virus in South America and its association with microcephaly in babies. The examples illustrate, that many of these diseases are provoked by RNA viruses. One of the first steps in understanding and eliminating those threats is the development of sensitive and rapid diagnostic methods. A general and relatively rapid method is the direct detection and examination of the agent’s genome. However, the nature of (re)emerging RNA viruses poses a series of very specific problems for the design of such methods. Therefore, a systematic approach was proposed for the design of DNA-hybridization-base methods to detect and characterize RNA viruses that will have both a high sensitivity and a specificity sufficiently broad to detect, per reaction, down to a single copy of any of the possible variants of the viral genome.
Following this approach a series of assays were designed, developed or adapted and put into use for detection and characterization of important RNA viruses. One of those viruses is West Nile virus (WNV), which after its explosive introduction into USA become the most widespread flavivirus throughout the world and, consequently, many countries began an intensive monitoring. While existing assay detected predominantly the Lineage 1, in Europa Lineage 2 was expected. Two new RT-qPCR for the detection of both lineages were developed, and reportedly used by independent laboratories. Due to more than 50000 associated deaths per year, the Hepatitis E virus also received an increasing attention to elucidate novel routes of transmission. This virus (especially genotype 3) has the zoonotic potential of transmission from pigs and wild boar to humans. RT-qPCR and nested qPCR for detection and characterization of this virus as well as a methodology for subtyping were developed and the first detected case of subtype 3b in a German wild animal was documented. In addition a novel assay for flaviviruses conformed by a RT-qPCR coupled with a low density DNA microarray was developed, which enabled the identification of WNV in mosquitoes from Greece. A RT-qPCR suitable for surveillance and diagnostic of all known variants of Venezuelan equine encephalitis virus was developed too. A causative agent of hemorrhagic infections, the Ngari virus, was detected and characterized in animal samples from Mauritania. These achievements were supported by the development of software applications for selection and visualization of primers and probes from aligned DNA sequences and for modeling of DNA hybridizations using unaligned sequences.
In conclusion a general methodology for rapid development of sensitive diagnostic methods based in DNA-hybridization technics (PCR, sequencing and microarray) was stablished and successful applications are reported.
The Flavivirus genus (Flaviviridae family) comprises the most important arboviruses in the world such as dengue virus, West Nile virus (WNV), Zika virus (ZIKV), Japanese encephalitis virus and yellow fever virus (YFV). Every year, several outbreaks caused by flaviviruses are reported worldwide (i.e.: ZIKV and YFV outbreaks in South America) with a huge impact on economy and public health. In the last few decades, many aspects of the flavivirus biology and the interaction of flaviviruses with host cells have been elucidated. However, many underlying mechanisms concerning receptor usage, entry process and viral interaction with host cell factors are still not completely understood. Integrins, the major class of cell adhesion molecules have been implicated in the infectious cycle of different viruses including flaviviruses. A previous report proposed that a particular integrin, the αVβ3 integrin, might act as a cellular receptor for WNV. However, this hypothesis was not confirmed by other groups. In the present study, murine cell lines lacking the expression of one or more integrin subunits were used to evaluate the involvement of different integrins in the flavivirus infection cycle. Mouse fibroblasts lacking the expression of β1 integrin (MKF-β1-/-) or β3 integrin (MEF-β3-/-) subunits or αVβ3 integrin (MEF-αVβ3-/-) as well as their corresponding wild-type cells were utilized. A second model using Chinese hamster ovary cells (CHO-K1), a cell line that has been described to be refractory to some flaviviruses, were modified to express either αV (CHO-αV+/+) or β3 (CHO-β3+/+) integrin subunits. All cell lines were first characterized by confocal laser microscopy, flow cytometry and functional assays prior to infection to assess their integrin expression. The cell lines were then inoculated with different flaviviruses of public health relevance: WNV, YFV-17D, Usutu virus (USUV), Langat virus (LGTV) and ZIKV. Infection assays were designed in order to evaluate whether integrins influence i) cell susceptibility; ii) binding; iii) internalization and iv) replication of the investigated flaviviruses. Our findings clearly demonstrate that β1, β3 and αVβ3 integrins do not act as flavivirus cellular receptor or attachment factor since their ablation does not completely abrogate flavivirus infection in the investigated cell lines. Flavivirus binding to the cell surface of MEFs, MKFs and CHO cells was not disturbed by the genomic deletion of the above-mentioned integrins. The deletion of β1 and β3 integrin subunit did not affect internalization of any of the flaviviruses tested. In contrast to that, loss of αVβ3 integrin in the MEF-αVβ3-/- cells showed a statistically significant decrease in WNV and USUV internalization while ZIKV, YFV-17D and LGTV internalization remained unaffected suggesting that αVβ3 integrin might be involved in the internalization process of at least some flaviviruses. On the other hand, flavivirus replication was substantially impaired in the integrin-deficient cell lines in comparison to their corresponding wild-type cells. Both, MEF-β3-/- and MKF-β1-/- cells showed a statistically significant reduction on viral load for all flaviviruses tested in comparison to their respective wild-type cells. The MEF-αVβ3-/- cells in particular, showed a strong inhibition of flavivirus replication with a reduction of up to 99% on viral loads for all flaviviruses tested. Levels of flavivirus negative-strand RNA were substantially decreased in MEF-αVβ3-/- cells indicating that integrins might influence flavivirus RNA replication. The ectopic expression of either αV or β3 integrin subunits in CHO cells slightly increased the replication of all flaviviruses tested. Taken together, this is the first report highlighting the involvement of integrins in ZIKV, USUV, LGTV and YFV infection. The results strongly indicate that the investigated integrins play an important role in flavivirus infection and might represent a novel host cell factor that enhances flavivirus replication. Although the exact mechanism of interaction between integrins and flaviviruses is currently unknown, the results provided in this study deepen our insight into flavivirus - host cell interactions and open doors for further investigations.