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Primary contact with human polyomaviruses is followed by lifelong asymptomatic persistence of viral DNA. Under severe immunosuppression JCV activation may lead to unrestricted virus growth in the CNS followed by development of progressive multifocal leukoencephalopathy (PML). Besides the kidney and the brain, target cells of persistent infection were also found in the hematopoietic system. This included the presence of JCV genomes in peripheral blood cells (PBCs). In the attempt to understand the role of PBCs for the JCV infection in humans, we asked for the type of cells affected as well as for virus interaction with PBCs. Analysis of separated subpopulations by highly sensitive and specific polymerase chain reaction and Southern blot hybridization revealed the presence of JCV DNA mostly in circulating granulocytes. These cells have important functions in innate immunity and are professional phagocytes. This suggested that PCR amplified DNA might be the result of an extranuclear association of the virus due to membrane attachment or phagocytosis rather than JCV infection with presence of viral DNA in the nucleus. In the attempt to answer this question JCV DNA was subcellularly localized in the blood of 22 healthy donors by JCV specific fluorescence in situ hybridization (FISH). Granulocytes and peripheral blood mononuclear cells (PBMCs) were separated by Percoll gradient centrifugation. Intracellular JCV DNA was hybridized with Digoxigenin-labeled JCV specific DNA probes covering half of the viral genome. As the sensitivity of the anti-digoxigenin antibody system was lower than the PCR detection level, a chemical amplification step was included consisting of peroxidase labeled secondary antibody precipitating biotinylated tyramide followed by detection with streptavidin-Texas-Red and fluorescence microscopy. Comparison of the number of cells affected in healthy individuals with 15 HIV-1 infected patients with and without PML revealed that the rate of affected PBMCs was comparable in both groups (2.5±0.4 and 14.5±0.9 per 1000). In contrast, the rate of JCV positive granulocytes in the immunosuppressed group was 92.6±1.7% compared to 4±1.4% in healthy donors thus confirming that granulocytes are the major group of circulating cells affected by JCV and that HIV-1 associated immune impairment has an important effect on the virus-cell association. Localization revealed that JCV DNA was predominantly located within the cytoplasm, although hybridizing signals occasionally covered the nuclear compartment. The fluorescent glow of chemical amplification combined with classical fluorescence microscopy did not allow an unequivocal localization of viral DNA. However, confocal microscopy of 24 sections through single cells combined with FISH without chemical amplification confirmed cytoplasmic localization of JCV DNA in a large number of cells. Additionally, it clearly demonstrated that JCV DNA was also located in the nucleus and nuclear localization directly correlated with the number of cells affected. Calculation of the virus load in subcellular compartments revealed that up to 50% of the JCV genomes were located in the nucleus thus pointing to viral infection at least in the granulocytes of HIV-1 infected patients. This may contribute to the distribution of the virus from sites of peripheral infection to the CNS and may promote the development of active PML in the severely immune impaired patients.
Das Polyomavirus WU (WUPyV) wurde erstmalig im Jahr 2007 in respiratorischem Material bei Patienten mit respiratorischem Infekt beschrieben. Charakterisierung, Epidemiologie und Beurteilung des Krankheitswerts des neuen Virus sind seither Gegenstand vieler Studien weltweit. Retrospektiv wurde Probenmaterial aus dem Respirationstrakt auf WUPyV mittels PCR untersucht. Das Material war zur virologischen Routinediagnostik eingegangen und stammte von in der Universitätskinderklinik Würzburg stationär behandelten Kindern, deren klinische Diagnosen anonymisiert zur Verfügung standen. Es wurden 1277 Nasenrachensekrete (NRS) berücksichtigt aus dem Zeitraum zwischen Januar 2002 und September 2005 sowie zwischen Januar und Juli 2007. Von 1277 NRS waren 62 (4,9 %) positiv für WUPyV. Das Virus wurde in jedem Monat eines Jahres nachgewiesen, wobei Wintermonate insgesamt stärker vertreten waren. Das mediane Alter der betroffenen Patienten betrug 3,0 Jahre (4 Monate – 6,3 Jahre). Klinische Diagnosen bei WUPyV-Infektionen umfassten ein breites Spektrum an oberen und unteren Luftwegserkrankungen. Bei 33 NRS (53,2 %) waren neben WUPyV zuvor ein oder zwei weitere respiratorische Viren durch PCR oder Immunfluoreszenz-Antigentest nachgewiesen worden (Adenovirus: 10; Influenza A: 10; humanes Bocavirus: 9; RSV: 5; Parainfluenzavirus 1/2/3: 3). Die Sequenzanalyse eines 647 bp langen Abschnitts der nicht kodierenden Region bei 50 WUPyV-positiven NRS zeigte eine Übereinstimmung der Sequenzen von 98,5 %. Die Ergebnisse der vorliegenden Studie unterstützen bisherige Ergebnisse zur Epidemiologie und Verbreitung des WUPyV. Demnach konnte WUPyV-DNA bei akuter respiratorischer Infektion im menschlichen Respirationstrakt, bevorzugt bei Kleinkindern, detektiert werden. WUPyV wies eine hohe Koinfektionsrate mit anderen respiratorischen Viren auf. Es zeigte sich in der phylogenetischen Analyse zweier Genomabschnitte eine geringe Variabilität des Genoms. Bei bisheriger Datenlage bleibt unklar, ob der Nachweis von WUPyV-DNA in NRS mit einer akuten respiratorischen Erkrankung assoziiert werden kann.