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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Puumala hantavirus : immune responses and vaccines /

Carvalho Nicacio, Cristina de, January 2002 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 5 uppsatser.
2

Implications of local Puumala hantavirus genetics and epidemiology for diagnostics and vaccine development /

Johansson, Patrik, January 2005 (has links)
Diss. (sammanfattning) Umeå : Umeå universitet, 2005. / Härtill 4 uppsatser.
3

Study of pathogenesis and immune response in human Puumala virus infection

Thunberg, Therese January 2013 (has links)
Hantaviruses can cause two severe human diseases: hemorrhagic fever with renal syndrome (HFRS) and hantavirus cardiopulmonary syndrome (HCPS). Hantaviruses are spread to humans mainly through inhalation of infectious virions, secreted from infected rodents. The human diseases are characterized by an increased capillary leakage syndrome. Hantaviruses are known to infect endothelial cells, but they are non-cytopathogenic. The mechanism behind human disease is not well understood, but an overactive immune response is implicated in the pathogenesis. The aim of my thesis has been to investigate parts of innate and adaptive immune responses in Puumala virus-infected patients. In paper I we found a sex difference in the cytokine profile during acute infection. Females had significantly higher plasma levels of IL-9, FGF-2, GM-CSF and lower levels of IL-8 and IP-10 compared to males. These differences may affect the activation and function of the immune response. In paper II we studied the phenotype and kinetics of NK cells. We observed that CD56dim NK cells were elevated during acute infection and that these, predominantly NKG2C+ NK cells, remained elevated for at least two months after symptom debut. Our novel finding of a prolonged NK cell response, implicates that NK cells may possess adaptive immunity features.  In paper III we observed a vigorous cytotoxic T cell (CTL) response during acute infection, which contracted in parallel with decrease in viral load. The CTL response was not balanced by an increase in regulatory T cells. The T cells expressed inhibitory immunoregulatory receptors, known to dampen intrinsic T cell activity.  In paper IV, we found that a low IgG response in patients was significantly associated with more severe disease, while the viral load did not affect the outcome. Our findings support the use of passive immunization as a treatment alternative for hantavirus-infected patients. In conclusion, my thesis contributes to an increased knowledge about the immune response in hantavirus-infected patients. The findings, combined with future studies, will hopefully lead to a better understanding of the pathogenesis and possible treatment alternatives.
4

Human antibody responses to hantavirus recombinant proteins & development of diagnostic methods

Elgh, Fredrik January 1996 (has links)
Rodent-borne hantaviruses (family Bunyaviridae) cause two distinct human infections; hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (HPS). HFRS is a common viral zoonosis, characterized by fever, renal dysfunction and hemostatic imbalance. Four HFRS-associated hantaviruses have been described: Hantaan virus and Seoul virus mainly found in Asia, Dobrava virus, encountered in the Balkan region and Puumala virus (PUU), causing mild HFRS (nephropathia epidemica; NE) in Europe. HPS, recently discovered in the Americas, involves adult respiratory distress syndrome with a high mortality rate and is caused by Sin Nombre virus. Hantaviruses are enveloped and carry a RNA genome which encodes a polymerase, two glycoproteins and a nucleocapsid protein. The latter elicits a strong humoral immune response in infected patients. The clinical diagnosis of hantavirus infections has until recently relied on serological confirmation by immunofluorescense assay (IFA) and enzyme-linked immunosorbent assay (ELISA) using cell culture derived viral antigens. Due to the hazardous nature of hantaviruses and variable virus yield in cell culture we aimed at using recombinant hantavirus proteins for serological purposes. We expressed PUU N in E. coli (PUU rN) and found that high levels of IgM to this protein could be detected at onset of NE. This indicated that it was useful as the sole antigen for serodiagnosis. Our finding was confirmed by comparing IFA and PUU rN ELISA using 618 sera collected at the regional diagnostic laboratory. Full-length PUU rN is difficult to purify due to aggregation to E. coli remnants. We therefore located the important domain for the humoral immune response by utilizing truncated PUU rN proteins to its amino-terminal region (amino acid 7-94). Amino acid 1-117 of N of the five major human hantavirus pathogens were produced in E. coli. Serological assays based on them could detect IgM and IgG serum responses in 380 HFRS and HPS patients from Sweden, Finland, Slovenia, China, Korea and the USA with high sensitivity. In an epidemiological investigation of hantavirus serum responses in European Russia we unexpectedly found antibody responses to the hantaviruses found in east Asia and the Balkan region in 1.5 %, speaking in favour for the presence of such virus in this region. The degree of cross reactivity within the hantavirus genus was adressed by following the serum responses in NE patients. We found an increase of cross reactivity during the maturation of the immune response from onset of disease up to three years by comparing the IgG reactivity towards the hantavirus aminoterminal rN proteins. The first human isolate of the causative agent of NE in Scandinavia was recovered in cell culture from phytohemagglutinin stimulated leukocytes. Serological analysis revealed that this virus belongs to the PUU hantavirus serotype, distinct from the rodent prototype PUU Sotkamo. The human PUU Umeå is unique but genetically similar to rodent isolates from northern Sweden. / digitalisering@umu.se
5

Implications of Local Puumala Hantavirus Genetics and Epidemiology for Diagnostics and Vaccine Development

Johansson, Patrik January 2005 (has links)
Puumala viruses, a member of the Hantavirus genus in the Bunyaviridae family, are enveloped by a lipid bilayer and possesses a tripartite single stranded RNA genome with negative polarity. The hantaviruses encode four proteins: a nucleocapsid protein (N), two membrane spanning glycoproteins (GN and GC) and a RNA dependent RNA polymerase (RdRp). Hantaviruses cause two forms of diseases, hemorrhagic fever with renal syndrome (HFRS) in Europe and Asia, and hantavirus pulmonary syndrome (HPS) in the Americas. The hantaviruses are mainly rodent borne, and humans are mostly infected by inhalation of aerosolized rodent secrete. Human Puumala virus infection results in nephropathia epidemica (NE), a mild haemorrhagic disease. It is of importance to have a good understanding of the epidemiology and genetics of these viruses for the development of new diagnostic methods and for future vaccine development. In this thesis we determined the complete viral genome sequence and characterized the structural proteins based on studies of expression and glycosylation patterns, for a unique human virus isolate; performed a genomic analysis of local Puumala viruses and their individual rodent host, Clethrionomys glareolus, from six different locations was performed. It was seen that the virus genetic variation between different locations could be stable over relatively large distances while there could be large variation over a short distance. For the bank voles no such variation could be seen; developed and evaluated Genetic vaccines, based on PCR-generated linear DNA. We showed that it was important to protect these fragments against nuclease degradation at that attachment of a nuclear localization signal peptide further improved the immune response. We also designed, fabricated and evaluated a 2000 probe cDNA-microarray for identification and differentiation of hantaviruses. The chips was based on 12 different strains of six hantaviruses and could differentiate between both different hantaviruses and strains within one hantavirus serotype.
6

TRANSMISSION AND PATHOGENESIS OF HANTAVIRUS / HANTAVIRUS ÖVERFÖRING OCH PATOGENES

Pettersson, Lisa January 2015 (has links)
Hantaviruses are the causative agents of hemorrhagic fever with renal syndrome (HFRS) in Eurasia, and of hantavirus cardiopulmonary syndrome (HCPS) in the Americas. Transmission to humans usually occurs by inhalation of aerosolized virus-contaminated rodent excreta. To date, human-to-human transmission has only been described for the Andes hantavirus. The mode of transmission of Andes hantavirus is not yet known, but transmission through saliva has been suggested. In Sweden, we have one hantavirus that is pathogenic to humans, Puumala virus (PUUV), which is endemic in Central and Northern Europe. It induces a relatively mild form of HFRS, also called nephropathia epidemica (NE). The rodent reservoir is the bank vole (Myodes glareolus). The mechanism behind the pathogenesis of hantavirus is complex and probably involves both virus-mediated and host-mediated mechanisms. The aim of this project was to investigate the transmission mechanisms and pathogenesis of hantavirus disease in humans. In our first study, we described the largest outbreak of PUUV so far in Sweden. We investigated factors that might be important for causing the outbreak, and suggested that a peak in the bank vole population together with concurrent extreme weather conditions most probably contributed to the outbreak. Our next studies concentrated on human-to-human transmission of hantaviruses. We found PUUV RNA in saliva from PUUV-infected patients, suggesting that there is PUUV in the saliva of infected humans, although no person-to person transmission appears to occur with PUUV.  In the studies that followed, we showed that human saliva and human salivary components could inhibit hantavirus replication. We also found PUUV-specific IgA in the saliva of PUUV-infected patients, which might prevent person-to-person transmission of the virus.  In the final study, we focused on the pathogenesis of NE. One hundred five patients were included in a prospective study.  They were divided into a group with mild disease and a group with moderate or severe disease. We found that the immune response had a dual role in disease development. It was partly responsible for development of severe disease, with significantly higher amounts of neutrophils in severely ill patients, but it was also protective against severe disease, because patients with mild disease had higher levels of PUUV-specific IgG. In conclusion, a peak in the bank vole population in combination with extreme weather will increase the risk of human infection, PUUV RNA is present in saliva, PUUV-specific IgA and salivary components inhibit person-to-person transmission of PUUV, and the immune response is important for the pathogenesis of PUUV and the severity of the disease. / Hantavirus är en grupp av virus som finns hos gnagare som bär på viruset utan att själva bli märkbart sjuka. Varje hantavirus har anpassat sig till sin egen art av gnagare som de infekterar (kallas virusets reservoar). Hantaviruset kan överföras till människor från gnagare och kallas då för en zoonos eftersom detsprids från djur till människa. I människa orsakar hantavirus blödarfeber med njurpåverkan i Eurasien och blödarfeber med med hjärt och lungpåverkan i Nord- och Sydamerika. I Sverige har vi bara ett hantavirus som är sjukdomsframkallande hos människor, Puumala-viruset som även finns i delar av övriga Europa. Det framkallar en relativt mild form av blödarfeber, som kallas sorkfeber eller Nephropathia epidemica. Puumala-virusets reservoar är skogssorken (Myodes glareolus). Människor smittas oftast av hantavirus när de andas in infekterat damm som innehåller utsöndringar (avföring, urin eller saliv) från gnagare som har torkat in och sedan blivit luftburet. Vad man vet hittills så finns det bara ett hantavirus som smittar från person till person, för övriga hantavirus är människan en ”dead end”. Det virus som kan smitta från person till person heter Andes hantavirus och finns i Sydamerika. Andes hantavirus har en mus som reservoar från vilken människor kan smittas, sedan har smittan i vissa fall förts vidare från människa till människa, som tur är har dessa utbrott gått att stoppa. Fastän utbrotten har varit små har många personer dött, eftersom dödligheten är så hög, ungefär 30-40% av de diagnostiserade fallen dör. Hur Andes hantavirus överförs från människa till människa är inte känt men överföring genom saliv har föreslagits. Hur viruset ger upphov till sjukdom hos människa är inte klarlagt. Studier talar för att mekanismen bakom sjukdomsutvecklingen (den så kallade patogenesen) hos hantavirusorsakade blödarfebrar är komplex. Sannolikt beror patogenesen både på egenskaper hos viruset och värden d.v.s. människan som är smittad av viruset. Vårt mål med detta projekt var att undersöka vad som hindrar överföring av Puumala hantavirus från människa till människa och att undersöka hur virusinfektionen påverkar sjukdomsutvecklingen hos människan. I vår första studie beskrev vi det största utbrottet av sorkfeber hittills i Sverige och vi undersökte faktorer som kan ha orsakat utbrottet. Vi föreslog att en topp i skogssorkpopulationen samtidigt med extremt varmt väder troligen bidrog till utbrottet. Utbrottet skedde i december och det extremt varma vädret medförde att snön smälte bort. Sorkarna bor vanligtvis under snön på vintern, vi tror att frånvaro av snötäcke fick sorkarna att söka sig till byggnader för att söka skydd och där kom i kontakt med människor. Våra efterföljande studier fokuserade på överföring av hantavirus från människa till människa. Vi hittade Puumala-virusets arvsmassa (RNA) i saliv från sorkfeberpatienter, vilket tyder på att det finns Puumala-virus i saliven hos infekterade människor, även om ingen överföring från person till person verkar inträffa. I efterföljande studier visade vi att mänsklig saliv och mänskliga salivkomponenter minskar hantavirus smittsamhet. Vi fann också Puumala-virusspecifika IgA-antikroppar i saliven från sorkfeberpatienter, vilket kan förhindra överföring från person till person. I den sista studien fokuserade vi på patogenesen hos människor efter hantavirusinfektion. 105 patienter ingick i en prospektiv studie och delades in i en grupp med mild sjukdom och en grupp med måttlig/svår sjukdom. Vi hittade en dubbel roll hos immunsvaret för sjukdomsutvecklingen. Immunsvaret var delvis ansvarig för utveckling av svår sjukdom med betydligt högre mängd neutrofiler hos svårt sjuka patienter, men det var också skyddande mot allvarlig sjukdom, eftersom patienter med en mild sjukdom hade högre nivåer av Puumalavirusspecifika IgG-antikroppar. Detta talar för att behandling med IgG-antikroppar specifikt riktade mot hantavirus skulle kunna vara effektiv hos hantavirusinfekterade patienter. Sammanfattningsvis; en topp i skogssorkspopulationen i kombination med extremt väder ökar risken för infektion hos människor; Puumala-virus arvsmassa (RNA) finns i saliv; Puumala-virusspecifika IgA-antikroppar och salivkomponenter hämmar överföring av Puumalavirus från person till person; immunsvaret är viktigt för Puumala-virus patogenes och sjukdomens svårighetsgrad.
7

Long-Lived Memory T Lymphocyte Responses Following Hantavirus Infection: a Dissertation

Van Epps, Heather Lin 18 July 2001 (has links)
Hantaviruses are members of the virus family Bunyaviridaethat cause two potentially life-threatening diseases in humans: hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (BPS). HFRS is caused by Old World hantaviruses that are endemic in many Asian and European countries. Infections with Old World hantaviruses can range in severity from asymptomatic to moderate or severe, depending primarily on the infecting serotype of virus. HPS is caused by New World hantaviruses in North and South America. New World hantaviruses are rarely asymptomatic and are severe in the majority of cases. These syndromes are distinct from one another in the primary target organ of virus infection (kidney vs. lung), but have important clinical features in common, including fever, thrombocytopenia, and a capillary leak syndrome. These common clinical manifestations suggest that the underlying mechanisms of disease may be similar in the two syndromes. The precise mechanisms of pathogenesis of HFRS and HPS are poorly characterized, but may be mediated in part by immunopathology. Hantaviruses are able to establish infections in many human cell types, including primary human endothelial cells, without having any cytopathic effect on these cells. Human infections with hantavirus result in a robust activation of the humoral and cellular immune response, and we hypothesize that these immune responses contribute to the pathology of disease. Evidence for the activation of T lymphocytes, and their potential involvement in immunopathology, includes increases in the number of circulating, activated CD8+ T cells during HFRS, the presence of lymphocytic infiltrates (predominantly CD8+T cells) in kidney biopsies from patients with acute HFRS, and associations between certain HLA haplotype and disease severity following hantavirus infection. This thesis is the first examination of human T lymphocyte responses that are generated during HFRS. Initially, we studied memory T cell responses in scientists who were sub-clinically infected with Hantaan virus (HTNV), the prototype hantavirus. We later investigated memory T cell responses in healthy Finnish adults who had HFRS caused by Puumala virus (PUUV), a hantavirus endemic primarily in Scandinavia. At the onset of these studies, there was no available information on human T lymphocyte responses to Old World hantaviruses. Virus-specific CD8+ and CD4+human T cell lines had been isolated from patients with acute HPS caused by Sin Nombre virus (SNV) infection. In that study, conducted in our laboratory, several human T cell epitopes on the nucleocapsid (N) protein and G2 envelope glycoprotein of SNV were identified and characterized. We decided to perform similar analyses on PBMC from donors who had been infected with HTNV and PUUV, in order to determine the specificity and diversity of the T cell response to Old World hantaviruses. The initial study of three donors who had sub-clinical infections with HTNV demonstrated that virus-specific T cell responses could be detected in all the donors following in vitro stimulation of PBMC with inactivated virus. In two of the donors, the virus-specific cytolytic T cells (CTL) recognized the HTNV N protein, and in the third donor the virus-specific CTLs recognized the HTNV G1 glycoprotein. Isolation and characterization of virus-specific T cells from two donors resulted in the identification of two CD8+ T cell epitopes on the HTNV N protein, which were restricted by either HLA A1 or B51. These CTL lines included both HTNV-specific (HLA B51-restricted) and serotype-cross reactive (HLA A1 restricted) lines. In one subject, these virus-specific T cell responses were detectable in IFN-γ ELISPOT assays following peptide stimulation, and in bulk cultures after short-term stimulation with inactivated HTNV. These results indicated that the CD8+CTL responses of humans after sub-clinical infection with HTNV were readily detectable and were directed against a limited number of viral proteins and epitopes. In addition, sub-clinical infection resulted in the generation of both virus-specific and cross-reactive CTL responses. We reasoned that hantavirus infections that lead to clinical illness may result in the generation of more robust and/or diverse virus-specific T cell responses than in sub-clinical infections. To address this question, we studied the memory CD8+ T cell responses in a group of healthy adults from Finland who had HFRS caused by PUUV infection between the years 1984 and 1995. We detected virus-specific CTL in the bulk cultures of seven of eleven immune individuals tested following stimulation with infectious virus. The PUUV proteins N, G1 and G2 were recognized by CTLs in six, five, and two donors respectively. Extensive cloning of T cells from two donors resulted in the isolation of sixty-three virus-specific CTL lines, the majority of which (61/63) were specific for the PUUV N protein. Six novel CD8+ CTL epitopes and one CD4+ CTL epitope were identified on the N protein, all of which clustered in the center of the protein between amino acids 173 and 251. The CTL lines specific for these epitopes were restricted by a variety of HLA alleles including A2, A28, B7 and B8, and were primarily serotype specific when tested against target cells expressing HTNV or SNV N protein. IFN-γ ELISPOT analysis using the defined epitopes to stimulated PBMC, revealed high frequencies of circulating N-specific CD8+ T cells in eight of thirteen individuals tested. Finally, T cell receptor (TCR) Vβ analysis of CTL clones specific for one epitope (N204-12) demonstrated that cells in this population expressed up to five different Vβ chains. These results demonstrated that the PUUV N protein may be the dominant target of the CTL response, that the N-specific CD8+ CTL responses are diverse, heterogeneous, and primarily serotype specific, and that virus-specific memory CD8+T cells can persist at high levels for up to 15 years after the primary infection. In order to understand the pathology of HFRS and HPS, we must be able to assess the contribution of various factors that could potentially contribute to disease. The virus burden in the infected individual is likely to be an important factor in the severity of the resulting disease. Quantitative RT-PCR analysis of plasma samples from acute HPS patients demonstrated that a higher virus burden (as reflected by viral RNA copy number) is associated with more severe HPS. In order to perform similar analyses in patients with HFRS caused by PUUV, we established a quantitative RT-PCR assay for the detection of PUUV S segment RNA in patient plasma. The design and optimization of the PUUV-specific RT-PCR is described in this report. This assay will allow us to measure the virus burden in patients and compare these data with levels of T cell activation and with parameters of disease severity. In this way, we hope to gain an understanding of the kinetics and magnitude of both the virus burden and virus-specific T cell response during the acute illness. This thesis provides the first description of human virus-specific T cell responses to HTNV and PUUV. These data shed light on the nature of the CD8+ T cell responses that are generated following natural infections with PUUV and sub-clinical infections with HTNV. The studies of memory CD8+ T cell responses to PUUV, and the development of a PUUV-specific quantitative RT-PCR assay, establish the framework for future studies of the immunopathology of acute HFRS. Quantitative analysis of both virus burden and T cell responses during acute illness will provide insight into their relative contributions to the pathology of disease.

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