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Yellow fever virus isolated from a fatal post vaccination event: an experimental comparative study with the 17DD vaccine strain in the Syrian hamster (Mesocricetus auratus)

Vírus da febre amarela isolado de acidente pós-vacinal fatal: estudo experimental comparativo com a amostra vacinal 17DD em Syrian hamsters (Mesocricetus auratus)

Abstracts

In order to investigate the pathogenicity of the virus strain GOI 4191 that was isolated from a fatal adverse event after yellow fever virus (YFV) vaccination, an experimental assay using hamsters (Mesocricetus auratus) as animal model and YFV 17DD vaccine strain as virus reference was accomplished. The two virus strains were inoculated by intracerebral, intrahepatic and subcutaneous routes. The levels of viremia, antibody response, and aminotransferases were determined in sera; while virus, antigen and histopathological changes were determined in the viscera. No viremia was detected for either strain following infection; the immune response was demonstrated to be more effective to strain GOI 4191; and no significant aminotransferase levels alterations were detected. Strain GOI 4191 was recovered only from the brain of animals inoculated by the IC route. Viral antigens were detected in liver and brain by immunohistochemical assay. Histothological changes in the viscera were characterized by inflammatory infiltrate, hepatocellular necrosis, and viral encephalitis. Histological alterations and detection of viral antigen were observed in the liver of animals inoculated by the intrahepatic route. These findings were similar for both strains used in the experiment; however, significant differences were observed from those results previously reported for wild type YFV strains.

Yellow fever; Experimental study; Hamster; Pathogenicity


Visando investigar a possível patogenicidade do vírus isolado (GOI 4191) de um evento adverso fatal pela vacinação antiamarílica, realizou-se um ensaio experimental em Syrian hamsters (Mesocricetus auratus), usando-se a cepa vacinal 17DD como parâmetro. As amostras virais foram inoculadas por via intracerebral, intra-hepática e subcutânea. Nos soros foram determinados níveis de viremia, resposta imune e aminotransferases, e nas vísceras a presença de vírus, antígeno e lesões teciduais. Não se detectou viremia para as duas amostras, a resposta imune foi maior para GOI 4191, e as aminotransferases não apresentaram alterações compatíveis com danos hepáticos. Nos animais inoculados por via intracerebral o vírus foi recuperado somente a partir do cérebro, sendo o antígeno viral detectado, por imuno-histoquímica, no cérebro e fígado. Infiltrado inflamatório e corpúsculos acidófilos foram observados no fígado e lesões tipo encefalite viral no sistema nervoso central. Alterações histológicas e antígeno viral foram observados, também, no fígado dos animais infectados por via intra-hepática, e ausentes naqueles inoculados por via subcutânea. Os resultados foram similares para as duas amostras testadas, entretanto distintos daqueles relatados na literatura para cepas silvestres do vírus amarílico.

Febre amarela; Estudo experimental; Hamster; Patogenicidade


Yellow fever virus isolated from a fatal post vaccination event: an experimental comparative study with the 17DD vaccine strain in the Syrian hamster (Mesocricetus auratus)

Vírus da febre amarela isolado de acidente pós-vacinal fatal: estudo experimental comparativo com a amostra vacinal 17DD em Syrian hamsters (Mesocricetus auratus)

Sueli Guerreiro RodriguesI; Amélia Paes de Andrade Travassos da RosaII; Ricardo GallerIII; Vera Lúcia Reis de Souza BarrosI; Conceição de Maria Almeida VieiraIV; Jorge Fernando Soares Travassos da RosaI; Raimunda do Socorro da Silva AzevedoI; Márcio Roberto Teixeira NunesI; Elizabeth Salbé Travassos da RosaI; Pedro Fernando da Costa VasconcelosI

IInstituto Evandro Chagas, Belém, PA, Brasil

IIDepartment of Pathology, University of Texas Medical Branch, Galveston, Texas, USA

IIIFundação Oswaldo Cruz, Rio de Janeiro, RJ, Brasil

IVUniversidade Federal Rural da Amazônia, Belém, PA, Brasil

Address to Address to: Drª Sueli Guerreiro Rodrigues Av. Almirante Barroso 492, Marco 66090-000 Belém, PA, Brasil. Telefax: 55 91 226-5262. e-mail: suelirodrigues@iec.pa.gov.br

ABSTRACT

In order to investigate the pathogenicity of the virus strain GOI 4191 that was isolated from a fatal adverse event after yellow fever virus (YFV) vaccination, an experimental assay using hamsters (Mesocricetus auratus) as animal model and YFV 17DD vaccine strain as virus reference was accomplished. The two virus strains were inoculated by intracerebral, intrahepatic and subcutaneous routes. The levels of viremia, antibody response, and aminotransferases were determined in sera; while virus, antigen and histopathological changes were determined in the viscera. No viremia was detected for either strain following infection; the immune response was demonstrated to be more effective to strain GOI 4191; and no significant aminotransferase levels alterations were detected. Strain GOI 4191 was recovered only from the brain of animals inoculated by the IC route. Viral antigens were detected in liver and brain by immunohistochemical assay. Histothological changes in the viscera were characterized by inflammatory infiltrate, hepatocellular necrosis, and viral encephalitis. Histological alterations and detection of viral antigen were observed in the liver of animals inoculated by the intrahepatic route. These findings were similar for both strains used in the experiment; however, significant differences were observed from those results previously reported for wild type YFV strains.

Key-words: Yellow fever. Experimental study. Hamster. Pathogenicity.

RESUMO

Visando investigar a possível patogenicidade do vírus isolado (GOI 4191) de um evento adverso fatal pela vacinação antiamarílica, realizou-se um ensaio experimental em Syrian hamsters (Mesocricetus auratus), usando-se a cepa vacinal 17DD como parâmetro. As amostras virais foram inoculadas por via intracerebral, intra-hepática e subcutânea. Nos soros foram determinados níveis de viremia, resposta imune e aminotransferases, e nas vísceras a presença de vírus, antígeno e lesões teciduais. Não se detectou viremia para as duas amostras, a resposta imune foi maior para GOI 4191, e as aminotransferases não apresentaram alterações compatíveis com danos hepáticos. Nos animais inoculados por via intracerebral o vírus foi recuperado somente a partir do cérebro, sendo o antígeno viral detectado, por imuno-histoquímica, no cérebro e fígado. Infiltrado inflamatório e corpúsculos acidófilos foram observados no fígado e lesões tipo encefalite viral no sistema nervoso central. Alterações histológicas e antígeno viral foram observados, também, no fígado dos animais infectados por via intra-hepática, e ausentes naqueles inoculados por via subcutânea. Os resultados foram similares para as duas amostras testadas, entretanto distintos daqueles relatados na literatura para cepas silvestres do vírus amarílico.

Palavras-chaves: Febre amarela. Estudo experimental. Hamster. Patogenicidade.

The 17D yellow fever virus vaccine strain is recognized as one of the most successful vaccines in terms of efficacy and safety. This vaccine has rarely been associated with severe adverse events; the most commonly reported is post-vaccination encephalitis observed most often in children less than 10 months of age11 15. Actually, only the 17D vaccine is produced to immunize humans against yellow fever virus (YFV); the vaccina derives from two distinct substrains, 17D-204 and 17DD, that correspond to different lineages obtained from the original YFV attenuated by Theiler and Smith8. In Brazil, the 17DD vaccine strain is currently used during vaccination campaigns, and is produced by the Institute of Technology in Immune Biologics (Bio-Manguinhos)/Oswaldo Cruz Foundation (FIOCRUZ)/Rio de Janeiro. Saccharose and glutamateare used as stabilizing components5.

In 1999, a child residing in Goiania, Goias state died showing clinical manifestations similar to classic YFV infection; her illness was associated with a YFV vaccination adverse event20. The virus strain (GOI 4191) obtained from clinical specimens of the patient, and YFV isolated from a second adverse vaccination event reported in Americana/Sao Paulo state in 2000 were genetically identified as YFV 17DD vaccine strain6 20. In 2001, two additional fatal cases were reported in Belo Horizonte, MG, and in Três Passos/RS states (MS/FUNASA, data not shown). In addition, a suspicious fatal case was reported in Santos/SP and was supposed to be associated to YFV vaccination; however, the absence of specific clinical symptoms and the vaccine lot made it difficult to clarify6.

Additional adverse events similar to those that occurred in Brazil have been reported in other countries. Four cases (3 of them fatal) were described in the United States9, and 1 in Australia3. Moreover, one suspected case was also reported for each country in England1, 1 in Germany21 and 1 in Sweden19.

The occurrence of these post vaccination events with the YFV vaccine lead to an exhaustive surveillance and caution. This type of adverse event can be related to genetic factors that may regulate the cellular susceptibility to the YFV, emphasizing that an exacerbated susceptibility can result in severe clinical expression of the disease, but fortunately this condition seems to be extremely rare6 20.

The data presented is this study are related to an experimental assay using the Syrian hamster (Mesocricetus auratus) in order to investigate the viscerotropic activity of the virus strain GOI 4191. Hamsters have been used successfully as an alternative animal model in substitution to monkeys, to study YFV pathogenicity and treatment investigations17 22.

MATHERIAL AND METHODS

Virus strains and inoculum. Vero cell cultures fluid infected with suspensions of heart fragments sampled from patients was used as virus stock for the strain GOI 4191. The Brazilian 17DD vaccine strain was used as virus reference to the experiment.

The vaccine vial (lot: 98UFB088Z) was reconstituted with 5mL of saline and apirogenic solution (lot: 99PDD284Z) to obtain the dose recommended to humans (minimum of 1000 LD50/0.5mL) in 0.1mL, the final volume inoculated into hamsters. Virus strain GOI 4191 was diluted in phosphate buffered saline (PBS), pH 7.4, containing 0.75% bovine albumin and antibiotics (100UI/mL of penicillin and 100mg/mL of streptomycin) to obtain a dose of 1000 LD50/0.1mL. The virus samples were diluted immediately before the assay and kept on ice. Subsequently, samples of both virus suspensions were titrated in 2-3 days albino Swiss mice to confirm the dose administrated. Titers were calculated using the Reed & Muench method14 and expressed in LD50/0.02mL.

Hamster infection and specimen collection. Groups of 22 male hamsters, 4-5 weeks old, and weighting 48g in average, were inoculated with both virus strains, GOI 4191 and 17DD, by subcutaneous (SC), intrahepatic (IH), and intracerebral (IC) routes as shown in Table 1. A total of 22 animals were used as negative controls for the assay.

For 10 consecutive days after infection, groups of animals containing 6 inoculated hamsters (2 IC, 2 IH, and 2 SC) and 1 normal were sacrificed daily. The animals surviving after 10 days were observed up to day 21, when all of them were sacrificed and the experiment concluded.

Under halothane anesthesia, hamsters were exsanguinated by cardiac puncture. The blood was obtained without anticoagulant substances and the serum separated and stored into two aliquots, one at -20ºC (for serology) and another at -70ºC (attempts for virus isolation). Subsequently, animal necropsy was carried out to obtain samples of brain, liver, spleen, heart, kidney, and lung. The viscera were separated into two aliquots, one to be frozen at -70ºC, and another preserved in 10% buffered formalin solution.

Virus testing. Sera and organ samples obtained from the infected hamsters were used for virus titration by inoculation in 2-3 day old albino Swiss mice. Each organ was individually macerated, and 10% suspensions were prepared in PBS pH7.4, containing 0.75% bovine albumin and antibiotics (100UI/mL of penicillin and 100mg/mL of streptomycin). Subsequently, the suspensions were clarified by centrifugation at 5,000rpm for 15 minutes at 4ºC, and the supernatants used undiluted as inocula in newborn mice. Sera and viscera supernatant fluids giving positive results (death in mice) were then titrated in newborn mice, using 10-fold serial dilutions prepared from 10-1 to 10-6. Virus titers were calculated using the Reed & Muench method14 and expressed as LD50/0.02mL.

Antibody detection.Complement fixation test: the complement fixation test CF) microtechnique modified by Fulton & Dumbell4 was used for antibody detection, using known antigens. Serum samples obtained from inoculated hamsters and from the negative controls (non inoculated hamster) were tested at dilutions of 1:8, 1:16; 1:32 and 1:64 against YFV (strain 17DD) and Guaroa (strain BEH22063) virus antigens at 1:8 and 1:16 dilutions. Guaroa, a bunyavirus, was used as negative control. The CF antibody titers for positive sera were reported as the highest dilution giving a percentage of hemolysis up to 25%.

Hemagglutination inhibition test: hamster sera, previously extracted by acetone method and adsorbed in goose erythrocytes, were tested by hemagglutination inhibition test (HI) using the microtechnique described by Shope16. Hemagglutinin antigens were prepared from YFV (strain 17DD) infected new born mouse brain, using the sucrose acetone extration method2. Initially, serum samples were tested at 1:20 dilution against 4 units of the antigen, and a 1:200 dilution of goose erytrocytes within pH 6.4. Subsequently, the titration of the positive sera was carried out up to 1:1,280 dilution.

Determination of alanine aminotransferase levels. Determination of alanine aminotransferase (ALT) level was determined in serum samples of hamsters previously inoculated with the YFV and controls, using a commercial kit (ROCHE) with an automated reader (COBRAS MIRA PLUS). ALT levels in the serum samples of hamsters collected from day 1 to day 10 and at day 21 post inoculation, were analyzed in function of the arithmetic average (å(Xi)/n) and standard deviation values found in the sera of hamsters not inoculated (71.5 ± 11.0) used as negative control in the experiment as well as in correlation with hepatic parenchyma damage.

Antigen detection.Complement fixation test: samples of brain, liver, heart, spleen, kidney and lung obtained from the infected and non infected hamsters were individually macerated and used to prepare 1mL of antigen suspension in veronal diluted at 1:5. The supernatants were clarified by refrigerated centrifugation at 2,500rpm for 5 minutes, and tested against mouse immune ascitic fluid anti YFV (MIAF-YFV).

Immunohistochemical assay: fragments of organs obtained from infected hamsters were processed to obtain 5mm thin cuts, placed over glass slides Super-frost ®/Plus (A. Daigger & Company), incubated at 60ºC, and processed by the immunohistochemicalmethod7. The primary antiserum corresponded to the antiMIAF-YFV antibody diluted at 1:4,000, and the secondary (conjugated antibody) to mice and rabbit anti immunoglobulins produced in goat and absorbed in dextran polymer containing alkaline phosphatase molecules (Envision System, Dako, EUA). The cells with viral antigen showed discrete, moderate, or strong cytoplasmic staining (red) when examined using an Olympus CBA Microscope.

Histopathology. Tissues fragments were processed for light microscopy, using a standard technique described as sequential immersion of tissues in solutions with different ethanol concentrations from 70% up to absolute (100%), followed by two passages in zylol solvent at room temperature, two immersions in paraffin resin at 60ºC, inclusion in paraffin blocks, 5mm thin cuts production using a rotating microtome (Jung Histocut 820 - Leica), and finally tissue staining, using the hematoxilin-eosin technique10 13.

RESULTS

The titers of the inocula for the GOI 4191 and 17DD virus strains corresponded to 10-2.3 LD50/0.02mL and 10-4.9 LD50/0.02mL, respectively. Virus testing, by newborn mice inoculation method, revealed no viremia in hamster sera inoculated with both strains by IC, IH or SC routes. Virus was recovered only from the brain of animals inoculated by the IC route. The 17DD virus strain was recovered from brain samples between day 1 and day 9 post-inoculation (pi) revealing a maximum titer at day 3 (10-3.4 LD50/0.02mL). Strain GOI 4191 was recovered from day 2 up to day 10 with highest titer detected at day 6 (10-4 LD50/0.02mL) (Figure 1).


Figure 2 shows the HI antibody responses in sera of hamsters inoculated with the 17DD strain 5 days pi by IC route, and at 6 days pi by IH and SC routes. On other hand, antibody for GOI 4191 strain was demonstrated at day 6 in hamsters inoculated by IH route and at day 7 in hamsters inoculated by IC and SC routes. Antibody titers could be detected up to day 21 pi. All of the samples obtained from the control animals were negatives.


Figure 3 shows the presence of CF antibodies produced against the 17DD YFV strain detected on the sixty day in animals inoculated by IC, IH and SC routes. On the fifth day, antibodies against the virus GOI 4191 were detected in animals inoculated by the IC route; and on the seventh day it was detected in animals inoculated by IH and SC routes.


Table 2 bring together the results concerning the determination of ALT levels, detection of viral antigen by immunohistochemical and histopathologic findings. Some ALT levels were found to be higher than 71.5 + 11.0, values observed in samples obtained from animals inoculated with 17DD (IC and SC) and GOI 4191 (IC, IH, and SC) strains. Viralantigens were not detected for animals inoculated by SC route.

The test for viral antigen in organs of hamsters inoculated with 17DD and GOI 4191 viruses by the CF test using MIAF-YFV (BEH111) gave negative results for all samples, including brains from animals inoculated by the IC route. However, viral antigen was demonstrated by immunohistochemical assay in the brain and liver of animals inoculated by the IC route with both strains (Figure 4A-C), as well as, in the liver of animals inoculated by the IH route withthe strain GOI 4191 (Figure 4D). Immunohistochemical detection of YF viral antigen in the liver of the animals inoculated by IH route with the strain 17DD was not carried out.



Histopathologic examinations carried out in organs of hamsters collected from day 1 through day 10, and day 21 pi, revealed histologicchanges in animals inoculated with the YFV 17DD and GOI 4191 strains by IC and IH routes. On the other hand, no histologic changes were found in animals inoculated by SC route.

Hamsters inoculated IC with the 17DD virus showed viral encephalitis from day 1 to day 10 pi and liver inflammatory infiltrate from day 7 to day 10, whereas in hamsters infected with the GOI 4191 strain, virus encephalitis was observed from day 7 to day 10 pi, as well as liver inflammatory reaction from day 1 to day 4 (Figure 5A-B). Animals inoculated with the 17DD and GOI 4191 by IH route showed morphologic changes in the liver from day 4 to day 6 and from day 1 to day 3, respectively (Figure 5C-D). Both strains produced viral encephalitis classified from light to severe, as well as discrete showed morphologic changes in the liver, described as mononuclear inflammatory reaction at lobule and portal space levels, and the presence of rare and isolated acidophilic granules.



DISCUSSION

No virus was detected in the sera of animals inoculated by any route, with either the 17DD or the GOI 4191 YFV strains. In contrast, differences could be observed in comparison with data previously reported for hamsters inoculated by intraperitoneal route with wild strains of YFV; the latter animals developed viremia within 24h pi. The viremia lasted 5-6 days, and usually reached maximum values at day 3 pi17. The HI and CF antibody curves for both strains were similar, although antibodies were initially detected at day 5-6 for the 17DD strain and at day 6-7 for the GOI 4191 virus strains. Furthermore, the highest antibody titers were induced by GOI 4191 strain. Early detection of HI antibodies (day 4 and day 5 pi) is reported for hamsters inoculated IP with a wild type YFV strain, as well as by IC and SC routes (APAT Rosa: unpublished data).

Complement-fixing antibodies were detected in hamsters inoculated IP with wild type YFV at day 4 and at day 6 pi by the SC route (APA Travassos da Rosa, unpublished data). In animals inoculated with the virus GOI 4191, complement-fixing antibodies were detected at day 6-7, but this type of antibody was also detected on day 6 pi in animals inoculated with the 17DD virus strain. Yellow fever vaccine has been shown to induce seroconversion or significant complement-fixing antibody titer rises in up to 46% of persons with pre vaccination YFV or heterologous flavivirus experiences, but not in immunological virgins12.

Levels of ALT, specific aminotransferases usually indicative of hepatic necrosis, in hamsters infected with wild type YFV became elevated from day 4 to day 6 pi reaching levels of 1000U/L considered higher than normal values (28-119U/L) reported for adult female hamsters17. In this study, ALT levels determined for hamsters inoculated with both virus strains showed different curve in comparison with the kinetic curves described above. In this case, enzyme levels showed ramdomized elevation, and according to results revealed by histophatology, correlation with hepatic parenchyma damage was not observed. ALT level alterations were not accentuated, except for hamsters inoculated with 17DD strain by IH and SC routes collected at tenth day pi. This finding probably was related to elevated hemolysislevel observed in the tested sera.

The 17DD and GOI 4191 virus strains were recovered only from brain of hamsters inoculated by the IC route, the recognized organ for YFV vaccine strain tropism. Histopathologic results revealed characteristic encephalitis in animals inoculated with GOI 4191 by the IC route, and hepatic inflammatory reaction in hamsters inoculated by IC and IH routes. Same morphological changes were also observed in animals inoculated with 17DD vaccine strain. These findings are in contrast with previous one observed for animals inoculated with vaccine strains18. On the other hand, histological damage observed in hamsters inoculated IP with wild YFV strains were described as moderate and non specific morphologic changes in the brain (perivascular hemorrhage and edema), as well as hepatic focal necrosis at day 3 pi with confluent necrosis and steatosisevolution, where hepatocellular regeneration was observed in survived animals after day 822.

YFV antigen determinations in organs of hamsters inoculated with 17DD and GOI 4191 strains were negative by CF test, including from the brain of animals inoculated IC; however the antigen was detected in fluids of infected Vero cells and brain of newborn mice infected with the referred strains (data not shown). In contrast, viral antigen was demonstrated by immuno histochemical technique in organs (brain and liver) of hamsters infected with 17DD and GOI 4191 strains.

Discrete differences observed for kinetic curves of virus detected in brain (Figure 1) and antibody levels (Figures 2 e 3) observed early with 17DD virus, probably are related with the different doses used in the experiment. Nevertheless, further studies are necessary in order to adjust the LD50 GOI 4191 dose in comparison with the reference virus, as well as an experiment using groups of animals inoculated with the wild type YFV strain and used as positive control for virus viscerotropism.

The phenotypic analysis revealed that the virus strain GOI 4191, using hamsters as experimental model, showed similar results to those reported for the 17DD vaccine virus (lot98UFB088Z) and different from those found in the literature for hamsters inoculated with wild type YFV strains by IP route.

AKNOWLEDGEMENTS

To Dr. Maria da Luz Fernandes Leal, Bio-Manguinhos/FIOCRUZ, who kindly provided the yellow fever virus vaccine vials (17DD substrain), Dr. Venâncio Avancini Ferreira Alves, Instituto Adolfo Lutz, for helping in immunohistochemical assay, and Dr. Robert B. Tesh, Department of Pathology/University of Texas Medical Branch, for his critical editing of the manuscript. The authors thank also Adlai Sousa for graphic computation support and Basilio Silva Buna, Elpídia do Socorro de Souza Costa, Francisca Nunes da Silva Nascimento, Helena Baldez Vasconcelos, Maria das Dores Miranda Barbosa, Maxwell Furtado de Lima, Raimunda do Socorro Rodrigues Pimentel and Walter Miranda Campos for technical support.

The present work was supported by grants from the IEC/FUNASA and CNPQ (process 521294/97-5).

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  • Address to:
    Drª Sueli Guerreiro Rodrigues
    Av. Almirante Barroso 492, Marco
    66090-000 Belém, PA, Brasil.
    Telefax: 55 91 226-5262.
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  • Publication Dates

    • Publication in this collection
      26 Sept 2014
    • Date of issue
      2004
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