Abstract

Findings

Nearly 26% of the Brazilian Amazon belongs to the Pará state and it is estimated that the buffalo herd of this region represents approximately 45% of the Brazililian population, found mainly on the Marajó island [¹1 Barbosa NGS: Bubalinocultura no Estado do Pará. Rev Bras Reprod Anim 2005, 29(1):34-38.]. With few exceptions, arbovirus (arthropod-borne virus) infections comprise zoonosis, because their natural cycles involve non-human vertebrates (hosts) and hematophagous arthropods (vectors). The Pan-Amazon is the largest area in the world where those viruses are found, and the Brazilian Amazon alone houses the largest variety of known isolated arbovi-ruses [²2 Vasconcelos PFC, da Rosa APA T, Pinheiro FP, da Rosa JFS T: Arboviroses. In Tratado de infectologia, Volume 1. Edited by Focaccia R, Veronesi R. São Paulo: Atheneu; 2005:289-302.].

In the Brazilian Amazon, there are numerous species of hematophagous diptera and wild vertebrates that cohabit within the same ecosystem. Such diversity and increased population size is globally unique. These factors provide favorable environmental conditions for viruses, particularly arboviruses [³3 da Rosa APA T, da Rosa JFS T, Pinheiro FP, Vasconcelos PFC: Arboviroses. In Doenças infecciosas e parasitárias: enfoque Amazônico.Edited by Leão RNQ. Belém: Cejup: UEPA; 1997:207-225.].

Although 210 arboviruses have been isolated in Brazil, their vast majority have been found in the Brazilian Amazon [⁴4 Martins LC, Diniz JA, Silva EV, Barros VL, Monteiro HA, Azevedo RS, Quaresma JA, Vasconcelos PF: Characterization of Minaçu virus (Reoviridae, Orbivirus) and pathological changes in experimentally Infected newborn mice.Int J Exp Pathol 2007, 88(1):63-73.,⁵5 Azevedo RSS, Silva EVP, Carvalho VL, Rodrigues SG, Nunes Neto JP, Monteiro HAO, Peixoto VS, Chiang JO, Nunes MRT, Vasconcelos PFC: Mayaro fever virus. Brazilian Amazon. Emerg Infect Dis 2009, 15(11):1830-1832.]. To the best of our knowledge, there have been no studies focused on investigating the role of water buffaloes(Bubalus bubalis) in the maintenance of arboviruses. To address this question, we have evaluated the prevalence of antibodies in water buffaloes in Pará state in order to determine which arboviruses are circulating.

Blood samples were collected from animals living in the six mesoregions of Pará, which were two years old or more, without arbovirus vaccination and born and raised at the studied areas. After proper restraint of the animals and local asepsis, the jugular vein was punctured, without anticoagulant, with a vacuum system and serum samples were transported on ice and then stored at -70°C until use. A total of 654 serum samples from water buffaloes were collected.

The hemagglutination-inhibition (HI) test was performed according to the microplate-adjusted protocol described by Shope [⁶6 Shope RE: The use of micro-hemagglutination-inhibition test to follow antibody response after arthropod-borne virus infection in a community of forest animals. An Microbiol Rio de Janeiro 1963, 11:167-171.]. The test is based on the ability of arboviruses to agglutinate goose(Anser anser) red blood cells. It is possible to inhibit hemagglutination activity of antigens using serum containing specific antibodies.

The test was performed against antigens from arbovi-ruses isolated in Brazil of six different Flavivirus types: yellow fever virus (YFV), Ilheus virus (ILHV), Saint Louis encephalitis virus (SLEV), Cacipacore virus (CPCV), Bus-suquara virus (BSQV) and Rocio virus (ROCV). All these viruses belonged to the collection of the Department of Arbovirology and Hemorrhagic Fevers of Evandro Chagas Institute, Ananindeua, PA, Brazil. Antigens were prepared from infected tissues from brain, liver or serum of newborn mice using the sucrose-acetone extraction technique. Animal sera were tested (initial dilution of 1:20) against four antigen units [⁷7 Clarke DH, Casals J: Technique for hemagglutination and hemagglutination-inhibition with arthropod-borne viruses. Am J Trop Med Hyg 1958, 7(5):561 -573.].

Rodrigues et al. [⁸8 Rodrigues SG, Oliva OP, Araújo FAA, Martins LC, Chiang JO, Henriques DF, da Silva EVP, Rodrigues DSG, Prazeres ASC, Tavares-Neto J, Vasconcelos PFC: Epidemiology of Saint Louis encephalitis virus in the Brazilian Amazon region and in the State of Mato Grosso do Sul, Brazil: elevated prevalence of antibodies in horses. Rev Pan-Amaz Saúde 2010, 1 (1):81 -86.] criteria for positivity were chosen. Positive reactions were classified as monotypic (reaction against only one antigen or the reaction was at least four-fold stronger against one antigen compared to all others of the same viral genus) or heterotypic (reactions against two or more viruses exhibiting similar titers or the predominance of an antigen was less than four-fold when compared to the others) or total (monotypic reactions plus heterotypic reactions).The results were analyzed using the chi-square goodness-of-fit test, using the BioEstat 5.0 software [9]. The sample scores were measured using a significance level (a) of 0.05 to reject the null hypothesis (p ≤ a).

Antibodies against the six investigated arboviruses showed different positive reaction rates (Table 1). Positive reactions against specific virus antigens suggest that different flaviviruses circulate among water buffaloes in Pará, Brazilian Amazon. These findings are surprising because there is little published evidence regarding arbo-virus infections on buffaloes. In addition, water buffaloes usually live in flooded regions where arthropods are frequently found, thereby increasing the probability of an infection.

The present results indicated that SLEV was the arbo-virus with the highest HI antibody prevalence, which had a broad circulation compared to other investigatedFlaviviruses (p < 0.05), except for ILHV (p = 0.1275). In Brazil, several SLEV strains have been isolated in the neighborhood of Belém, Pará state, from sentinel animals and also during epizootics from both wild birds and hematophagous arthropods over different years and geographical areas [¹⁰10 Vasconcelos PFC, da Rosa JFS T, da Rosa APA T, Degallier N, Pinheiro FP, Sá Filho GC: Epidemiologia das encefalites por arbovirus na Amazônia brasileira. Rev Inst Med Trop São Paulo 1991, 33(6):465-476.]. Several serologic surveys previously performed in humans living in the Brazilian Amazon indicated the prevalence of HI antibodies against SLEV ranging from 1 to 5% [¹¹11 Pinheiro FP, da Rosa APA T: Arboviral zoonoses of Central and South American. In Handbook of Zoonoses: viral. 2nd edition. Edited by Beran GW. Boca Raton: CRC Press; 1994:210-212.]. In contrast to the human data, the results of the current study indicate that SLEV was the most prevalent virus in all investigated areas. Indeed, a remarkable prevalence of SLEV infection was observed in the studied water buffaloes.

ILHV is the most widely distributed non-epidemic Fla-vivirus and exhibits the highest prevalence by HI assays in Brazil. In the Brazilian Amazon, this virus has been systematically isolated from several wild animal species and vector arthropods, found sporadically from febrile patients [¹¹11 Pinheiro FP, da Rosa APA T: Arboviral zoonoses of Central and South American. In Handbook of Zoonoses: viral. 2nd edition. Edited by Beran GW. Boca Raton: CRC Press; 1994:210-212.]. It exhibited the second highest prevalence in this study.

The present study has also detected HI antibodies against YFV in water buffaloes. This virus had the third highest prevalence. Such results are puzzling and may indicate cross-reactivity with another untested or unknown Flavivirus,or, alternatively, may indicate that animals are becoming asymptomatically infected by YFV. Further studies must be carried out to establish the prevalence of neutralizing YFVantibodies in these animals.

There are no records of association of the flaviviruses ROCV, BSQV and CPCV with disease in domestic or wild animals [¹¹11 Pinheiro FP, da Rosa APA T: Arboviral zoonoses of Central and South American. In Handbook of Zoonoses: viral. 2nd edition. Edited by Beran GW. Boca Raton: CRC Press; 1994:210-212.]. However, some human patients from the state of São Paulo, Brazil, reported domestic swine and fowl deaths during a ROCV encephalitis epidemic in humans [¹²12 Iversson LB: Rocio encephalitis. In The arboviruses: epidemiology and ecology, Volume 4. Edited by Monath TP. Boca Raton: CRC Press; 1988:77-92.]. The CPCV had no monotypic reactions that indicate cross-reactivity with other tested Flavivirus.

Conclusions

The current findings allow us to conclude that there is preliminary evidence of active Flavivirus infection in water buffaloes in the Brazilian Amazon. In this region, the animals are exposed to many thousands of mosquito bites in places that sometimes serve as transmission foci for these viruses. Animals bitten by infected mosquitoes may develop infection and seroconversion. If frequently exposed to arboviruses, the buffaloes possibly represent a public health risk to humans that may be susceptible to develop the infection. In many cases, high seroprevalence in farm animals indicate lower risk for people, since the animals are providing zooprophylaxis by absorbing infectious bites from mosquitoes. The water buffaloes showed higher prevalence of heterotypic antibodies reactions, which suggests that they might to act as sentinel to detect the movement of arboviruses.

Acknowledgments

The authors would like to thank CNPq (grant number 301641/2010-2), IEC/ MoH and UFRA for their funding of this research.

References

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