Detection of rotavirus in dogs with diarrhea in Brazil

Gabbay, Yvone B.; Homem, Valéria S.F.; Munford, Veridiana; Alves, Antonia S.; Mascarenhas, Joana D.P.; Linhares, Alexandre C.; Rácz, Maria Lúcia

doi:10.1590/S1517-83822003000100016

Abstracts

Rotavirus was detected by the enzyme-linked immunosorbent assay (ELISA) in the faeces of a diarrheic dog. Virus particles with morphology typical of rotavirus were visualized by direct electron microscopy. This sample was subsequently tested for the four main human serotypes (G1-G4), by ELISA with monoclonal antibodies. G genotyping was attempted by RT-PCR using G1-G6 and G8-G11 primers but no positive results could be yielded. Also using RT-PCR it was possible to characterize this canine strain as belonging to P[ 3] genotype. This is the first canine rotavirus detected in Brazil.

rotavirus; diarrheic dog; genotype G; genotype P; Belém- Brazil

Rotavírus foi detectado pela técnica imunoenzimática (ELISA) nas fezes de um cachorro que apresentava diarréia. Partículas virais com morfologia típica de rotavírus foram visualizadas por microscopia eletrônica direta. Essa amostra foi posteriormente testada para os quatro principais sorotipos humanos de rotavírus (G1-G4) por ELISA utilizando anticorpos monoclonais. Genotipagem para G foi realizada por RT-PCR usando "primers" específicos para G1-G6 e G8-G11. Nenhum resultado positivo foi obtido. Também utilizando RT-PCR, foi possível caracterizar essa amostra canina como genotipo P [ 3] . Este é o primeiro rotavirus canino descrito no Brazil.

rotavirus; diarréia canina; genotipo G; genotipo P; Belém-Brasil

Detection of rotavirus in dogs with diarrhea in Brazil

Detecção de rotavírus em cachorros com diarréia

Yvone B. Gabbay^I^* * Corresponding author. Mailing Address: Av. Almirante Barroso 492. 66090-000 Belém, PA, Brasil. Fax: (+5591) 2142005. E-mail: yvonegabbay@iec.pa.gov.br ; Valéria S.F. Homem^II; Veridiana Munford^III; Antonia S. Alves^I; Joana D.P. Mascarenhas^I; Alexandre C. Linhares^I; Maria Lúcia Rácz^III

^ISeção de Virologia Geral, Instituto Evandro Chagas, Fundação Nacional de Saúde

IIDepartamento de Medicina Veterinária Preventiva e Saúde Animal, Faculdade de Medicina Veterinária e Zootecnia, Universidade de São Paulo, SP, Brasil

IIIDepartamento de Microbiologia, Instituto de Ciências Biomédicas, Universidade de São Paulo, SP, Brasil

ABSTRACT

Rotavirus was detected by the enzyme-linked immunosorbent assay (ELISA) in the faeces of a diarrheic dog. Virus particles with morphology typical of rotavirus were visualized by direct electron microscopy. This sample was subsequently tested for the four main human serotypes (G1-G4), by ELISA with monoclonal antibodies. G genotyping was attempted by RT-PCR using G1-G6 and G8-G11 primers but no positive results could be yielded. Also using RT-PCR it was possible to characterize this canine strain as belonging to P[ 3] genotype. This is the first canine rotavirus detected in Brazil.

Key words: rotavirus, diarrheic dog, genotype G, genotype P, Belém- Brazil

RESUMO

Rotavírus foi detectado pela técnica imunoenzimática (ELISA) nas fezes de um cachorro que apresentava diarréia. Partículas virais com morfologia típica de rotavírus foram visualizadas por microscopia eletrônica direta. Essa amostra foi posteriormente testada para os quatro principais sorotipos humanos de rotavírus (G1-G4) por ELISA utilizando anticorpos monoclonais. Genotipagem para G foi realizada por RT-PCR usando "primers" específicos para G1-G6 e G8-G11. Nenhum resultado positivo foi obtido. Também utilizando RT-PCR, foi possível caracterizar essa amostra canina como genotipo P [ 3] . Este é o primeiro rotavirus canino descrito no Brazil.

Palavras-chaves: rotavirus, diarréia canina, genotipo G, genotipo P, Belém-Brasil

INTRODUCTION

Rotaviruses are the major cause of acute viral gastroenteritis in infants and young children, as well as in young animals of several species, including strains of bovine, equine, porcine and canine origin (16).

Rotavirus is classified in the family Reoviridae, genus Rotavirus, comprizing five species (Rotavirus A to E) and two tentative species (Rotavirus F and G). Rotavirus A (RV-A) is further classified into G and P serotypes/genotypes according to the two external capsid proteins, VP7 and VP4, respectively (34).

Rotavirus infections in dogs have already been reported elsewhere (4,6,9). Viral particles with morphology typical of rotavirus were detected by electron microscopy (EM) in the faeces from a 12-week-old pup with nonfatal diarrhea (6). Other authors (4) have associated rotavirus infection with a fatal neonatal diarrhea in a 3-day-old pup, where the virus was detected by negative contrast EM examination of intestinal contents and, thereafter, the agent was successfully propagated in MDCK (Madin-Darby canine kidney) cells. Similar results were obtained by Fulton et al. (9), who observed diarrhea in several litters of pups (< 1 week old) from the same kennel. In a 2-day-old pup that died from diarrhea, rotavirus particles were detected by EM in specimen prepared from the intestinal homogenate. Roseto et al. (26), examining stool samples from apparently normal dogs randomly caught on the sidewalks of Paris, France, detected 2 (3.6%) rotavirus-positive faecal specimens by EM. In addition, Hoshino et al. (15), reported the detection of rotavirus, by EM, in fecal samples from an apparently normal, one-year old beagle. This agent was subsequently propagated in cell cultures and characterized through comparison with rotaviruses from other species. By plaque reduction neutralization assay, a two-way antigenic relationship was found between this virus and simian (rhesus MMU 18006 and SA-11) rotaviruses and a one-way antigenic relationship with feline (Taka), bovine (NCDV), and porcine (OSU) rotaviruses. Dogs experimentally infected with a human rotavirus (32, 33) did not present diarrhoea, although rotavirus antibodies have been detected and viral particles were visualized by TEM in their faeces. These studies indicate that dogs may be infected with rotaviruses from different species and that transmission may occur through direct contact. These findings also indicate that dogs may have a role in the transmission and dissemination of rotavirus between humans and other species. The environmental contamination by dogs' stools represents a serious sanitary problem in many urban and suburban areas, and, since the detection of rotavirus in stools from these animals has been previously reported (26), this may be of epidemiological importance.

The present report deals with the detection of rotavirus in dogs from Belém, PA and Botucatu, SP, Brazil.

MATERIALS AND METHODS

Fecal specimens

A total of 70 faecal specimens (one per dog) were collected from diarrheic and asymptomatic dogs from April to July 1996. Twenty-nine samples were obtained in the Veterinary Hospital of the "Faculdade de Ciências Agrárias do Pará (FCAP)", Belém, Pará, and forty-one samples from the Veterinary Hospital of the "Faculdade de Medicina Veterinária e Zootecnia (FMVZ)", Botucatu, São Paulo, Brazil. Clinical data were obtained from forms filled out by the attending veterinarians. Dogs were from different races. In relation to the age, most of them had one to five months, and male dogs (60.6 %) predominated over female dogs (39.4%).

Electron microscopy (EM)

The examination of fecal samples was performed essentially as previously described (1). Briefly, crude faecal specimens were mixed with distilled water and applied onto a carbon-collodium coated 400-mesh copper grid. The grid was subsequently dried and the preparation stained with one drop of 2% phosphotungstic acid (PTA) pH 7.2. The grid was then examined by transmission electron microscopy (TEM), in a Zeiss EM900 electron microscopy model, at 80 KV. Virus particles were sought in at least five grid squares and identification was made following the criteria proposed by Flewett and Woode (8).

Enzyme-linked immunosorbent assay

All specimens were tested by the EIARA ELISA, developed at Oswaldo Cruz Foundation, Rio de Janeiro, Brazil (25). This test allows the detection of both group A rotaviruses and adenoviruses. The stools were also tested by a commercial DAKOPATTS ELISA kit (Copenhagen, Denmark), as previously described (7). G serotyping was performed using monoclonal antibodies against each of four epidemiologically important human G serotypes (G1, G2, G3, and G4), essentially as reported by Taniguchi et al. (28).

Polyacrylamide gel electrophoresis (PAGE)

Electrophoresis of deproteinized rotavirus dsRNA was carried out through a 5% polyacrylamide gel, using discontinuous buffer system, as recommended by Laemmli (17).

Reverse transcription-polymerase chain reaction (RT-PCR)

G and P genotyping was performed in two steps, RT-PCR and semi-nested PCR as described previously (10,11). The second amplification was carried out for G typing using two sets of primers specific for human genotypes G1, G2, G3, G4 and G9 (3,11); and one set specific for porcine genotypes G5 and G11 and bovine genotypes G6, G8 and G10 (12). For P typing, bovine, porcine and human rotaviruses primers, specific for VP4 genotypes P[ 1] , P[ 3] , P[ 4] , P[ 5] , P[ 6] , P[ 7] , P[ 8] , P[ 9] , P[ 10] and P[ 11] were used (10,13,18).

RESULTS

Rotavirus particles measuring approximately 70nm in diameter were observed in faeces from one (3.0%) of the 33 specimens examined by TEM. Parvovirus, paramyxoviruses and coronavirus-like particles were also detected in 30.3%, 3.0% and 6.0%, respectively (14). Of 70 stools tested by ELISA, only one (1.4%) sample from a diarrheic case was positive for group A rotavirus by both ELISA methods, corresponding to the EM-positive sample. Sample was from a 8 month old S.R.D. dog, with the following symptoms: diarrhea, vomiting, dehydration and apathy. RNA electrophoresis of this sample showed a long eletrophoretic profile. This pattern was classified as I2C IIW+ III2 IVL+ according to Moosai et al. (21), and as Ib IIa IIIc IVa electropherotype, as proposed by Lourenço et al. (19). This sample did not react with any of the monoclonal antibodies to serotypes G1, G2, G3 and G4. No amplification product was obtained using primers G1-G6, and G8-G11 in PCR. P typing however characterized this strain as genotype P[ 3] (

).

DISCUSSION

Rotaviruses have already been detected in faeces from dogs with diarrhoea (4,9). Using electron microscopy, Roseto et al. (26) detected rotavirus at rates (3.5%) lower than those observed for other pathogens such as parvoviruses (23.2%) and coronaviruses (12.5%). In our study, the results obtained by this technique were similar, since for rotavirus the positivity was 3.0%, for parvovirus and coronavirus-like 30.3% and 6.0% respectively (14). Serological studies (20), however, have shown that approximately 80% of the dogs have antibodies to rotavirus, suggesting that the majority of infections may be asymptomatic. One issue to be considered is that rotavirus antibodies detected in these dogs by immunofluorescence technique are group-specific, suggesting that interspecies infections may occur (2,30,32,35).

Most of the canine rotavirus samples are characterized as serotype G3 (24). Our sample did not react with any of the G MAbs, including G3 MAbs and was not amplified by RT-PCR for all the genotypes tested (G1-G6 and G8-G11), including two different G3 specific primers. This results indicates that our canine rotavirus strain may belong to a serotype different from G3.

P[ 3] genotype has already been identified in simian (strains Si/RRV), canine (Ca/K9, CaCu-1) and feline rotavirus specimens (strains Fe/FRV64, Fe/ Cat97) as well as in human samples (strains RO1845, HCR3) (5), including Brazilian human strains (31). Analysis conducted by Nakagomi and Nakagomi (23) showed, by RNA-RNA hybridization, that human strains HCR3 and Ro1845, are very closely related to each other and virtually indistinguishable from feline (strain Fe/FRV64) and canine (strains Ca/K9, CaCu-1) rotaviruses. Others authors also demonstrated this homology using different techniques (22,27,29). This suggests an interspecies transmission of rotavirus from cats and dogs to humans. However the impact of these samples on infant morbidity for rotavirus gastroenteritis has not yet been established.

To our knowledge this is the first report on the detection of a rotavirus of canine origin in Brazil. It would be rather important to further characterize the G type of this sample in order to compare it with other canine rotavirus strains worldwide.

ACKNOWLEDGEMENTS

We are grateful to Dr. Manoel Soares and Mr. Antonio de Moura for technical support, Dr. Maria de Lourdes C. Gomes for helpful comments on the manuscript. This work was supported by IEC and FAPESP grant 99/04575-9.

Submitted: January 20, 2002; Returned to authors for corrections: July 12, 2002; Approved: December 12, 2002

1. Barth, O.M. Estudo sobre a contrastação negativa de suspensões virais. Rev. Brasil. Biol., 44: 71-80, 1984.
2. Dagenais, L.; Schwers, A.; Pastoret, P.P.; Chappuis, G. Propagation of bovine rotavirus by dogs. Vet. Rec., 109: 187, 1981.
3. Das, B.K.; Gentsch, J.R.; Cicirello, H.G.; Woods, P.A.; Gupta, A.; Ramachandran, M.; Kumar, R.; Bhan, M.K.; Glass, R.I. Characterization of rotavirus strain from newborns in New Delhi, India. J. Clin. Microbiol., 32(7): 1820-1822, 1994.
4. England, J.J.; Poston, R.P. Electron microscopic identification and subsequent isolation of a rotavirus from a dog with fatal neonatal diarrhea. Am. J. Vet. Res., 41: 782-783, 1980.
5. Estes, M.K. Rotaviruses and their replication. In: Fields, B.N.; Knipe, D.M.; Howley, P.M.; Chanock, R.M.; Melnick, J.L.; Monath, T.P.; Roizman, B.; Straus, S.E. (eds.). Fields Virology, 3rd. ed., Lippincott-Raven, Philadelphia, 1996, p. 1625-1655.
6. Eugster, A.K.; Sidwa, T. Rotaviruses in diarrheic feces of a dog. Vet. Med. Small Anim. Clin., 74: 817-818, 1979.
7. Flewett, T.H.; Aries, C.F.; Avendano, L.F.; Ghafoor, A.; Mathan, M.M.; Mendis, L.; Moe, K.; Bishop, R.F. Comparative evaluation of the WHO and DAKOPATTS enzyme-linked immunoassay kits for the rotavirus detection. Bull. World Health Organ., 67: 369-374, 1989.
8. Flewett, T.H.; Woode, G.N. The rotaviruses. Arch. Virol., 57: 1-23, 1978.
9. Fulton, R.W.; Johnson, C.A.; Pearson, J.; Woode, G.N. Isolation of a rotavirus from a newborn dog with diarrhea. Am. J. Vet. Res., 42: 841-843, 1981.
10. Gentsch, J.R.; Glass, R.I.; Woods, P.; Gouvea, V.; Gorziglia, M.; Flores, J.; Bimal, K.D.; Bhan, M.K. Identification of group A rotavirus gene 4 types by polymerase chain reaction. J. Clin. Microbiol., 30(6): 1365-1373, 1992.
11. Gouvea, V.; Glass, R.I.; Woods, P.; Taniguchi, K.; Clark, H.F.; Forrester, B.; Fang, Z. Polymerase chain reaction amplification and typing of rotavirus nucleic acid from stool specimens. J. Clin. Microbiol., 28: 276-282, 1990.
12. Gouvea, V.; Santos, N.; Timenetsky, M.C. Identification of bovine and porcine rotavirus G types by PCR. J. Clin. Microbiol., 32: 1338-1340, 1994a.
13. Gouvea, V.; Santos, N.; Timenetsky, M.C. Vp4 typing of bovine and porcine group A rotaviruses by PCR. J. Clin. Microbiol., 32: 1333-1337, 1994b.
14. Homem, V.S.F.; Mendes, Y.G.; Linhares, A.C. Gastroenterite canina - agentes virais nas fezes de cães diarréicos e não diarréicos. Arq. Bras. Med. Vet. Zootec., 51(6): 531-536, 1999.
15. Hoshino, Y.; Wyatt, R.G.; Scott, F.W.; Appel, M.J. Isolation and characterization of a canine rotavirus. Arch. Virol., 72: 113-125, 1982.
16. Kapikian, A.Z.; Chanock, R.M. Rotaviruses. In: Fields, B.N.; Knipe, D.M.; Howley, P.M.; Chanock, R.M.; Melnick, J.L.; Monath, T.P.; Roizman, B.; Straus, S.E. (eds.), Fields Virology, 3rd. ed., Lippincott-Raven, Philadelphia, 1996, p. 1657-1708.
17. Laemmli, U.K. Cleavage of structural proteins during the assembly of head of bacteriophage T4. Nature, 227: 680-685, 1970.
18. Li, B.; Clark, H.F.; Gouvea, V. - Nucleotide sequence of VP4 - encoding gene of an unusual human rotavirus (HCR3). Virology, 196: 825-30, 1993.
19. Lourenço, M.H.; Nicolas, J.C.; Cohen, J.; Scherrer, R.; Bricout, F. Study of human rotavirus genoma by electrophoresis: attempt of classification among strains isolated in France. Ann. Virol. (Inst Pasteur) 132E: 161-73, 1981.
20. McNulty, M.S.; Allan, G.M.; Thompson, D.J.; O'Boyle, J.D. Antibody to rotavirus in dogs and cats. Vet. Rec., 102: 534-535, 1978.
21. Moosai, R.B.; Alcock, R.; Madeley, C.R. A cryptogram for recording rotavirus strains: the rotacode. J. Hyg., 93: 237-250, 1984.
22. Nakagomi, O.; Isegawa, Y.; Hoshino, Y.; Aboudy, Y.; Shif, I.; Silberstein, I.; Nakagomi, T.; Ueda, S.; Sears, J.; Flores, J. A new serotype of the outer capsid protein VP4 shared by an unusual human rotavirus strain Ro1845 and canine rotaviruses. J. Gen. Virol., 74: 2771-2774, 1993.
23. Nakagomi, T.; Nakagomi, O. Human rotavirus HCR3 possesses a genomic RNA constellation indistinguishable from that of feline and canine rotaviruses. Arch. Virol., 145: 2403-2409, 2000.
24. Nishikawa, K.; Hoshino, Y.; Taniguchi, K.; Green, K.Y.; Greenberg, H.B.; Kapikian, A.Z.; Chanock, R.M.; Gorziglia, M. Rotavirus VP7 neutralization epitopes of serotype 3 strains. Virology, 171: 503-511, 1989.
25. Pereira, H.G.; Azeredo, R.S.; Leite, J.P.; Andrade, Z.P.; De Castro, L. A combined enzyme immunoassay for rotavirus and adenovirus (EIARA). J. Virol. Meth., 10: 21-28, 1985.
26. Roseto, A.; Lema, F.; Cavalieri, F.; Dianoux, L.; Sitbon, M.; Ferchal, F.; Lasneret, J.; Peries, J. Electron microscopy detection and characterization of viral particles in dog stools. Arch. Virol., 66: 89-93, 1980.
27. Shirane, K.; Nakagomi, O. Interspecies transmission of animal rotaviruses to humans as evidenced by phylogenetic analysis of the hypervariable region of the VP4 protein. Microbiol. Immunol., 38: 823-826, 1994.
28. Taniguchi, K.; Urasawa, T.; Morita, Y.; Greenberg, H.B.; Urasawa, S. Direct serotyping of human rotavirus in stools using serotype 1-, 2-, 3- and 4-, specific monoclonal antibodies to VP7. J. Infec. Dis., 155: 1159-1166, 1987.
29. Taniguchi, K.; Urasawa, T.; Urasawa, S. Species specificity and interspecies relatedness in VP4 genotypes demonstrated by VP4 sequence analysis of Equine, Feline, and canine rotavirus strains. Virology, 200: 390-400, 1994.
30. Torres-Medina, A.; Wyatt, R.G.; Mebus, C.A.; Underdahl, N.R.; Kapikian, A.Z. Diarrhea caused in gnotobiotic piglets by the reovirus-like agent of human infantile gastroenteritis. J. Infec. Dis., 133: 22-27, 1976.
31. Timenetsky, M.C.; Santos, N.; Gouvea, V. Survey of rotavirus G and P types associated with human gastroenteritis in Sao Paulo, Brazil, from 1986 to 1992. J. Clin. Microbiol., 32: 2622-2624, 1994.
32. Tzipori, S. Human rotavirus in young dogs. Med. J. Aust., 2: 922-923, 1976.
33. Tzipori S, Makin T 1978. Propagation of human rotavirus in young dogs. Vet. Microbiol, 3: 55-63.
34. Van Regenmortel, M.H.V.; Fauquet, C.M.; Bishop, D.H.L. - Virus Taxonomy. Classification and Nomenclature of Viruses. Seventh Report of the International Committee on Taxonomy of Viruses. Academic Press, San Diego, 2000.
35. Wyatt, R.G.; Mebus, C.A.; Yolken, R.H.; Kalica, A.R.; James, H.D.; Kapikian, A.Z.; Chanock, R.M. Rotaviral immunity in gnotobiotic calves: heterologous resistance to human virus induced by bovine virus. Science, 203: 538-549, 1979.

^*

Corresponding author. Mailing Address: Av. Almirante Barroso 492. 66090-000 Belém, PA, Brasil. Fax: (+5591) 2142005. E-mail:

yvonegabbay@iec.pa.gov.br

Publication Dates

Publication in this collection
30 June 2003
Date of issue
Apr 2003

History

Accepted
12 Dec 2002
Reviewed
12 July 2002
Received
20 Jan 2002

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Barth, O.M. Estudo sobre a contrastação negativa de suspensões virais. Rev. Brasil. Biol., 44: 71-80, 1984.

[2] 2. Dagenais, L.; Schwers, A.; Pastoret, P.P.; Chappuis, G. Propagation of bovine rotavirus by dogs. Vet. Rec., 109: 187, 1981.

[3] 3. Das, B.K.; Gentsch, J.R.; Cicirello, H.G.; Woods, P.A.; Gupta, A.; Ramachandran, M.; Kumar, R.; Bhan, M.K.; Glass, R.I. Characterization of rotavirus strain from newborns in New Delhi, India. J. Clin. Microbiol., 32(7): 1820-1822, 1994.

[4] 4. England, J.J.; Poston, R.P. Electron microscopic identification and subsequent isolation of a rotavirus from a dog with fatal neonatal diarrhea. Am. J. Vet. Res., 41: 782-783, 1980.

[5] 5. Estes, M.K. Rotaviruses and their replication. In: Fields, B.N.; Knipe, D.M.; Howley, P.M.; Chanock, R.M.; Melnick, J.L.; Monath, T.P.; Roizman, B.; Straus, S.E. (eds.). Fields Virology, 3rd. ed., Lippincott-Raven, Philadelphia, 1996, p. 1625-1655.

[6] 6. Eugster, A.K.; Sidwa, T. Rotaviruses in diarrheic feces of a dog. Vet. Med. Small Anim. Clin., 74: 817-818, 1979.

[7] 7. Flewett, T.H.; Aries, C.F.; Avendano, L.F.; Ghafoor, A.; Mathan, M.M.; Mendis, L.; Moe, K.; Bishop, R.F. Comparative evaluation of the WHO and DAKOPATTS enzyme-linked immunoassay kits for the rotavirus detection. Bull. World Health Organ., 67: 369-374, 1989.

[8] 8. Flewett, T.H.; Woode, G.N. The rotaviruses. Arch. Virol., 57: 1-23, 1978.

[9] 9. Fulton, R.W.; Johnson, C.A.; Pearson, J.; Woode, G.N. Isolation of a rotavirus from a newborn dog with diarrhea. Am. J. Vet. Res., 42: 841-843, 1981.

[10] 10. Gentsch, J.R.; Glass, R.I.; Woods, P.; Gouvea, V.; Gorziglia, M.; Flores, J.; Bimal, K.D.; Bhan, M.K. Identification of group A rotavirus gene 4 types by polymerase chain reaction. J. Clin. Microbiol., 30(6): 1365-1373, 1992.

[11] 11. Gouvea, V.; Glass, R.I.; Woods, P.; Taniguchi, K.; Clark, H.F.; Forrester, B.; Fang, Z. Polymerase chain reaction amplification and typing of rotavirus nucleic acid from stool specimens. J. Clin. Microbiol., 28: 276-282, 1990.

[12] 12. Gouvea, V.; Santos, N.; Timenetsky, M.C. Identification of bovine and porcine rotavirus G types by PCR. J. Clin. Microbiol., 32: 1338-1340, 1994a.

[13] 13. Gouvea, V.; Santos, N.; Timenetsky, M.C. Vp4 typing of bovine and porcine group A rotaviruses by PCR. J. Clin. Microbiol., 32: 1333-1337, 1994b.

[14] 14. Homem, V.S.F.; Mendes, Y.G.; Linhares, A.C. Gastroenterite canina - agentes virais nas fezes de cães diarréicos e não diarréicos. Arq. Bras. Med. Vet. Zootec., 51(6): 531-536, 1999.

[15] 15. Hoshino, Y.; Wyatt, R.G.; Scott, F.W.; Appel, M.J. Isolation and characterization of a canine rotavirus. Arch. Virol., 72: 113-125, 1982.

[16] 16. Kapikian, A.Z.; Chanock, R.M. Rotaviruses. In: Fields, B.N.; Knipe, D.M.; Howley, P.M.; Chanock, R.M.; Melnick, J.L.; Monath, T.P.; Roizman, B.; Straus, S.E. (eds.), Fields Virology, 3rd. ed., Lippincott-Raven, Philadelphia, 1996, p. 1657-1708.

[17] 17. Laemmli, U.K. Cleavage of structural proteins during the assembly of head of bacteriophage T4. Nature, 227: 680-685, 1970.

[18] 18. Li, B.; Clark, H.F.; Gouvea, V. - Nucleotide sequence of VP4 - encoding gene of an unusual human rotavirus (HCR3). Virology, 196: 825-30, 1993.

[19] 19. Lourenço, M.H.; Nicolas, J.C.; Cohen, J.; Scherrer, R.; Bricout, F. Study of human rotavirus genoma by electrophoresis: attempt of classification among strains isolated in France. Ann. Virol. (Inst Pasteur) 132E: 161-73, 1981.

[20] 20. McNulty, M.S.; Allan, G.M.; Thompson, D.J.; O'Boyle, J.D. Antibody to rotavirus in dogs and cats. Vet. Rec., 102: 534-535, 1978.

[21] 21. Moosai, R.B.; Alcock, R.; Madeley, C.R. A cryptogram for recording rotavirus strains: the rotacode. J. Hyg., 93: 237-250, 1984.

[22] 22. Nakagomi, O.; Isegawa, Y.; Hoshino, Y.; Aboudy, Y.; Shif, I.; Silberstein, I.; Nakagomi, T.; Ueda, S.; Sears, J.; Flores, J. A new serotype of the outer capsid protein VP4 shared by an unusual human rotavirus strain Ro1845 and canine rotaviruses. J. Gen. Virol., 74: 2771-2774, 1993.

[23] 23. Nakagomi, T.; Nakagomi, O. Human rotavirus HCR3 possesses a genomic RNA constellation indistinguishable from that of feline and canine rotaviruses. Arch. Virol., 145: 2403-2409, 2000.

[24] 24. Nishikawa, K.; Hoshino, Y.; Taniguchi, K.; Green, K.Y.; Greenberg, H.B.; Kapikian, A.Z.; Chanock, R.M.; Gorziglia, M. Rotavirus VP7 neutralization epitopes of serotype 3 strains. Virology, 171: 503-511, 1989.

[25] 25. Pereira, H.G.; Azeredo, R.S.; Leite, J.P.; Andrade, Z.P.; De Castro, L. A combined enzyme immunoassay for rotavirus and adenovirus (EIARA). J. Virol. Meth., 10: 21-28, 1985.

[26] 26. Roseto, A.; Lema, F.; Cavalieri, F.; Dianoux, L.; Sitbon, M.; Ferchal, F.; Lasneret, J.; Peries, J. Electron microscopy detection and characterization of viral particles in dog stools. Arch. Virol., 66: 89-93, 1980.

[27] 27. Shirane, K.; Nakagomi, O. Interspecies transmission of animal rotaviruses to humans as evidenced by phylogenetic analysis of the hypervariable region of the VP4 protein. Microbiol. Immunol., 38: 823-826, 1994.

[28] 28. Taniguchi, K.; Urasawa, T.; Morita, Y.; Greenberg, H.B.; Urasawa, S. Direct serotyping of human rotavirus in stools using serotype 1-, 2-, 3- and 4-, specific monoclonal antibodies to VP7. J. Infec. Dis., 155: 1159-1166, 1987.

[29] 29. Taniguchi, K.; Urasawa, T.; Urasawa, S. Species specificity and interspecies relatedness in VP4 genotypes demonstrated by VP4 sequence analysis of Equine, Feline, and canine rotavirus strains. Virology, 200: 390-400, 1994.

[30] 30. Torres-Medina, A.; Wyatt, R.G.; Mebus, C.A.; Underdahl, N.R.; Kapikian, A.Z. Diarrhea caused in gnotobiotic piglets by the reovirus-like agent of human infantile gastroenteritis. J. Infec. Dis., 133: 22-27, 1976.

[31] 31. Timenetsky, M.C.; Santos, N.; Gouvea, V. Survey of rotavirus G and P types associated with human gastroenteritis in Sao Paulo, Brazil, from 1986 to 1992. J. Clin. Microbiol., 32: 2622-2624, 1994.

[32] 32. Tzipori, S. Human rotavirus in young dogs. Med. J. Aust., 2: 922-923, 1976.

[33] 33. Tzipori S, Makin T 1978. Propagation of human rotavirus in young dogs. Vet. Microbiol, 3: 55-63.

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