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Spread of vaccinia virus to cattle herds, Argentina, 2011.

To the Editor: Since 1999, several zoonotic outbreaks of vaccinia virus (VACV) infection have been reported in cattle and humans in rural areas of Brazil. The infections have caused exanthematous lesions on cows and persons who milk them, and thus are detrimental to the milk industry and public health services (1,2). In Brazil during the last decade, VACV outbreaks have been detected from the north to the extreme south of the country (1-4). Because Brazil shares extensive boundaries with other South American countries, humans and cattle on dairy and beef-producing farms in those countries may be at risk of exposure to VACV. To determine if VACV has spread from Brazil to Argentina, we investigated the presence of VACV in serum samples from cattle in Argentina.

During 2011, we obtained serum samples from 100 animals (50 dairy and 50 beef cattle) on farms in Cordoba, Corrientes, Entre Rms, and Santa Fe Provinces in Argentina (online Technical Appendix, panel A, http:// No VACV cases had been reported in humans or cattle in these provinces. However, Corrientes Province borders the Brazilian state of Rio Grande do Sul, where VACVs (Pelotas 1 and Pelotas 2 viruses) were isolated during an outbreak affecting horses in 2008 (2).

To determine the presence of neutralizing antibodies in the serum samples, we used an orthopoxvirus 70% plaque-reduction neutralization test as described (4). On the basis of previous studies that detected viral DNA in serum samples (4-6), we used realtime PCR to amplify the highly conserved orthopoxvirus vaccinia growth factor (vgf) gene DNA (P.A. Alves, unpub. methods).

To amplify the hemagglutinin (HA) gene DNA from the serum samples, we used real-time PCR with primers as described by de Souza Trindade et al. 2008 (7). The HA PCR products were directly sequenced in both orientations by using specific primers and capillary electrophoresis (Genetic Analyzer 3130; Applied Biosystems, Grand Island, NY, USA). We used ClustalW (http://www.clustal. org) and MEGA4 software (http:// to align nucleotide sequences and construct a phylogenetic tree (neighbor-joining method, 1,000 bootstraps) from the obtained HA fragment.

Of the 50 dairy cattle samples, 4 (8.0%) had neutralizing antibodies against orthopoxvirus; of these, 3 (75.0%) had titers of 100 neutralizing units (NU)/mL, and 1 (25.0%) had a titer of 400 NU/mL. Of the 50 beef cattle, 8 (16.0%) had antibodies to orthopoxvirus, 1 (12.5%) of which had a titer of 800 NU/mL. Most of the positive samples were from cattle in Corrientes and Entre Rms Provinces (Table).

Of the 100 serum samples, 5 (3 from beef and 2 from dairy cattle) were positive for vgf by real-time PCR. HA DNA was amplified from 2 of the 3 vgf PCR-positive beef cattle samples; plaque-reduction neutralization test results were also positive for the 2 samples (Table).

Alignment of the HA fragment nucleotide sequence of the isolates from Argentina showed that the sequence was highly similar to that of the homologous gene of VACV isolates from Brazil. Furthermore, the sequences showed a signature deletion that is also present in the sequences of VACV isolates from Brazil. Compared with sequences for other VACV isolates, those from Argentina had 2 polymorphisms (online Technical Appendix, panel C). The HA sequences from the isolates from Argentina demonstrated 100% identity among themselves and exhibited higher identity with group 1 (98.2% identity) versus group 2 (93.6% identity) isolates from Brazil (online Technical Appendix, panel D). In the phylogenetic tree based on the HA nucleotide sequences (online Technical Appendix, panel B), the VACVs from Argentina clustered with several group 1 VACVs detected during outbreaks in Brazil.

Although no outbreaks of exanthematous VACV infection have been described in cattle or humans in Argentina, we detected neutralizing antibodies against orthopoxvirus and detected VACV DNA in serum samples from cattle in the country. Most of the seropositive samples were from cattle in Entre Rms Province, which shares a border with Uruguay, and Corrientes Province, which shares a border with Rio Grande do Sul State in Brazil, where Pelotas VACVs have been isolated (2).

We believe that the seropositive cattle in this study may have been exposed to VACV, the only orthopoxvirus known to be circulating in South America (1-4,8-10). Despite veterinary surveillance efforts of border control organizations, VACV control may be hampered by the circulation of infected rural workers and the misdiagnosis of VACV infection; misdiagnoses occur because VACV lesions resemble those of other exanthematous diseases. Moreover, peridomestic rodents have been hypothesized to act as VACV hosts, and could facilitate the spread of VACV in border areas (10). In addition, we could not rule out the circulation of autochthonous VACV in Argentina, but this is a less likely explanation. Our findings suggest that cattle herds in areas of Argentina near the border with Brazil may be exposed to VACV from Brazil and, thus, may be at risk for VACV infection. Further research is needed to determine the risk factors for VACV infection and to assess the circulation of VACV in South America


We thank Joao Rodrigues dos Santos, Angela Sana Lopes, Ilda Gama, and colleagues from the Laboratorio de Vans for their excellent technical support.

Financial support was provided by the Conselho Nacional de Desenvolvimento Cientlfico e Tecnologico (CNPq), Coordenafao de Aperfeifoamento de Pessoal de Mvel Superior (CAPES), Fundafao de Amparo a Pesquisa do Estado de Minas Gerais (FAPEMIG), and Ministerio da Agricultura, Pecuaria e Abastecimento (MAPA). A.P.M. F.-L. was the recipient of a fellowships from CAPES, and E.G.K., C.A.B., G.S.T., and P.C.P.F. were recipients of fellowships from CNPq.

Ana Paula Moreira Franco-Luiz, Alexandre Fagundes-Pereira, Galileu Barbosa Costa, Pedro Augusto Alves, Danilo Bretas Oliveira, Claudio Antonio Bonjardim, Paulo Cesar Peregrino Ferreira, Giliane de Souza Trindade, Carlos Javier Panei, Cecilia Monica Galosi, Jonatas Santos Abrahao, and Erna Geessien Kroon

Author affiliations: Universidade Federal de Minas Gerais, Belo Horizonte, Brazil (A.P.M. Franco-Luiz, A. Fagundes-Pereira, G.B. Costa, P.A. Alves, D.B. Oliveira, C.A. Bonjardim, P.C.P. Ferreira, G.S. Trindade, J.S. Abrahao, E.G. Kroon); Universidad Nacional de la Plata, Buenos Aires, Argentina (C.J. Panei, C.M. Galosi); Consejo Nacional Investigaciones Cienhficas y Tecnicas, Buenos Aires (C.J. Panei); and Comision de Investigaciones Cientfficas Provincia de Buenos Aires,, Buenos Aires (C.M. Galosi)



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(2.) Campos RK, Brum MC, Nogueira CE, Drumond BP, Alves PA, Siqueira-Lima L, et al. Assessing the variability of Brazilian vaccinia virus isolates from a horse exanthematic lesion: coinfection with distinct viruses. Arch Virol. 2011; 156:275-83.

(3.) Mota BEF, Trindade GS, Diniz TC, da Silva-Nunes M, Braga EM, UrbanoFerreira M, et al. Seroprevalence of orthopoxvirus in an Amazonian rural village, Acre, Brazil. Arch Virol. 2010; 155:113944.

(4.) Abrahao JS, Silva-Fernandes AT, Lima LS, Campos RK, Guedes MI, Cota MM, et al. Vaccinia virus infection in monkeys, Brazilian Amazon. Emerg Infect Dis. 2010; 16:976-9. 10.3201/eid1606.091187

(5.) Cohen JI, Hohman P, Preuss JC, Li L, Fischer SH, Fedorko DP, et al. Detection of vaccinia virus DNA, but not infectious virus, in the blood of smallpox vaccine recipients. Vaccine. 2007; 25:4571-4. 03.044

(6.) Savona MR, Dela Cruz WP, Jones MS, Thornton JA, Xia D, Hadfield TL, et al. Detection of vaccinia DNA in the blood following smallpox vaccination. JAMA. 2006; 295:1895-900. 10. 1001/jama.295.16.1898

(7.) de Souza Trindade G, Li Y, Olson VA, Emerson G, Regnery RL, da Fonseca FG, et al. Real-time PCR assay to identify variants of vaccinia virus: implications for the diagnosis of bovine vaccinia in Brazil. J Virol Methods. 2008; 152: 63-71. 2008.05.028

(8.) Damon IK. Poxviruses. In: Knipe DM, Howley PM, Griffin DE, Lamb RA, Martin MA, Roizman B, et al., editors. Fields virology. Vol II. 5th ed. Philadelphia: Lippincott Williams and Wilkins; 2007. p. 2947-75.

(9.) Trindade GS, Emerson GL, Carroll DS, Kroon EG, Damon IK. Brazilian vaccinia viruses and their origins. Emerg Infect Dis. 2007; 13:965-72. http://dx.doi. org/10.3201/eid1307.061404

(10.) Abrahao JS, Guedes MI, Trindade GS, Fonseca FG, Campos RK, Mota BF, et al. One more piece in the VACV ecological puzzle: could peridomestic rodents be the link between wildlife and bovine vaccinia outbreaks in Brazil? PLoS ONE. 2009; 4:e7428. journal.pone.0007428

Address for correspondence: Erna G. Kroon, Laboratorio de Virus, Departamento de Microbiologia, Instituto de Ciencias Biologicas, Universidade Federal de Minas Gerais, Av. Antonio Carlos, 6627, Caixa Postal 486, CEP 31270-901, Belo Horizonte, Minas Gerais, Brazil; email:
Table. Diagnosis of Orthopoxvirus infection in beef and dairy cattle
during a study of the spread of vaccinia virus to cattle herds,
Argentina, 2011 *

                                                     No. serum
                                   No. farms          samples
                                    sampled           tested
Province      Cattle type

Cordoba          Dairy                 1                25
Santa Fe         Dairy                 1                25
Corrientes        Beef        >2 ([double dagger])       8
Entre Rios        Beef                 5                42
Total        Dairy and beef            >9               100

             No. positive samples, by level of NU/mL
                 against orthopoxvirus ([dagger])

Province     100   200   400   800   Total (%)

Cordoba       0     0     1     0     1 (4.0)
Santa Fe      3     0     0     0    3 (12.0)
Corrientes    0     1     1     0    2 (25.0)
Entre Rios    2     2     1     1    6 (14.3)
Total         5     3     3     1    12 (12.0)

                    No. (%) positive by real-time

Province             vgf                     HA

Cordoba            2 (8.0)                   0
Santa Fe              0                      0
Corrientes   1 (12,5) ([section])   1 (12,5) ([section])
Entre Rios         2 (4,8)          1 (2,4) ([section])
Total              5 (5.0)                2 (2.0)

* HA, hemagglutinin gene DNA;  NU, serum dilution at which 70% plaque
reduction per mL occurs;  vgf, orthopoxvirus vaccinia growth factor
gene DNA.

([dagger]) Determined by plaque-reduction neutralization test.

([double dagger]) Samples were obtained from several farms in
Corrientes Province.

([section]) Animal was also positive by plaque-reduction
neutralization test.
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Title Annotation:LETTERS
Author:Franco-Luiz, Ana Paula Moreira; Fagundes-Pereira, Alexandre; Costa, Galileu Barbosa; Alves, Pedro Au
Publication:Emerging Infectious Diseases
Article Type:Letter to the editor
Date:Sep 1, 2014
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