Análise filogenética de isolados do vírus da raiva de herbívoros na fronteira de Minas Gerais e São Paulo (2000-2009), Brasil

Estévez Garcia, Andrea I.; Peixoto, Haila C.; Silva, Sheila O.; Polo, Gina; Alves, Ana J.; Brandão, Paulo E.; Cunha, Elenice M.; Richtzenhain, Leonardo J.

doi:10.1590/S0100-736X2014001200009

Resumos

A raiva transmitida por morcegos hematófagos da espécie Desmodus rotundus representa uma preocupação de saúde pública e causa de importantes prejuízos para a pecuária brasileira. A evidência atual sugere que a ocorrência de raiva está relacionada às características da paisagem, topografia, hidrografia, sistemas de produção animal e usos da terra. Contudo, existem poucos estudos que analisem as possíveis conexões entre fatores geográficos e a diversidade molecular do vírus da raiva, permitindo a compreensão da dinâmica espacial e temporal dos focos de raiva. Um desses trabalhos estabeleceu que a última epizootia de raiva dos herbívoros registrada no leste do estado de São Paulo (na fronteira com Minas Gerais), aconteceu em duas ondas epidêmicas, sendo a primeira em 1998 e, em 1999, a segunda. Considerando esta evidência, o intuito do presente estudo foi analisar casos de raiva em herbívoros na região sudeste de Minas Gerais (2000-2009) e sua possível relação com a epidemia previamente mencionada, incluindo as características geográficas da região. Foram obtidas sequencias parciais dos genes da glicoproteína (539 nt) e da nucleoproteína (414 nt) a partir de 31 isolados de vírus da raiva procedentes de herbívoros. Foi proposta uma árvore filogenética para cada região genômica usando o método de Neighbor joining, fixando o modelo evolutivo Kimura 2 - parâmetros com um nível de bootstrap de 1000 replicações. As sublinhagens genéticas foram localizadas sobre mapas, considerando as áreas de risco para raiva dos herbívoros em São Paulo, assim como as características topográficas e bacias hidrográficas com o intuito de visualizar qualquer padrão aparente de distribuição segundo essas características. As duas árvores filogenéticas mostraram topologias concordantes, sugerindo uma possível origem comum para os surtos que aconteceram ao longo da fronteira SP/MG, ao redor das porções menos elevadas da Serra da Mantiqueira e acompanhando as bacias hidrográficas dos rios Piracicaba/Jaguarí, Paranaíba do Sul, Grande, Pardo e Mogi-Guaçu. Foi possível observar circulação de varias linhagens virais simultaneamente em alguns municípios, possivelmente por causa de sobreposição de surtos. As sequencias de proteína inferidas a partir dos dois genes mostraram mutações sinônimas, excetuando aquelas encontradas entre os resíduos 20 a 200, correspondentes ao domínio externo da glicoproteína. Esta informação salienta a importância da cooperação entre as autoridades sanitárias de ambos os estados para reforçar o programa de controle da doença nas áreas limítrofes.

Desmodus rotundus; raiva; glicoproteína; nucleoproteína; análise de sequencias; DNA

Rabies transmitted by the hematophagous bat Desmodus rotundus represents a public health concern and a burden for the Brazilian livestock industry. Current evidence suggests that rabies occurrence is related to landscape characteristics, topography, hydrography, animal production systems and land use. However, a few studies have analyzed the possible connections among geographic factors and the molecular diversity of the rabies virus, furthering the understanding of the spatial and temporal dynamics of outbreaks. A study reported that the latest rabies epizootics in herbivores reported in the eastern region of São Paulo (close to the Minas Gerais border) occurred in two epidemic waves; the first was before 1998, and the other occurred after 1999. Using this evidence, the aim of the present study was to analyze cases of rabies in herbivores in the southern region of Minas Gerais (2000-2009) and their possible relationship with the aforementioned epidemics, considering the geographic characteristics of the region. Partial sequences of glycoprotein (539 nt) and nucleoprotein genes (414 nt) were obtained from 31 rabies virus isolates from herbivores. A phylogenetic tree was proposed for each genomic region using the Neighbor joining method, fixing the Kimura 2-parameter evolution model with a bootstrap level of 1,000 replications. Genetic sublineages were plotted on maps, considering rabies risk areas for herbivores in São Paulo, as well as topographic characteristics and hydrographic basins, to visualize any apparent distribution pattern influenced by those features. The phylogenetic trees had concordant topologies, suggesting a possible common origin for rabies outbreaks in herbivores along the SP/MG border, surrounding the less elevated portions of the Serra da Mantiqueira and along the hydrographic basins of Piracicaba/Jaguarí, Paranaíba do Sul, Grande, Pardo and Mogi-Guaçu rivers.The co-circulation of several viral lineages was observed in some municipalities, possibly due to an overlapping of rabies outbreaks. Inferred protein sequences of both genes showed synonymous mutations, except among residues 20 to 200, corresponding to the external domain of the glycoprotein. This information prompted cooperation among the animal health services of both states to reinforce rabies control in the border area.

Desmodus rotundus; rabies; glycoprotein; nucleoprotein; sequence analysis; DNA

ANIMAIS DE PRODUÇÃO/LIVESTOCK DISEASES

Phylogenetic analysis of rabies virus isolated from herbivores in Minas Gerais and São Paulo border (2000-2009), Brazil

Análise filogenética de isolados do vírus da raiva de herbívoros na fronteira de Minas Gerais e São Paulo (2000-2009), Brasil

Andrea I. Estévez Garcia^I^* * Corresponding author: isaestgar@yahoo.com ; Haila C. Peixoto^I; Sheila O. Silva^I; Gina Polo^I; Ana J. Alves^I; Paulo E. Brandão^I; Elenice M. Cunha^II; Leonardo J. Richtzenhain^I

^IDepartamento de Medicina Veterinária Preventiva e Saúde Animal, Faculdade de Medicina Veterinária e Zootecnia (FMVZ), Universidade de São Paulo (USP), Avenida Professor Dr. Orlando Marques de Paiva 87, Cidade Universitária, São Paulo, SP 05508-270, Brazil. E-mails: hailachagas@hotmail.com, sheilacateq@yahoo.com.br, imaginapolo@gmail.com, ajulia.vet@gmail.com, paulo7926@yahoo.com, leonardo@usp.br; ^IILaboratório de Raiva e Encefalites Virais, Instituto Biológico de São Paulo, Av. Conselheiro Rodrigues Alves 1252, Vila Mariana, São Paulo, SP 04014-002, Brazil. E-mail: cunha@biologico.sp.gov.br

ABSTRACT

Rabies transmitted by the hematophagous bat Desmodus rotundus represents a public health concern and a burden for the Brazilian livestock industry. Current evidence suggests that rabies occurrence is related to landscape characteristics, topography, hydrography, animal production systems and land use. However, a few studies have analyzed the possible connections among geographic factors and the molecular diversity of the rabies virus, furthering the understanding of the spatial and temporal dynamics of outbreaks. A study reported that the latest rabies epizootics in herbivores reported in the eastern region of São Paulo (close to the Minas Gerais border) occurred in two epidemic waves; the first was before 1998, and the other occurred after 1999. Using this evidence, the aim of the present study was to analyze cases of rabies in herbivores in the southern region of Minas Gerais (2000-2009) and their possible relationship with the aforementioned epidemics, considering the geographic characteristics of the region. Partial sequences of glycoprotein (539 nt) and nucleoprotein genes (414 nt) were obtained from 31 rabies virus isolates from herbivores. A phylogenetic tree was proposed for each genomic region using the Neighbor joining method, fixing the Kimura 2-parameter evolution model with a bootstrap level of 1,000 replications. Genetic sublineages were plotted on maps, considering rabies risk areas for herbivores in São Paulo, as well as topographic characteristics and hydrographic basins, to visualize any apparent distribution pattern influenced by those features. The phylogenetic trees had concordant topologies, suggesting a possible common origin for rabies outbreaks in herbivores along the SP/MG border, surrounding the less elevated portions of the Serra da Mantiqueira and along the hydrographic basins of Piracicaba/Jaguarí, Paranaíba do Sul, Grande, Pardo and Mogi-Guaçu rivers.The co-circulation of several viral lineages was observed in some municipalities, possibly due to an overlapping of rabies outbreaks. Inferred protein sequences of both genes showed synonymous mutations, except among residues 20 to 200, corresponding to the external domain of the glycoprotein. This information prompted cooperation among the animal health services of both states to reinforce rabies control in the border area.

Index terms:Desmodus rotundus, rabies, glycoprotein, nucleoprotein, sequence analysis, DNA.

RESUMO

A raiva transmitida por morcegos hematófagos da espécie Desmodus rotundus representa uma preocupação de saúde pública e causa de importantes prejuízos para a pecuária brasileira. A evidência atual sugere que a ocorrência de raiva está relacionada às características da paisagem, topografia, hidrografia, sistemas de produção animal e usos da terra. Contudo, existem poucos estudos que analisem as possíveis conexões entre fatores geográficos e a diversidade molecular do vírus da raiva, permitindo a compreensão da dinâmica espacial e temporal dos focos de raiva. Um desses trabalhos estabeleceu que a última epizootia de raiva dos herbívoros registrada no leste do estado de São Paulo (na fronteira com Minas Gerais), aconteceu em duas ondas epidêmicas, sendo a primeira em 1998 e, em 1999, a segunda. Considerando esta evidência, o intuito do presente estudo foi analisar casos de raiva em herbívoros na região sudeste de Minas Gerais (2000-2009) e sua possível relação com a epidemia previamente mencionada, incluindo as características geográficas da região. Foram obtidas sequencias parciais dos genes da glicoproteína (539 nt) e da nucleoproteína (414 nt) a partir de 31 isolados de vírus da raiva procedentes de herbívoros. Foi proposta uma árvore filogenética para cada região genômica usando o método de Neighbor joining, fixando o modelo evolutivo Kimura 2 - parâmetros com um nível de bootstrap de 1000 replicações. As sublinhagens genéticas foram localizadas sobre mapas, considerando as áreas de risco para raiva dos herbívoros em São Paulo, assim como as características topográficas e bacias hidrográficas com o intuito de visualizar qualquer padrão aparente de distribuição segundo essas características. As duas árvores filogenéticas mostraram topologias concordantes, sugerindo uma possível origem comum para os surtos que aconteceram ao longo da fronteira SP/MG, ao redor das porções menos elevadas da Serra da Mantiqueira e acompanhando as bacias hidrográficas dos rios Piracicaba/Jaguarí, Paranaíba do Sul, Grande, Pardo e Mogi-Guaçu. Foi possível observar circulação de varias linhagens virais simultaneamente em alguns municípios, possivelmente por causa de sobreposição de surtos. As sequencias de proteína inferidas a partir dos dois genes mostraram mutações sinônimas, excetuando aquelas encontradas entre os resíduos 20 a 200, correspondentes ao domínio externo da glicoproteína. Esta informação salienta a importância da cooperação entre as autoridades sanitárias de ambos os estados para reforçar o programa de controle da doença nas áreas limítrofes.

Termos de Indexação:Desmodus rotundus, raiva, glicoproteína, nucleoproteína, análise de sequencias, DNA.

INTRODUCTION

Rabies transmitted by hematophagous bat Desmodus rotundus represents a public health concern and has been a burden to the Brazilian livestock industry since 1911, when the first rabies outbreak in bovines and equines was officially reported in the south of the country. Since then, rabies has exhibited endemic, epidemic and sporadic presentation in Brazil (Brasil 2009). Two studies have addressed rabies prevalence in Minas Gerais. The first consisted of a regression analysis of cases reported from 1976 to 1997. The study allowed the detection of the annual growing prevalence of rabies with outbreaks in 75% of the municipalities. Additionally, a geographic pattern was observed, spreading from "Triângulo Mineiro" to the center and south/southeast regions and from the "Zona da Mata" toward the North of the State (Silva et al. 2001). The second study included surveillance data from 1998 to 2006. During this period, the number of positive municipalities fluctuated, but there was an overall decreasing trend (Menezes et al. 2008).

It is believed that the drastic environmental transformations that occurred in the south and southeast regions of Minas Gerais due to the substitution of forests by pastures for livestock may have facilitated rabies dispersion in urban and rural ecosystems (Silva et al. 2001).

Regarding São Paulo, it is well documented that mountainous regions are more prone to shelter D. rotundus, due to favorable conditions, such as the higher rainfall index and milder temperatures (Gomes, 2011). Considering the existence of different degrees of rabies risk in livestock according to geographic areas, Animal Health authorities divided the State into epidemic, endemic and sporadic areas. The western region of São Paulo is classified as sporadic and the eastern region is epidemic, particularly the border between Minas Gerais and São Paulo along the Paraíba do Sul basin (Peres, 2008).

Current evidence suggests that rabies occurrence depends on several factors such as landscape characteristics, topography, hydrography, animal production systems and land use (Grenfell et al. 2004). River basins constitute one of the most important factors related to the presence of D. rotundus (Tadei et al. 1991).

In Brazil, few studies have explored the possible connections among geographic factors and the molecular diversity of the rabies virus. One study suggested that six main genetic lineages with molecular differences occur in São Paulo and Minas Gerais and that their distribution is apparently affected by rivers, chains of mountains and specific biomes (Kobayashi et al. 2008). Interestingly, an analysis of rabies virus sequences from both states, reveals that their viral subpopulations are closely related (Macedo et al. 2010). In contrast, other studies propose that geographic factors are not always involved in the genetic diversification of the rabies virus (Heinemann et al. 2002).

These types of studies are valuable because they help track the spatial and temporal dynamics of outbreaks by taking advantage of the mutation rate of the rabies virus. These mutations emerge as consequence of the interactions between the virus and its animal hosts, and because of ecological and geographical aspects that shape the distribution of the host populations (Nadin-Davis 2007, Real et al. 2005, Wunner 2007). Analyzing the phylogenetic relationships among rabies virus isolates also provides a more detailed way to comprehend epizootic dynamics; one example is a study by Carnieli et al. (2009); who examined evolutionary changes in glycoprotein and nucleoprotein genes of the rabies virus during the most recent epizootics between 1997 and 2002, in the eastern region of São Paulo, near the Minas Gerais border. Their results suggest that this event occurred in two epidemic waves, with the first occurring before 1998 and the second after 1999.

Considering this background, the aim of the present study was to genetically characterize 31 rabies virus isolates from herbivores in the southern region of Minas Gerais (2000-2009), explore possible relationships between these cases and São Paulo’s latest epizootics, considering the main geographic characteristics of the region, as well as compare these sequences with those from other cases in different regions of Brazil.

MATERIALS AND METHODS

Samples were selected by convenience to address the molecular epidemiology of the rabies virus at the border of Minas Gerais and São Paulo after the most recent epizootics in São Paulo state (1997-2002). The samples consisted of 31 confirmed rabies cases in bovines and equines from 13 municipalities of the Minas Gerais, Brazil. Figure 1 shows the geographical origin of the rabies cases studied.

Samples were submitted to a previous screening by the Direct Fluorescence Test and a mouse inoculation test, both performed at Instituto Biologico de São Paulo. All procedures followed ethical guidelines from the animal experimentation committee at its respective institution.

RNA extraction was executed using the guanidinium thiocyanate-phenol-chloroform method according to the manufacturer´s instructions. Reverse transcription (RT) and polymerase chain reaction (PCR) as well as sequencing reactions were performed using primers for glycoprotein gene [(sense-GA (5´ CGCTGCATTTTRTCARAGT 3´) and antisense –GB (5´ GAGGGCACCATTTGGTMTC 3´)], and a DNA product of 914 nucleotides was obtained (Sato et. al. 2004). For the nucleoprotein gene, primers [sense-21G (5´ ATGTAACACCTCTACAATG 3´) and antisense-304 (5´ TTGACGAAGATCTTGCTCAT 3´)], were used, and a product of 1,478 nucleotides was obtained (Orciari et al., 2001). The reactions were executed separately for each gene. For RT, 3.5µL of RNA were used in 2µL 5X First Strand Buffer, 1µL of dNTPs (10 mM), 1µL DTT (100 mM), 1µL of each primer (10mM), 0.5µL Reverse Transcriptase MMLV (200 U/µL) for a final reaction volume of 10µL. The RT reaction was performed at 42°C for 60 minutes. The PCR reactions contained 5µL cDNA, 5µL 10X PCR Buffer, 8µL dNTPs (1.25 Mm), 1.5µL MgCl₂ (50mM), 2.5µL of each primer (10mM), 25.25µL DEPEC water and 0.25µL Taq DNA polymerase (5 U/µL), for a final reaction volume of 50µL. PCR was performed by following these steps: 1 cycle at 94°C for five minutes (denaturation), 35 cycles at 94°C for 45 seconds (denaturation), 35 cycles at 55°C for 45 seconds (annealing), 35 cycles at 72°C for 2 minutes (extension), 1 cycle at 72°C for 2 minutes (extension). PCR products were subjected to agarose (1.5%) gel electrophoresis in TBE buffer 1X (0.1 M Tris, 0.09 Boric Acid, 0.001 M EDTA, containing Ethidium bromide 0.45mg/mL). Samples were considered positive if fragments of 914pb for gene G and 1478 for gene N were visualized as clearly defined single bands under UV light. To purify the DNA products, exonuclease with shrimp alkaline phosphatase was used according to the manufacturer´s instructions. Briefly, for each 5µL DNA, 2 µL of the enzymatic mix was used and incubated at 37°C for 15 minutes. The enzymes were inactivated at 80°C for 15 minutes before sequencing.

DNA sequencing was performed using the dideoxy method (Sanger method) by capillary electrophoresis. Briefly, 6µL of DNA template (approx. 30-50ng) was used for each sample in 2µL of di-deoxy fluorescent-labeled nucleotides, 1.5µL of 5X sequence buffer (containing DNA polymerase and nucleotides), 0.5µL of each primer (10 Mm), for a final reaction volume of 10µL. Two different mixes were prepared for each sample, one including the sense primer and the other including the antisense primer. The sequence program included the following steps: 35 cycles at 96°C for 10 seconds, 50°C for 5 seconds, and 60°C for 4 minutes.

DNA sequences with marked nucleotides were purified by precipitation, using 5 µL of EDTA 125 mM and 60 µL pure ethanol for each 10µL of sequencing reaction in 500µL microtubes. Samples were gently agitated, incubated at room temperature for 15 minutes (protected from light), and centrifuged at 16500g for 45 minutes at 4°C. The supernatant was discarded by inversion. The resulting pellet was washed with ethanol 70% (milliQ water) at 16500g for 15 minutes at 4°C, the supernatant was discarded and the ethanol residues were completely evaporated by heating the microtubes at 95°C for 5 minutes.

Precipitated DNA was resuspended in 10µL HI-DI formamide and transferred to a 96-well plate, denaturated at 95°C for 2 minutes and finally read on an ABI3500 automatic sequencer.

The quality of sequences was evaluated using FINCH TV software, version 1.4.0 (Geospiza, Inc.; Seattle, WA, USA; http://www.geospiza.com) and the PHRED application (Embrapa, Genetic Resources and Biotechnology, Brazil; http://asparagin.cenargen.embrapa.br/phph/). Only nucleotides with a probability higher than 90% and a quality index greater than 21 were accepted in the final sequence. Less reliable segments were removed using the BioEdit (version 5.0.6) software (Hall, 1999). After the execution of capping/contig with Clustal W (version 1.83 incorporated to BioEdit 5.0.6), the polarity and identity of sequences were verified by blasting (http://blast.ncbi.nlm.nih.gov).

Two phylogenetic trees were constructed: the first was based on a 539 nucleotide fragment of glycoprotein, and the second was based on a 414 nucleotide fragment of a nucleoprotein gene. The sequences used for the phylogenetic analysis of the glycoprotein (n= 109) and nucleoprotein genes (n=142) were retrieved from GenBank and randomly selected. We tried to include at least three members of each genetic sublineage, representing different natural regions of Brazil and animal hosts, as described by Carnieli et al. (2009) Heinemann et al. (2002), Ito et al. (2003), Kobayashi et al. (2005, 2008), Macedo et al. (2010), Sato et al. (2004, 2006 and unpublished, available in http://www.ncbi.nlm.nih.gov/nuccore/AB276308 ), Tordo et al., (1986). Disparities in the number of sequences used for each gene were a consequence of the different numbers of sublineages described in the literature and the availability of data in GenBank for each genomic segment. The geographic origin of São Paulo sequences retrieved from the Internet is detailed in Figure 1.

These sequences were included in the analysis to explore a possible genetic relationship of the Minas Gerais cases with previous and contemporary cases that occurred in São Paulo. Sequence alignments were performed with Clustal W (version 1.83) and trees were inferred using the neighbor-joining method with MEGA software (version 4) (Tamura et al. 2007), fixing the Kimura 2-parameter evolution model with a bootstrap level of 1,000 replications. Bootstrap values exceeding 70% were considered to indicate phylogenetic association. The cases in Minas Gerais studied here, in addition to all of the cases considered in both genetic analyses, were plotted on maps using ArcGis 10.2 (Environmental System Research Institute, Inc., Redlands, CA, USA), considering rabies risk areas for herbivores in São Paulo, as described by Peres (2008), and the topographic characteristics and hydrographic basins to visualize whether some genetic lineages had a trend to circulate in certain regions according the epidemiological status and key geographical features of the areas under study, as described by Kobayashi et al. (2008).

RESULTS

DNA amplicons of 914 nt and 1,478 nt of glycoprotein gene and nucleoprotein gene, respectively, were obtained after sequencing. In spite of several attempts to improve sequencing performance, it was not possible to use the full-length amplicons because of the poor-quality indexes obtained during the stringent evaluation process. The sequences were trimmed to consider only the reliable segments, as described above.

After editing the DNA sequences, two different genomic regions of rabies virus were obtained and analyzed independently: a glycoprotein gene fragment with a length of 539 nucleotides (positions from nucleotides 3,378 to 3,917 according to the Pasteur Virus complete genome; GenBank Accession number M13215), encoding for the glycoprotein external domain, and a 414 nucleotide fragment from the nucleoprotein gene (positions from nucleotides 299 to 712). The sequences were deposited into GenBank under accession numbers KF805574 to KF805627.

Figures 2 and 3 show the phylogenetic trees based on the glycoprotein and nucleoprotein gene analysis, respectively.

Figure 3

Relevant information regarding the animal hosts, the chronology, the geographic origin and distribution of the rabies isolates is detailed below. Figure 2 shows the two main lineages according to the glycoprotein gene, labeled I and II. Lineage I is composed of Brazilian rabies viruses isolated from livestock and bats (hematophagous and non-hematophagous). Lineage II contains clusters of Brazilian rabies viruses from humans, dogs, cats and pigs. Lineage I showed several genetic sublineages designated as Ia to Ie as follows. Sublineage Ia contains rabies virus isolates from the epidemic area of São Paulo (1999-2008) and the southeastern border of Minas Gerais (2000-2009), including two from Artibeus lituratus in the sporadic area (the municipality of Dracena, in 2002, AB496680). Sublineage Ib includes bovine and vampire bat samples from the epidemic and endemic areas of São Paulo (f989-2004) and sequences from frugivorous bats from the sporadic (1998 and 2003) and endemic areas (1994). Sublineage Ic contains cases that occurred in the epidemic area of São Paulo (1995-2004), the endemic area (1992), the sporadic area (1998), and two sequences from the Rio de Janeir(1997 and 1998). Sublineage Id contains three cases from Tocantins and one from Maranhão. Sublineage Ie contains cases from Maranhão and Paraíba. Lineage II is comprised of genetic sublineages IIa and IIb as follows. Sublineage IIa contains dog (Maranhão) and human (Rio de Janeiro) viruses. Sublineage IIb contains viruses from carnivores and humans (unknown geographic origin), humans and dogs (Goiás), and pigs (Paraná).

Figures 4 and 5 show the geographical distribution of the genetic sublineages described in the phylogenetic analysis for glycoprotein and nucleoprotein genes, respectively, according to the risk areas for rabies in São Paulo.

In these maps, only the information concerning the area under study (São Paulo/Border of Minas Gerais with São Paulo) is illustrated. No data were available regarding the risk areas in Minas Gerais.

The amino acid sequences were inferred from the nucleotide sequences with BioEdit software. Several non-synonymous substitutions were observed in the glycoprotein sequence among residues 20 to 200 and in the nucleoprotein sequences among residues 77 to 214.

The cases analyzed in the present study occurred along southern border of Minas Gerais with São Paulo, coinciding with a chain of mountains named Serra da Mantiqueira. This region presents a topographic mosaic with altitudes ranging from 200 to 1500 meters. Figures 6 and 7 show that all of the cases studied here occurred in the less elevated portions of the Serra da Mantiqueira (600-1,000m above sea level), which belongs to an extensive area of the Atlantic forest biome that is irrigated primarily by the Piracicaba-Jaguarí, Paranaíba do Sul, Grande, Pardo and Mogi-Guaçu river basins.

DISCUSSION

Both phylogenetic trees suggested that the cases from Minas Gerais (2000-2009) most likely have the same genetic origin as the São Paulo epizootics. Phylogeny based on the glycoprotein gene establishes a closer relationship between the sequences obtained in the present study and the cases that occurred after 1999 because they are included in the same clade. The topologies of both phylogenetic trees are mutually consistent, reinforcing the hypothesis of a possible common origin; moreover, the glycoprotein and nucleoprotein genes of

the rabies virus circulating in the livestock and bats of this geographic area are highly conserved, as previously stated by Carnieli et al (2009).

Regarding the polymorphism analysis, only seven, non-synonymous amino acid substitutions in residues 20 to 200 were detected in the external domain of the glycoprotein. This region is the most conserved portion of the glycoprotein, primarily because of structural restrictions (Benmansour et al. 1992, Kissi et al. 1995). All mutations detected in the nucleoprotein gene were synonymous.

Although sublineage Ia (according to the glycoprotein and nucleoprotein genes) is predominant in the epidemic area, there is spatial and chronological overlapping with other subpopulations of rabies viruses. This observation was previously reported by Kobayashi et al. (2008). In addition, in some municipalities, there are two or three viral lineages circulating simultaneously (e.g.., Itapira, Mococa, Morungaba, Pindamonhangaba, Salesópolis, Socorro, Taubaté and Vargem Grande Paulista). A similar behavior in rabies virus isolates from different species of non-hematophagous bat was found in Argentina, where the municipalities of Santa Fé, and Rosario, among others, showed co-circulation of multiple virus lineages (Piñero et al. 2012).

Conversely, the opposite situation can be observed when the same genetic sublineage is found at distant geographic points. One example is sublineage Ia (based on the glycoprotein gene analysis); this lineage was circulating in bovine and D. rotundus from municipalities in the epidemic area and was found in one frugivorous bat (Artibeu lituratus) in Dracena in the sporadic area, 690 km away from the epidemic area. Although there is a close phylogenetic relationship among D. rotundus and A. lituratus rabies virus isolates in some cases, according to Shoji et al. (2004), new evidence suggests that it is possible that the presence of species-specific genetic lineages can adapt to certain hosts. The occurrence of the same lineages of rabies virus isolates from non-hematophagous bats circulating in non-adjacent locations reported by Kobayashi et al. (2005) supports this idea and was subsequently confirmed by Oliveira et al. (2010) and Fahl et al. (2012). Sublineage Id, showed a similar behavior (based on the nucleoprotein gene analysis).

Regarding to maps of the geographic distribution of genetic lineages according to risk areas, only Sublineage Ia (glycoprotein and nucleoprotein) showed an apparent tendency to circulate in epidemic regions.

The distribution of several clusters is separated by geographic boundaries such as mountain ranges. Another interesting finding is that several cases involving the same sublineage were distributed along the same river (Kobayashi et al. 2008). The results of the present study are discordant with the first statement and compatible with the second one because sublineage Ia was observed across the Serra da Mantiqueira. A possible explanation is that bat colonies could have moved between São Paulo and Minas Gerais using the less elevated areas as a corridor. The presence of rabies cases along Piracicaba-Jaguarí, Paranaíba do Sul, Grande, Pardo and Mogi-Guaçu river basins agrees with other researchers, who reported a similar epidemiological behavior for this region (Tadei 1991, Trajano 1996).

The spatial and chronological overlapping of rabies cases is most likely related to the mobility of D. rotundus, which frequently circulates among shelters and caves in a radius of 2-3 km with a maximum distance of 20 km (Delpietro et al. 1992, Vieira et al. 2013). This behavioral characteristic enhances the spread of rabies among migrating bat populations, with the concomitant involvement of livestock in the transmission cycle as an accidental host (Trajano 1996, Real et al. 2005).

Major environmental changes (i.e., a sudden shift from agriculture to livestock farming, construction of highways and railways and hydroelectric plants) are among the factors that can force bat colonies to change their migration patterns, roosts and habitats (Estrada & Coates-Estrada 2002, Evelyn & Stiles 2003, Quesada et al. 2004).

CONCLUSIONS

São Paulo and Minas Gerais rabies virus isolates are more genetically related compared with sequences from other geographic regions.

Phylogenetic analysis of two genes suggested that Minas Gerais cases (2000-2009) most likely have the same genetic origin as the São Paulo epizootics (1997-2002).

The glycoprotein gene analysis showed a closer relationship of the Minas Gerais cases with rabies virus isolates involved in the second epidemic wave in São Paulo that occurred after 1999.

Sublineage Ia (according to the glycoprotein and nucleoprotein genes) had a tendency to circulate in the epidemic area of São Paulo.

A chronological and spatial overlapping of viral subpopulations was observed primarily in the epidemic area of São Paulo could be related to bat colonies migration and most of the mutations found in both genes were synonymous except those in residues 20 to 200, which correspond to the external domain of glycoprotein.

This information prompted cooperation among the animal health services of both states to reinforce rabies control in the border area of São Paulo and Minas Gerais.

ACKNOWLEDGEMENTS

This study was funded by FAPESP (research number 2011/06236-0) and CAPES (Andrea Isabel Estevez Garcia PhD fellow-

ship).

Received on October 6, 2014

Accepted for publication on November 23, 2014

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Brinkman F.S.L & Leipe D.D. 2001. Phylogenetic analysis, p.349. In: Baxevanis A. & Ouelette B.F (Ed.), Bioinformatics: a practical guide to the analysis of genes and proteins 2^nd ed. Wiley Interscience, New York.
Carnieli P., Castilho J.G., Fahl W.O., Verás N.M.C. & Timenetsky M. 2009. Genetic characterization of rabies virus isolated from cattle between 1997 and 2002 in an epizootic area in the state of São Paulo, Brazil. Virus Res. 144:215-245.
Delpietro H.A., Marchevsky N. & Simonetti E. 1992. Relative population densities and predation of the common vampire bat (Desmodus rotundus) in natural and cattle-raising areas in north-east Argentina. Prev. Vet. Med. 14:13-20.
Estrada A. & Coates-Estrada R. 2002. Bats in continuous forest, forest fragments and in an agricultural mosaic habitat-island at Los Tuxtlas, Mexico. Biol. Conserv. 103:237-245.
Evelyn M.J. & Stiles D.A. 2003. Roosting requirements of two frugivorous bats (Sturnira lilium and Artibeus intermedius) in fragmented Neotropical forest. Biotropica 35:405-418.
Gomes N.M. & Monteiro A.M.V. 2011. Raiva bovina no estado de São Paulo e sua distribuição espacial entre 1992 e 2003 [Bovine rabies in São Paulo state and its spatial distribution between 1992 and 2003]. Arq. Bras. Med. Vet. Zootec. 63:279-286.
Grenfell B.T., Pybus O.G., Gog J.R., Wood J.L.N., Janet M., Mumford J.A. & Holmes E.C. 2004. Unifying the epidemiological and evolutionary dynamics of pathogens. Science 303:327-333.
Fahl W.O., Carnieli Jr P., Castilho J.G., Carrieri M.L., Kotait I., Iamamoto K., Oliveira R.N. & Brandão P.E. 2012. Desmodus rotundus and Artibeus spp bats might present distinc rabies virus lineages. Braz J. Infect. Dis. 16:545-551.
Hall T. 1999. BioEdit: a user friendly biological sequence alignement editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp. Ser. 41:95-98.
Heinemann M.B., Fernandes-Matioli F.M., Cortez A., Soares R.M., Sakamoto S.M., Bernardi F., Ito F.H., Madeira A.M. & Richtzenhain L.J. 2002. Genealogical analyses of rabies virus strains from Brazil based on N gene alleles. Epidemiol. Infect. 128:503-511.
Kissi B., Tordo N. & Bourhy H. 1995. Genetic polymorphism in the rabies virus nucleoprotein gene. Virology 209:526-537.
Kobayashi Y., Hirano S., Mochizuki N., Itou T., Ito F.H. & Sakai T. 2008. Molecular and geographic analyses of vampire bat-transmitted cattle rabies in central Brazil. BMC Vet. Res. 4:44-52.
Kobayashi Y., Sato G., Shoji Y., Sato T., Itou T., Cunha E.M., Samar S.I., Carvalho A.A., Nociti D.P., Ito F.H. & Sakai T. 2005. Molecular epidemiological analysis of bat rabies viruses in Brazil. J. Vet. Med. Sci. 67:647-652.
Ito M., Itou T., Shoji Y., Sakai T., Ito F.H., Arai Y., Takasaki T. & Kurane I. 2003. Discrimination between dog-related and vampire bat-related rabies viruses in Brazil by strain-specific reverse transcriptase-polymerase chain reaction and restriction fragment length polymorphism analysis. J. Clin. Virology 26:317-330.
Macedo C.I., Carnieli P., Fahl W.O., Oliveira J., Oliveira R., Achkar S.M., Castilho J.G., Carrieri M.L. & Kotait I. 2010. Genetic characterization of rabies virus isolated from bovines and equines between and 2008 in the states of São Paulo and Minas Gerais. Revta Soc. Bras. Med. Trop. 43:116-120.
Menezes F.L., Silva J.A., Moreira E.C., Meneses J.N.C., Magalhães D.F., Barbosa A.D. & Oliveira C.S.F. 2008. Distribuição espaço-temporal da raiva bovina em Minas Gerais, 1998 a 2006. Arq. Bras. Med. Vet. Zootec. 60:566-573.
Miyaki C.Y., Russo C.A. & Pereira S.L. 2012. Capítulo 13: reconstrução filogenética, métodos geométricos, p.124. In: Matioli S. & Fernandes F.M. (Eds), Biologia Molecular e Evolução. 2ª ed. Holos Editora, Riberão Preto, SP.
Nadin-Davis S. 2007. Molecular epidemiology, p.69-122. In: Jackson A.C. & Wunner W.H. (Eds), Rabies. Elsevier, Ontario, Canada.
Oliveira R.N., Souza S.P., Vaz Lobo R.S., Castilho J.G., Macedo C.I., Carnieli Jr P., Fahl W.O., Achkar S.M., Scheffer K.C., Kotait I., Carrieri M.L. & Brandão P.E. 2010. Rabies virus insectivorous bats: implication of the diversity of the nucleoprotein and glycoprotein genes for molecular epidemiology. Virology 405:352-360.
Orciari L.A., Niezgoda M., Hanlon C.A., Shaddock J.H., Sanderlin J.H., Yager P.A. & Rupprecht C.E. 2001. Rapid clearance of SAG-2 rabies virus from dogs after oral vaccination. Vaccine 19:4511-4518.
Peres N.F. 2008. Profilaxia e controle da raiva dos herbívoros domésticos no Estado de São Paulo, Sudeste do Brasil no período 1997-2007. Dissertação de Mestrado, Universidade de São Paulo, São Paulo, SP.
tics. PLOS Negl. Trop. Dis. 6:e1635.
caceous trees. Biotropica 36:131-138.
Real L.A., Henderson J.C., Biek R., Snaman J., Jack T.L., Childs J.E., Stahl E., Waller L., Tinline R. & Nadin-Davis S. 2005. Unifying the spatial population dynamics and molecular evolution of epidemic rabies virus. Proc. Natl Acad. Sci. USA 102:12107-1211.
Sato G., Itou T., Shoji Y., Miura Y., Mikami T., Ito M., Kurane I., Samara S.I., Carvalho A.A., Nociti D.P., Ito F.H. & Sakai T. 2004. Genetic and phylogenetic analysis of glycoprotein of rabies virus isolated from several species in Brazil. J. Vet. Med. Sci. 66:747-753.
Sato G., Kobayashi Y., Shoji Y., Sato T., Itou T. & Ito F.H. 2006. Molecular epidemiology of rabies from Maranhão and surrounding states in the northeastern region of Brazil. Arch. Virol. 151:2243-2251.
Sato G. Determination of phylogenetic and genetic feature of the glycoprotein gene of the human rabies virus strains in Brazil <http://www.ncbi.nlm.nih.gov/nuccore/AB276308> (Unpublished)
Shoji Y., Kobayashi Y., Sato G., Itou T., Miura Y., Mikami T., Cunha E., Samara S., Carvalho A.B., Nocitti D., Ito F.H., Kurane I. & Sakai T. 2004. Genetic characterization of rabies viruses isolated from frugivorous bat (Artibeus spp) in Brazil. J. Vet. Med. Sci. 66(10):1271-1273.
Silva J.A., Moreira E.C., Haddad J.P.A., Modena C.M. & Tubaldini M.A.S. 2001. Distribuição temporal e espacial da raiva bovina em Minas Gerais, 1976 a 1997. Arq. Bras. Med. Vet. Zootec. 53. Available from <http://dx.doi.org/10.1590/S0102-09352001000300001> Access on 19 Sept. 2014.
Tadei V., Gonçalves C.A., Pedro W.A., Tadei W.J., Kotait I. & Arieta C. 1991. Distribuição do Morcego Vampiro, Desmodus rotundus (Chiroptera, Phyllostomidae) no Estado de São Paulo e a raiva dos animais domésticos. Secretária de Agricultura e Abastecimento de São Paulo, São Paulo, SP.
Tamura K., Dudley J., Nei M. & Kumar S. 2007. MEGA 4: molecular evolutionary genetics analysis (MEGA) software version 4.0. Mol. Biol. Evol. 24:1596-1599.
Tordo N., Poch O., Ermine A., Keith G. & Rougeon F. 1986. Walking along the rabies genome: is the large G-L intergenic region a remnant gene? Proc. Natl Acad. Sci. USA 83:3914-3918.
Trajano E. 1996. Movements of cave bats in Southeastern Brazil, with emphasis on the population ecology of the common vampire Desmodus rotundus (Chiroptera). Biotropica 28:121-129.
Vieira L.F.P., Pereira S.R.F.G., Carnieli P., Tavares L.C.B. & Kotait I. 2013. Phylogeography of rabies virus isolated from herbivores and bats in the Espírito Santo State, Brazil. Virus Genes 46:330-336.
Wunner W.H. 2007. Rabies virus, p.23-68. In: Jackson A.C. & Wunner W.H. (Eds), Rabies. Elsevier, Ontario, Canada.

*

Corresponding author:

isaestgar@yahoo.com

Datas de Publicação

Publicação nesta coleção
29 Jan 2015
Data do Fascículo
Dez 2014

Histórico

Aceito
23 Nov 2014
Recebido
06 Out 2014

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

[1] Benmansour A., Brahimi M., Tuffereau C., Coulon P., Lafay F. & Flamand A. 1992. Rapid sequence evolution of street rabies glycoprotein is related to the highly heterogeneous nature of the viral population. Virology 187:33-45.

[2] Bourhy H. & Kissi B.T. 1993. Taxonomy and evolutionary studies on lyssaviruses with special reference to Africa. Onderstepoort J. Vet. Res. 60(4):277-282.

[3] Brasil 2009. Manual de Controle da Raiva em Herbívoros. 2ªed. Ministério da Agricultura Pecuária e Abastecimento, Brasília, DF.

[4] Brinkman F.S.L & Leipe D.D. 2001. Phylogenetic analysis, p.349. In: Baxevanis A. & Ouelette B.F (Ed.), Bioinformatics: a practical guide to the analysis of genes and proteins 2^nd ed. Wiley Interscience, New York.

[5] Carnieli P., Castilho J.G., Fahl W.O., Verás N.M.C. & Timenetsky M. 2009. Genetic characterization of rabies virus isolated from cattle between 1997 and 2002 in an epizootic area in the state of São Paulo, Brazil. Virus Res. 144:215-245.

[6] Delpietro H.A., Marchevsky N. & Simonetti E. 1992. Relative population densities and predation of the common vampire bat (Desmodus rotundus) in natural and cattle-raising areas in north-east Argentina. Prev. Vet. Med. 14:13-20.

[7] Estrada A. & Coates-Estrada R. 2002. Bats in continuous forest, forest fragments and in an agricultural mosaic habitat-island at Los Tuxtlas, Mexico. Biol. Conserv. 103:237-245.

[8] Evelyn M.J. & Stiles D.A. 2003. Roosting requirements of two frugivorous bats (Sturnira lilium and Artibeus intermedius) in fragmented Neotropical forest. Biotropica 35:405-418.

[9] Gomes N.M. & Monteiro A.M.V. 2011. Raiva bovina no estado de São Paulo e sua distribuição espacial entre 1992 e 2003 [Bovine rabies in São Paulo state and its spatial distribution between 1992 and 2003]. Arq. Bras. Med. Vet. Zootec. 63:279-286.

[10] Grenfell B.T., Pybus O.G., Gog J.R., Wood J.L.N., Janet M., Mumford J.A. & Holmes E.C. 2004. Unifying the epidemiological and evolutionary dynamics of pathogens. Science 303:327-333.

[11] Fahl W.O., Carnieli Jr P., Castilho J.G., Carrieri M.L., Kotait I., Iamamoto K., Oliveira R.N. & Brandão P.E. 2012. Desmodus rotundus and Artibeus spp bats might present distinc rabies virus lineages. Braz J. Infect. Dis. 16:545-551.

[12] Hall T. 1999. BioEdit: a user friendly biological sequence alignement editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp. Ser. 41:95-98.

[13] Heinemann M.B., Fernandes-Matioli F.M., Cortez A., Soares R.M., Sakamoto S.M., Bernardi F., Ito F.H., Madeira A.M. & Richtzenhain L.J. 2002. Genealogical analyses of rabies virus strains from Brazil based on N gene alleles. Epidemiol. Infect. 128:503-511.

[14] Kissi B., Tordo N. & Bourhy H. 1995. Genetic polymorphism in the rabies virus nucleoprotein gene. Virology 209:526-537.

[15] Kobayashi Y., Hirano S., Mochizuki N., Itou T., Ito F.H. & Sakai T. 2008. Molecular and geographic analyses of vampire bat-transmitted cattle rabies in central Brazil. BMC Vet. Res. 4:44-52.

[16] Kobayashi Y., Sato G., Shoji Y., Sato T., Itou T., Cunha E.M., Samar S.I., Carvalho A.A., Nociti D.P., Ito F.H. & Sakai T. 2005. Molecular epidemiological analysis of bat rabies viruses in Brazil. J. Vet. Med. Sci. 67:647-652.

[17] Ito M., Itou T., Shoji Y., Sakai T., Ito F.H., Arai Y., Takasaki T. & Kurane I. 2003. Discrimination between dog-related and vampire bat-related rabies viruses in Brazil by strain-specific reverse transcriptase-polymerase chain reaction and restriction fragment length polymorphism analysis. J. Clin. Virology 26:317-330.

[18] Macedo C.I., Carnieli P., Fahl W.O., Oliveira J., Oliveira R., Achkar S.M., Castilho J.G., Carrieri M.L. & Kotait I. 2010. Genetic characterization of rabies virus isolated from bovines and equines between and 2008 in the states of São Paulo and Minas Gerais. Revta Soc. Bras. Med. Trop. 43:116-120.

[19] Menezes F.L., Silva J.A., Moreira E.C., Meneses J.N.C., Magalhães D.F., Barbosa A.D. & Oliveira C.S.F. 2008. Distribuição espaço-temporal da raiva bovina em Minas Gerais, 1998 a 2006. Arq. Bras. Med. Vet. Zootec. 60:566-573.

[20] Miyaki C.Y., Russo C.A. & Pereira S.L. 2012. Capítulo 13: reconstrução filogenética, métodos geométricos, p.124. In: Matioli S. & Fernandes F.M. (Eds), Biologia Molecular e Evolução. 2ª ed. Holos Editora, Riberão Preto, SP.

[21] Nadin-Davis S. 2007. Molecular epidemiology, p.69-122. In: Jackson A.C. & Wunner W.H. (Eds), Rabies. Elsevier, Ontario, Canada.

[22] Oliveira R.N., Souza S.P., Vaz Lobo R.S., Castilho J.G., Macedo C.I., Carnieli Jr P., Fahl W.O., Achkar S.M., Scheffer K.C., Kotait I., Carrieri M.L. & Brandão P.E. 2010. Rabies virus insectivorous bats: implication of the diversity of the nucleoprotein and glycoprotein genes for molecular epidemiology. Virology 405:352-360.

[23] Orciari L.A., Niezgoda M., Hanlon C.A., Shaddock J.H., Sanderlin J.H., Yager P.A. & Rupprecht C.E. 2001. Rapid clearance of SAG-2 rabies virus from dogs after oral vaccination. Vaccine 19:4511-4518.

[24] Peres N.F. 2008. Profilaxia e controle da raiva dos herbívoros domésticos no Estado de São Paulo, Sudeste do Brasil no período 1997-2007. Dissertação de Mestrado, Universidade de São Paulo, São Paulo, SP.

[25] tics. PLOS Negl. Trop. Dis. 6:e1635.

[26] caceous trees. Biotropica 36:131-138.

[27] Real L.A., Henderson J.C., Biek R., Snaman J., Jack T.L., Childs J.E., Stahl E., Waller L., Tinline R. & Nadin-Davis S. 2005. Unifying the spatial population dynamics and molecular evolution of epidemic rabies virus. Proc. Natl Acad. Sci. USA 102:12107-1211.

[28] Sato G., Itou T., Shoji Y., Miura Y., Mikami T., Ito M., Kurane I., Samara S.I., Carvalho A.A., Nociti D.P., Ito F.H. & Sakai T. 2004. Genetic and phylogenetic analysis of glycoprotein of rabies virus isolated from several species in Brazil. J. Vet. Med. Sci. 66:747-753.

[29] Sato G., Kobayashi Y., Shoji Y., Sato T., Itou T. & Ito F.H. 2006. Molecular epidemiology of rabies from Maranhão and surrounding states in the northeastern region of Brazil. Arch. Virol. 151:2243-2251.

[30] Sato G. Determination of phylogenetic and genetic feature of the glycoprotein gene of the human rabies virus strains in Brazil <http://www.ncbi.nlm.nih.gov/nuccore/AB276308> (Unpublished)

[31] Shoji Y., Kobayashi Y., Sato G., Itou T., Miura Y., Mikami T., Cunha E., Samara S., Carvalho A.B., Nocitti D., Ito F.H., Kurane I. & Sakai T. 2004. Genetic characterization of rabies viruses isolated from frugivorous bat (Artibeus spp) in Brazil. J. Vet. Med. Sci. 66(10):1271-1273.

[32] Silva J.A., Moreira E.C., Haddad J.P.A., Modena C.M. & Tubaldini M.A.S. 2001. Distribuição temporal e espacial da raiva bovina em Minas Gerais, 1976 a 1997. Arq. Bras. Med. Vet. Zootec. 53. Available from <http://dx.doi.org/10.1590/S0102-09352001000300001> Access on 19 Sept. 2014.

[33] Tadei V., Gonçalves C.A., Pedro W.A., Tadei W.J., Kotait I. & Arieta C. 1991. Distribuição do Morcego Vampiro, Desmodus rotundus (Chiroptera, Phyllostomidae) no Estado de São Paulo e a raiva dos animais domésticos. Secretária de Agricultura e Abastecimento de São Paulo, São Paulo, SP.

[34] Tamura K., Dudley J., Nei M. & Kumar S. 2007. MEGA 4: molecular evolutionary genetics analysis (MEGA) software version 4.0. Mol. Biol. Evol. 24:1596-1599.

[35] Tordo N., Poch O., Ermine A., Keith G. & Rougeon F. 1986. Walking along the rabies genome: is the large G-L intergenic region a remnant gene? Proc. Natl Acad. Sci. USA 83:3914-3918.

[36] Trajano E. 1996. Movements of cave bats in Southeastern Brazil, with emphasis on the population ecology of the common vampire Desmodus rotundus (Chiroptera). Biotropica 28:121-129.

[37] Vieira L.F.P., Pereira S.R.F.G., Carnieli P., Tavares L.C.B. & Kotait I. 2013. Phylogeography of rabies virus isolated from herbivores and bats in the Espírito Santo State, Brazil. Virus Genes 46:330-336.

[38] Wunner W.H. 2007. Rabies virus, p.23-68. In: Jackson A.C. & Wunner W.H. (Eds), Rabies. Elsevier, Ontario, Canada.