Highlights
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We performed a search for canine coronavirus in fecal samples and organs from dogs.
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Pantropic canine coronavirus was found in different organs.
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Similar lesions to those found in canine parvovirus were observed.
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This study reinforces the need for differential diagnosis between canine parvovirus and canine coronavirus.
Keywords: Dog, Canine coronavirus, Canine parvovirus, Pantropic, Sequencing
Abstract
Characterization of canine coronavirus (CCoV) strains currently in circulation is essential for understanding viral evolution. The aim of this study was to determine the presence of pantropic CCoV type IIa in tissue samples from five puppies that died in Southern Brazil as a result of severe gastroenteritis. Reverse-transcriptase PCR was used to generate amplicons for sequence analysis. Phylogenetic analysis of the CCoV-IIa strains indicated that they were similar to those found in other countries, suggesting a common ancestor of these Brazilian isolates. This is the first report of pantropic CCoV-II in puppies from Latin America and our findings highlight that CCoV should be included as a differential diagnosis when dogs present with clinical signs and lesions typically seen with canine parvovirus infection.
Canine coronavirus (CCoV) infection is usually characterized by high morbidity and low mortality, predominantly affecting dogs in kennels and rescue shelters. CCoV replication is mainly limited to the gastrointestinal tract and can eventually lead to death, particularly when co-infection with canine parvovirus (CPV-2), canine adenovirus type 1 (CAV-1) or canine distemper virus (CDV) are present. CCoV can be grouped into two genotypes: CCoV-I and CCoV-II (Decaro, Buonavoglia, 2008, Decaro, Buonavoglia, 2011). Recently, CCoV-II has been subdivided into CCoV-IIa (which derives from recombination with a feline coronavirus; FCoV-II) and CCoV-IIb (which derives from recombination with porcine transmissible gastroenteritis virus; TGEV), but the latter has not been shown to be associated with clinical disease in dogs (Decaro and Buonavoglia, 2011).
Following emergence of the more virulent pantropic CCoV-IIa strain (Decaro et al., 2012), detection, identification and monitoring of these new coronaviruses has become more important, when dogs are presented with severe gastroenteritis that would previously have been attributed to CPV-2 infection. The aim of the present study was to characterize the phylogeny of coronaviruses isolated from dogs in Brazil that had died from gastroenteritis.
Five dogs (aged 1 to 6 months) that died at the Clinical Veterinary Hospital of Universidade Federal do Rio Grande do Sul, Southern Brazil, between June and September 2011, were necropsied. Total RNA was extracted from tissue biopsies and fecal samples, obtained from each dog, using TRIzol LS (Life Technologies) and cDNA synthesized using the Superscript III Reverse Transcriptase Kit (Life Technologies). DNA was extracted from the supernatant of the fecal suspension, using a commercial kit (Simbios Biotecnologia). CCoV-I and CCoV-II primer pairs were used to amplify a region of the M gene, as described by Herrewegh et al. (1998). EL1F, EL1R and S5, S6 primer pairs were used to differentiate between CCoV-I and CCoV-II as described by Pratelli et al. (2004). Reactions specific to CCoV-IIa and CCoV-IIb were performed, using CCoV-IIaF/CCoV-IIaR and CCoV-IIbF/CCoV-IIbR primer pairs in two different reactions, which amplified fragments of the 5′ end region of the S gene (Decaro et al., 2012). Fecal samples were also analyzed by PCR for the presence of other gastrointestinal viruses, namely CPV-2 (Buonavoglia et al., 2001), CAV-1 and CAV-2 (Hu et al., 2001), CDV (Frisk et al., 1999) and canine rotavirus (CRV) (Gouvea et al., 1990). Platinum Taq DNA Polymerase (Life Technologies) was used for PCR, according to the manufacturer's recommendations.
CCoV amplicons were purified using the NucleoSpin Extract II Kit (Macherey-Nagel) and sequenced with an ABI PRISM 3100 Genetic Analyzer (Applied Biosystems) using a BigDye Terminator v.3.1 cycle sequencing kit (Applied Biosystems). The maximum likelihood (ML) trees were constructed using PhyML version 3.0.1 The best substitution models were estimated using JModeltestv.0.1.12 for the nucleotide dataset and ProtTest version 2.43 for the amino acid dataset, both with the Akaike information criterion (AIC). For Bayesian inference, we selected substitution models according to the AIC using MrModeltest.4
The dogs presented with hemorrhagic gastroenteritis, vomiting, fever, loss of appetite and collapse. At necropsy, similar lesions were seen, consisting of thickening and roughening of the small intestinal mucosa, submucosal edema and enlargement of the Peyer's patches and mesenteric lymph nodes. Histopathology revealed necrotic enteritis, with atrophy and fusion of microvilli, edema and congestion of mesenteric lymph nodes and mild to moderate edema and diffuse congestion in the lungs. There was reduced bone marrow content and evidence of necrosis in four of the five dogs.
Molecular analysis of samples from the five dogs revealed that three were positive for CCoV-II and three were positive for CPV-2, with two dogs co-infected by both of these viruses (further details in Appendix: Supplementary material). One dog was negative for all viruses tested and all five dogs were negative for CDV, CRV, CAV-1 and CAV-2. Amplification and sequencing of the 5′ region of the S gene (CCoV-II) and of the VP2 gene (CPV-2) allowed further characterization that these were pantropic CCoV-IIa and CPV-2c. Phylogenetic trees, obtained using different datasets and estimated by different methods, indicated a close relationship between the CCoV identified and the CCoV-II related group (Fig. 1 ). The phylogenetic analyses, based on the nucleotide sequence of the M gene, grouped the Brazilian pantropic samples from Rio Grande do Sul state (Southern Brazil) with GU300127, identified from a dog in São Paulo state (Southeastern Brazil) in both maximum likelihood (ML) and Bayesian (BI) analyses with moderate to high statistical support (Fig. 1A).
Fig. 1.
Maximum likelihood (ML) tree showing the relationships between CCoV strains (JX442376, JX442377 and JX442378 identified in the present study) based on (A) a 332 base pair (bp) fragment of the M gene, (B) a 569 bp fragment from the 3′end region of the S gene and (C) a 938 bp fragment of the S gene (5′end plus 3′end combined dataset), using the TIM2+G model. Nodal support values (<0.7 posterior probability or <70% bootstrap not shown) are indicated for ML and Bayesian (BI) methods, respectively. (–) indicates values <70%, while (*) stands for different resolution in BI analysis.
The phylogenic analysis, based on the 3′end region of the S gene, grouped the Brazilian samples into a principal group with CCoV-IIa, FCoV-II and TGEV with moderate to high support (Fig. 1B). However, the relationships within this group are not fully resolved. Analysis using the concatenated fragment of the S gene (5′end plus 3′end) supported this principal group and clustered the Brazilian samples into a highly supported monophyletic clade (Fig. 1C). The phylogeny also suggests a sister–group relationship between the Brazilian samples and the group composed of JQ404410, X80799, and NC002306. Amino acid differences between Brazilian and reference samples of the partial M gene and the 5′ region of the S gene are shown in Table 1, Table 2 . BLAST searches5 using the partial M gene sequences as the query revealed greatest identity with sequence GU300127 (95.5–98.6% identity) and similarity with reference samples AY704916 (Germany) (94.4–96.7% nucleotide identity) and DQ112226 (Italy) (93.7–95.2% nucleotide identity).
Table 1.
Amino acid differences between Brazilian and reference samples for the CCoV M gene.
| Amino acid position | |||||||
|---|---|---|---|---|---|---|---|
| Samplesa | 123 | 127 | 187 | 212 | 223 | 243 | 246 |
| D13096 CCoV-IIa (UK) | Thr | Ile | Cys | Val | Lys | Tyr | Asp |
| AY342160 CCoV-IIa (UK) | Ile | Ile | Tyr | Ser | Gln | Tyr | Asp |
| DQ112226 CCoV-IIa (Italy) | Ile | Ile | Tyr | Ser | Lys | Tyr | Asp |
| EU924790 CCoV-IIb (Italy) | Ile | Ile | Tyr | Ser | Lys | Tyr | Asp |
| GU300127 (Brazil) | Ile | Val | Tyr | Ser | Gln | ||
| JX442376* (Brazil) | Ile | Val | Tyr | Ser | Gln | Asn | Glu |
| JX442377* (Brazil) | Ile | Val | Tyr | Ser | Lys | Asn | Glu |
| JX442378* (Brazil) | Ile | Val | Tyr | Ser | Lys | Asn | Glu |
| NC002306 FCoV-II (USA) | Val | Ala | Tyr | Ser | Gln | ||
| Recombitek | Ile | Tyr | Ser | Lys | |||
aGenBank accession numbers are shown with country of origin in parentheses. Recombitek is a commercial vaccine. Amino acid differences are highlighted in bold text. *Identified in the present study.
Table 2.
Amino acid differences between Brazilian and reference samples for the 5′ region of the CCoV S gene.
| Amino acid position | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Samplesa | 5 | 20 | 21 | 34 | 38 | 54 | 72 | 78 | 125 |
| DQ112226 CCoV-IIa (Italy) | Leu | Thr | Thr | Asp | Asn | Val | Ala | Glu | Asn |
| JQ404410 CCoV-IIa (USA) | Val | Thr | Ala | Pro | Tyr | Val | Ala | Gln | Asp |
| KC138236* (Brazil) | Val | Met | Ala | Pro | Tyr | Val | Ala | Glu | Asp |
| KC138237* (Brazil) | Val | Thr | Thr | Pro | Tyr | Val | Arg | Glu | Asp |
| KC138238* (Brazil) | Glu | Thr | Thr | Pro | Tyr | Glu | Ala | Glu | Asp |
| NC002306 FCoV-II (USA) | Val | Thr | Thr | Ala | Asn | Val | Ala | Gln | Asp |
aGenBank accession numbers are shown with country of origin in parentheses. Amino acid differences are highlighted in bold text. *Identified in the present study.
This is the first report of pantropic CCoV in dogs from Latin America. Fecal samples and several organs from three dogs affected with gastroenteritis were positive for CCoV, corroborating the data published previously (Decaro et al, 2012, Zicola et al, 2012). Phylogenetic analysis of the CCoV strains showed that these were similar to those found in other countries. The Brazilian samples tended to group into a single clade, suggesting a common ancestor. The results of this study indicate that pantropic CCoV should be considered in puppies, presenting with hemorrhagic gastroenteritis, which would usually be attributed to CPV-2. Inclusion of diagnostic testing for CoCV should be considered in such cases, to differentiate between these two pathogens and to identify animals with co-infections.
Conflict of interest statement
None of the authors of this paper has a financial or personal relationship with other people or organization that could inappropriately influence or bias the content of the paper.
Acknowledgments
We are thankful to Simbios Biotecnologia Ltd. for kindly supplying the DNA extraction kits. We thank the veterinarians who collected samples from the dogs and the undergraduate and graduate students of the Laboratory of Virology for their collaboration in this work. Financial support was provided by Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), grant number 475223/2013-6, Fundação de Amparo à Pesquisa do Estado do Rio Grande do Sul (FAPERGS), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) and Propesq/UFRGS.
Footnotes
See: http://www.ncbi.nlm.nih.gov/BLAST/Blast.cgi?PROGRAM=blastn&PAGE_TYPE=BlastSearch&LINK_LOC=blasthome.
Supplementary data to this article can be found online at doi:10.1016/j.tvjl.2014.09.006.
Appendix. Supplementary Material
The following is the supplementary data to this article:
Results for the partial amplification by PCR of the S gene in the 5'-end region for CCoV-IIa in organ samples.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Results for the partial amplification by PCR of the S gene in the 5'-end region for CCoV-IIa in organ samples.