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487 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 2, p. 487-495, Mar./Apr. 2020 
http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

ANATOMOPATHOLOGICAL CHANGES IN CANINE DISTEMPER 
SEROPOSITIVE DOGS AND VIRUS DETECTION IN SINOATRIAL NODES 

 

ALTERAÇÕES ANATOMOPATOLÓGICAS EM CÃES SOROPOSITIVOS PARA 
CINOMOSE E DETECÇÃO DO VÍRUS EM NÓ SINOATRIAL 

 
José Eugenio Diniz BASTOS1; Neide Maria SILVA2; Marisol Patrícia Pallete BRICEÑO3;  

Tais Meziara WILSON4; Alessandra Aparecida MEDEIROS-RONCHI1 
1. Associate Professor of Faculty of Veterinary Medicine, Federal University of Uberlândia - UFU, Uberlândia, MG, Brazil;  

2.  Associate Professor of Institute of Biomedical Sciences - UFU, Uberlândia, MG, Brazil; 3. PhD, UFU, Uberlândia, MG, Brazil;  
4. Doctorate in Animal Science, University of Brasília, Brasília, DF, Brazil. 

 
ABSTRACT: Canine distemper is a viral disease that affects several systems on dogs, among them, 

the cardiovascular system. The aim of this study was to identify canine distemper virus (CDV) in the sinoatrial 
node (SAN) of dogs serologically positive for distemper by Polymerase Chain Reaction preceded by reverse 
transcription (RT-PCR), and to analyze gross and microscopic changes of distemper in the heart and other 
tissues. SAN and tissue fragments were collected from 17 serologically positive dead animals, necropsied from 
October 2015 to December 2016. In the heart, right heart dilatation was observed in 13 dogs (76.47%) and left 
concentric hypertrophy in two dogs (11.76%). Microscopically, lymphocytic myocarditis was observed in four 
(23.53%) dogs and 41.18% presented viral inclusion corpuscles of CDV in the bladder epithelium. Only one 
(5.88%) dog presented a 319 bp target fragment for distemper virus using primers CDV 1 and CDV 2 at the 
sinoatrial node. In conclusion, CDV can be located in the sinoatrial node of naturally infected dogs, as 
demonstrated in this study by the RT-PCR technique, reinforcing the hypothesis that CDV is capable of causing 
inflammatory lesions in the sinoatrial node of this species. Macroscopic and microscopic cardiac changes are 
frequently observed in dogs with distemper, mainly cardiac dilatation and myocarditis. Viral inclusions of CDV 
in bladder epithelial cells are an important microscopic finding for the diagnosis of distemper. 
 

KEYWORDS: Cardiac Conduction System. Canine Distemper Virus. Cardiomyopathy. 
 
INTRODUCTION 
 

The sinoatrial node (SAN) is responsible for 
the heart rhythm and is essential for the normal 
physiology of the heart (JOUNG et al., 2011). His 
bundle together with the atrioventricular node and 
the Purkinge fibers are the specialized conduction 
system of the heart (CUNNINGHAM; KLEIN, 
2008). 

SAN dysfunction has multifactorial 
etiologies. Monfredi et al. (2010) and Andrade et al. 
(1988) reported that the SAN also shows an 
increasing density as the age progresses and that 
sinoatrial node dysfunction can be considered an 
aging phenomenon. 

Information about microorganisms that 
affect the canine SAN are rare.  The possibility of 
canine distemper virus (CDV) causing injury 
specifically in this area as suggested by Mendonça 
and Coelho (2006) raised interest about the presence 
of the virus in this cardiac structure. Nelson and 
Couto (2015) reported that cardiotropic viruses play 
an important role in the pathogenesis of myocarditis 
in several species. 

Canine distemper virus is the most frequent 
pathogen for dogs and wild carnivores and its 
infection is relevant in all continents and is 
associated with high mortality and morbidity. In the 
dog, it develops respiratory, gastrointestinal, 
dermatological, ophthalmic, neurological 
manifestations and may cause myocarditis 
(BUDASZEWSKI et al., 2014). 

Higgins et al. (1981) inoculated the CDV 
strain in dogs and 36% presented cardiac lesions. 
Resende et al. (2009) analyzed the myocardium of 
left ventricle of seropositive dogs for distemper and 
verified myocarditis in 42.8% of the animals. 

Araújo (2017) evaluated the influence of the 
CDV on the cardiovascular system and verified that 
there is virus activity in the excitatory system and 
specialized heart conductors. Mendonça and Coelho 
(2006) studied SAN lesions on dogs serologically 
positive for distemper and observed cardiac 
dilatation in 97.14% of the animals in addition to 
inflammatory and degenerative alterations. Bastos et 
al. (2007) also verified degenerative, vascular and 
inflammatory microscopic lesions in the SAN in 
dilated hearts of dogs with clinical suspicion of 
distemper. CDV belongs to the genus Morbillivirus 

Received: 14/05/18 
Accepted: 20/11/19 



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Anatomopathological...  BASTOS, J. E. D. et al. 

Biosci. J., Uberlândia, v. 36, n. 2, p. 487-495, Mar./Apr. 2020 
http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

of the family Paramixoviridae (VAN 
REGENMORTEL et al., 2000) and is a single-
stranded RNA virus of negative polarity. 
Polymerase chain reaction (PCR) has been used  to  
diagnose  canine  distemper  and  the  main  
advantages  of  this  technique  preceded  by  a  
reverse transcription step (RT-PCR) for RNA 
viruses include the speed of obtaining results, no 
need of viral particle infectivity and it's high levels 
of sensitivity and specificity (FRISK et al., 1999; 
GEBARA et al., 2004). 

The aim of this study was to identify CDV 
in the SAN of dogs serologically positive for 
distemper using RT-PCR and to analyze gross and 
microscopic changes of distemper in the heart and 
other tissues. 
 
MATERIAL AND METHODS 
 
Animals and clinical data 

Cases of necropsied dogs were selected at 
the Animal Pathology Laboratory of the Veterinary 
Hospital of the Faculty of Veterinary Medicine of 
the Federal University of Uberlândia from October 
2015 to December 2016. The animals had received 
the clinical and serological diagnosis of canine 
distemper but did not respond to the conventional 
therapy for the disease and came to natural death. 

The clinical diagnosis was made based on 
laboratory exams and signs: anorexia, hyperthermia, 
conjunctivitis, optic neuritis, uveitis, chorioretinitis, 
dry keratoconjunctivitis, upper respiratory tract 
inflammation with mucopurulent nasal discharge, 
pneumonia, hemorrhagic gastroenteritis or the lack 
of it, cervical stiffness, convulsions, myoclonus, 
ataxia of cerebellar or vestibular origin, paresis, 
tetraparesis, vesicular pustules, nasal and/or pads 
hyperkeratosis, lymphocytopenia, thrombocytopenia 
and anemia (GREENE et al., 2012; DEEM et al., 
2000). The serological diagnosis of distemper was 
performed using immunochromatographic 
immunoassay for the qualitative detection of 
antibodies (IgG and IgM) for distemper (Alere 
Cinomose AgTest®) according to manufacturer`s 
protocol. 

The animals were divided into three groups 
by age: young (up to one year old), adults (one to 
nine years of age) and the elderly (ten years of age 
or older), according to (FIGHERA et al., 2008). 
Data such as breed, age, sex and macroscopic 
lesions observed during necropsy were recorded. 

The necropsies were performed within 30 
minutes after death and in the impossibility of 
performing them this way, the body was kept under 
refrigeration in a cold room for a maximum of three 

hours. At the beginning of the necroscopic 
procedure, the costochondral joints were opened and 
the thoracic cavity was exposed. The heart was 
removed and, using sterile material, a 2 cm fragment 
was collected from the initial portion of the caudal 
cranial cava, near the end sulcus region, where the 
SAN is located. The SAN fragment was 
immediately packed into sterile cryotubes and kept 
in a container with crushed ice until they were sent 
to ultra-freezer storage at -80°C. 

The necropsy technique was performed 
following the organ inspection sequence of the 
necropsy specimen procedures of the Laboratory of 
Animal Pathology. Fragments of myocardium, lung, 
pancreas, liver, bladder (for research of inclusion 
corpuscles of the distemper virus), kidney and other 
tissues that presented macroscopic alterations were 
collected. The fragments were fixed in 10% 
buffered formalin for 48 hours and routinely 
processed for the preparation of histological slides 
stained with Hematoxylin and Eosin (HE) 
(TOLOSA et al., 2003). 

 
Detection of distemper virus by RT-PCR 

The fragments containing the sinoatrial 
node maintained in ultra-freezer -80ºC were used to 
extract viral RNA using Trizol reagent (Life 
Technologies®), according to the manufacturer's 
instructions, at the Laboratory of Immunopathology 
of the Federal University of Uberlândia. 

The first complementary DNA strand 
(cDNA) was synthesized from 2 μg of total RNA. 
Initially 25 pmol of the reverse primer CDV strain 
Onderstepoort, CDV 02 (5'-
GATTGCTTAGGACCAGTAGC-3') were added to 
2 μg of RNA and denaturation was done at 70° C for 
10 minutes. Immediately after the addition of 
Impron II reverse transcriptase (Promega®, 
Madison, WI, USA), 2μl; 250 μM dNTP mix, 8 μl 
of RT buffer, 3 mM magnesium chloride, 2 μl 
Dithiothreitol (DTT) at 20 mM and RNAse-free 
water to complete the final volume of 40 μl. The 
reaction was incubated at 42˚C for 1 hour, then 
cooled at 4˚C and maintained at -80˚C until use. The 
RNA virus from the distemper vaccine (Duramune 
D®, Fort DODGE) was used as a positive control of 
the reaction. Specific primers that amplified the 
CDV nucleocapsid gene were used, according to 
(DEL PUERTO et al., 2010), CDV01, forward, (5'-
CAGCACCGTACATGGTTATC-3') and reverse 
CDV 02 (5' GATTGCTTAGGACCAGTAGC-3') 
which amplifies a 319bp fragment; and canine 
housekeeping gene -actin-specific primers: F (5'-
CACCTTCTACAACGAGCTGCG-3') and R (5'-
ATCTTCTCACGGTTGGCCT-3') which amplifies 



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Anatomopathological...  BASTOS, J. E. D. et al. 

Biosci. J., Uberlândia, v. 36, n. 2, p. 487-495, Mar./Apr. 2020 
http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

a 93bp fragment. 5μl of the cDNA from each 
sample were used; 25 pmol of each primer; 250 μM 
dNTP mix (Promega®, Madison, WI, USA); 2 mM 
MgCl 2; 1.25 U GoTaq® Flexi DNA Polymerase 
(Promega®, Madison, WI, USA) or 0.25μl; Taq 
buffer (10μl) and ultrapure water to make up the 
final volume of 50μL. PCR conditions were: initial 
denaturation at 93˚C for 2 minutes, 1 cycle followed 
by 40 cycles of denaturation at 93˚C for 1 minute, 
annealing at 56˚C for 1 minute, and extension at 
72˚C for 1 minute. Final extension at 72°C for 5 
minutes. 

The amplified products were stained with 
SYBR Safe DNA gen stain (Invitrogen®) and were 
separated by a horizontal electrophoresis system 
(Loccus  Biotechnology LCH®) in 1.5% agarose gel 
and visualized with the gel documentation system 
MiniBIS – PRO (DNR Bio-Imaging Systems). 
 

RESULTS 
 

Seventeen canine distemper seropositive 
dogs with clinical symptomatology compatible with 
distemper were used. Four were males and 13 
females, with respect to breed 15 were mixed-breed 
dogs, one Poodle and one Cocker Spaniel. As to age 
seven (41.18%) were young, three (17.64%) adults 
and seven (41.18%) were elderly. 
 
Gross and microscopic lesions 

With regard to the macroscopic aspect of 
the heart the alterations evidenced were: right heart 
dilation in 13 dogs (76.47%) (Figure 1) and left 
concentric hypertrophy in two dogs (11.76%).  
Microscopically, lymphocytic myocarditis was 
observed in four (23.53%) dogs (Table1). 

 

 

Figure 1. Heart gross lesions of dogs serologically positive for distemper. (A) the heart was enlarged and 
remarkably globoid; (B) left concentric hypertrophy and congestive blood vessels; (C) right heart 
dilatation. 
 
Macroscopically, splenomegaly was 

observed in 35.29% and hepatomegaly was present 
in 17.64% of the seropositive dogs for distemper. 
Microscopically, interstitial nephritis was observed 
in 70.58% of dogs, and in 41.18% there were viral 
inclusion bodies in the bladder epithelium (Figure 
2). In the digestive system the main changes were 
hepatic lipidosis and enteritis in 47.05% of dogs and 
in 5.88% of the dogs there were viral inclusion 
bodies in the hepatocytes. Pneumonia was observed 
in 52.94% dogs. In the spleen, lymphoid atrophy 
was observed in 29.41% dogs (Table 1). 
 
RT-PCR 

Of the 17 seropositive dogs for distemper, 
5.88% presented a 319 bp target fragment for 
distemper using the CDV1 and CDV2 primers at the 

sinoatrial node using the RT-PCR technique. This 
animal was a four-month-old female, mixed-breed, 
and with incomplete vaccination scheme. Clinically 
presented myoclonus, abdominal pustule, 
parakeratosis in the pads and nasal plane. Gross 
lesions were right heart dilation, histoplasmacytic 
pancreatitis, lymphoplasmacytic pneumonia, 
lymphoid atrophy in the spleen and platelet disease 
(12,000 platelets/μL of blood). 
 
 
 
 
 
 
 
 

B C A 



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Anatomopathological...  BASTOS, J. E. D. et al. 

Biosci. J., Uberlândia, v. 36, n. 2, p. 487-495, Mar./Apr. 2020 
http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

  
Table 1. Microscopic lesions of 17 canine distemper virus seropositive dogs, Uberlândia, 2017. 

MICROSCOPIC LESIONS N . ABSOLUTE 
(% ) 

Cardiovascular system   
Lymphocytic focal myocarditis  4 (23.52%) 
Urinary system   
Lymphoplasmacytic interstitial nephritis 12 (70.58%) 
Intranuclear inclusion of bladder epithelium7 (41.17%) 
Lymphocytic cystitis 2 (11.76%) 
Digestive system   
Hepatic Lipidosis 8 (47.05%)  
Enteritis 8 (47.05%) 
Lymphoplasmacytic hepatitis  7 (41.16%) 
Lymphoplasmacytic pancreatitis 3 (17.64%) 
Hepatic necrosis 1 (5.88%) 
Intranuclear inclusion in hepatocytes 1 (5.88%) 
Pancreatic hemorrhage 1 (5.88%) 
Respiratory system   
Lymphoplasmacytic pneumonia  7 (41.16%) 
Purulent pneumonia 2 (11.76%) 
Hematopoietic system   
Splenic lymphoid atrophy 5 (29.4%) 
Splenic hemosiderosis 2 (11.76%) 

 
 

 
Figure 2. Intranuclear inclusion bodies (black arrows) of canine distemper virus in bladder epithelium of 

naturally infected dog. Hematoxylin and eosin stain, 40x. 
 
 
DISCUSSION 
 

In the present study most dogs with 
distemper were adults or elderly. Silva et al. (2009) 
and Santos et al. (2012) reported that distemper is 
more frequent in dogs over one year of age, as 
observed in our results. However, the disease can 
reach dogs of different ages and the incidence of 
major distemper cases occurs between 60 and 90 
days of age (CORRÊA; CORRÊA, 1992). Even so, 

these same authors reported that the disease may 
develop in animals from 7 to 9 years old, the age 
observed in the present study, but the lethality is 
higher in young dogs especially when the virus acts 
on the central nervous system (CORRÊA; 
CORRÊA, 1992). 

In the present study, 76.47% of the dogs 
presented cardiac dilatation. Several agents are 
capable of cause cardiac dilatation. Janus et al. 
(2014) studied dogs with heart disease and observed 
63.63% with cardiac dilation identifying the 



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Biosci. J., Uberlândia, v. 36, n. 2, p. 487-495, Mar./Apr. 2020 
http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

presence of Borrelia burgdorferi in 54.54% of the 
dogs. These authors also mentioned distemper and 
ehrlichiosis as possible agents responsible for 
myocarditis and cardiac dilatation. 

The distemper virus is pantropic and can 
affect the cardiac musculature and its association 
with heart lesions was already mentioned by several 
authors (MENDONÇA; COELHO, 2006; 
RESENDE et al., 2009) Mendonça and Coelho 
(2006) evaluated seropositive dogs for distemper 
and identified 97.14% of hearts with cardiac 
dilatation and Resende et al. (2009) observed 
88.57%. Higgins et al. (1981) studied dogs 
inoculated with CDV and found cardiac dilation in 
only one dog (9.09%). 

Lymphocytic myocarditis, observed in the 
present study, may be associated with the presence 
of the virus in the tissue. The immune response of 
the host contributes to the installation of the 
inflammatory process and consequently myocardial 
injury (NELSON; COUTO, 2015; MENDONÇA; 
COELHO, 2006). 

Lymphocytic myocarditis is reported by 
several authors. (HIGGINS et al., 1981; SONNE et 
al., 2009; MENDONÇA; COELHO, 2006; 
WOOLLEY et al., 2007; KANESHIGE et al., 2007; 
RESENDE et al., 2009) as a lesion associated with 
the distemper virus. Resende et al. (2009) studying 
dogs with CDV found 42.8% with lymphocytic 
myocarditis, 31.4% with hyaline degeneration, 
14.3% with hyperemia and 11.4% with hemorrhage. 
However, Sonne et al. (2009) did not observe 
significant microscopic changes in the heart of dogs 
with distemper. 

Kaneshige et al. (2007) related distemper 
and parvovirus as possible viruses associated with 
myocarditis, as well as bacteria and protozoa such 
as Trypanosoma cruzi. Scalabrini et al. (1996) 
studied dog infected with Trypanosoma cruzi and 
observed myocarditis and inflammation in the 
sinoatrial node. Woolley et al. (2007) reported the 
canine distemper virus as responsible for 
myocarditis in addition to parvovirus, bacteria, 
Borrelia burgdorferi and leishmaniasis. 

In the present study it was not possible to 
evaluate microscopically the sinoatrial node region 
since it was harvested for CDV identification by 
RT-PCR. However, Bastos et al. (2007) observed 
microscopic lesions in the sinoatrial node of dogs 
with cardiac dilation such as lymphocytic 
inflammation (45.3%), hyaline degeneration 
(26.2%), fatty degeneration (9.5%) and hemorrhage 
(7.1 %). 

Mendonça and Coelho (2006) also studied 
lesions in the sinoatrial node of dogs serologically 

positive for distemper and observed lymphocytic 
infiltration in 42.86%; fat infiltration in 28.57%; 
hyaline degeneration at 8.57%; hemorrhage in 
18.57% and absence of lesions in 25.7%. 

Araújo (2017) evaluated the influence of the 
distemper virus on the cardiovascular system and 
verified that there is virus activity in the excitatory 
and specialized heart conduction system. Dogs 
positive for the distemper virus had decreased heart 
rate variability and the negativity of arrhythmias to 
holter. 

Several agents have been described as 
causing damage to the sinoatrial node but there are 
no reports of agent identification in this anatomical 
structure. In the present study it was possible to 
detect the distemper virus in the SAN by the RT-
PCR technique proving that this virus can be located 
in the dog sinoatrial node. Studies performed so far 
cite inflammatory process in this cardiac structure, 
but without identification of the etiological agent 
responsible for the inflammation. Likewise, to date 
there are reports of the presence of CDV detected by 
RT-PCR in several types of biological samples and 
tissues, but not specifically in the sinoatrial node. 

CDV  was  detected  at  low  levels  (2.79 × 

10
4 

copies  of  RNA /μL)  in  a  dog  heart  
seropositive  for distemper and at high levels in 
other tissues, such as skin, muscle and oral mucosa, 
with viral load varying from 2, 10 × 10 6 to 4.25 × 
10 8 μL (ELIA et al., 2006). 

Previous studies using the RT-PCR 
technique had demonstrated CDV RNA in other 
tissues and fluids. CDV was detected by RT-PCR in 
86% serum samples and 88% of whole blood and 
cerebrospinal fluid samples from 
immunohistochemically confirmed dogs with 
distemper (FRISK et al., 1999). Gebara et al. (2004) 
obtained amplification of the CDV nucleoprotein 
gene in 47.1% of urine samples from dogs with 
clinical signs suggestive of distemper. 

Depending on the clinical presentation and 
evolution of canine distemper CDV may be present 
in a variety of biological samples. At different 
stages of infection urine, whole blood, leukocytes, 
feces, saliva, respiratory secretion and CSF may 
present the virus in various titres (FRISK et al., 
1999; ELIA et al., 2006; SANTOS et al. 2012). 
Negrão et al. (2007) obtained the amplification of a 
CDV fragment from the urine or leukocytes of 
66.5% of the animals with canine distemper and 
stated that the different forms of clinical 
presentation  and  evolution  of  canine  distemper  
can  make  it  difficult  to  choose  only  a  type  of  



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http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

biological material to perform the ante-mortem 
etiological diagnosis. 

However, RT-PCR has limitation and may 
present false negative results. Several factors may 
interfere with the results such as selection of the 
nucleotide target sequence to be amplified, method 
of RNA extraction,  standardization  of  reagents  
used  in  the  technique,  selection  of  biological  
material  to  be  used, conservation form and storage 
time since it is a virus whose genome consists of 
single stranded RNA which can easily undergo 
degradation (FRISK et al, 1999; GEBARA et al., 
2004; KIM et al., 2001). 

Virus inclusions bodies were identified in 
the bladder epithelial cells in 41.18% of the animals, 
and it may be considered an important microscopic 
finding for the diagnosis of distemper. Kubo et al. 
(2007) observed viral inclusions bodies in the 
bladder of canines infected with the distemper virus 
in 73.0% of the cases. Sonne et al. (2009) in 27.8% 
of the dogs and these authors associated the low 
frequency of inclusions in the bladder with the 
desquamation observed in the epithelium of the 
same making it impossible to visualize the inclusion 
bodies. 

Regarding the absence of inclusions bodies 
in other organs Sonne et al. (2009) consider that 
these corpuscles can be identified in other organs or 
not and is therefore not mandatory. Batista, Moura 
and Reis (2000) and Aleman et al. (1992) also 
reported the low frequency of inclusion bodies in 
dogs with distemper. 

The digestive system was the most affected 
in dogs with distemper in this study, especially liver 
and pancreas. (KANESHIGE et al., 2007) observed 
hepatic congestion and necrosis of hepatocytes in 
dogs with distemper and cite that CDV may cause 
liver injury. 

Considering that CDV is a multisystemic 
agent, it may be capable of causing hepatitis 
(KANESHIGE et al., 2007), observed in 41.16% of 
the dogs in this study. Hepatic lipidosis was 
frequent and may be associated with heart failure 
(ANDERSON, 1992; TAMS, 2005), since most of 
the animals presented macroscopic or microscopic 
cardiac alterations. However, differently from these 

studies Sonne et al. (2009) did not identify 
significant microscopic changes in the liver. 

Pancreatic lesions were frequent in this 
study and Tams (2005) cites that the canine 
distemper virus can cause pancreatitis, reinforcing 
the findings of this work. Lymphoid atrophy was 
observed in 29.4% of dogs as reported by Kubo et 
al. (2007). 

Deem et al. (2000) cited pneumonia in dogs 
with distemper as one of the important postmortem 
findings and in their study 52.92% of the dogs had 
pneumonia. Sonne et al. (2009) verified 44.4% of 
the animals with pneumonia and Kubo et al. (2007) 
reported that the main finding in 100 dogs with 
distemper was pneumonia. Also Tudury et al. 
(1997) reported 12.34% of dogs with distemper 
showing bronchopneumonia. 

 
CONCLUSIONS 
 

Gross and microscopic cardiac changes are 
frequently observed in dogs with distemper mainly 
cardiac dilation and myocarditis. Viral inclusions 
bodies in bladder epithelial cells are an important 
microscopic finding for the diagnosis of distemper, 
and lymphoplasmacytic interstitial nephritis was 
also a frequent lesion. 

CDV can be located in the sinoatrial node of 
naturally infected dogs as demonstrated in this study 
by the RT-PCR technique reinforcing the hypothesis 
that CDV is capable of causing inflammatory 
lesions in the sinoatrial node of this species and 
disorders in the cardiac dynamics, compromising its 
normal physiology and leading the dog to death. 

Investigative studies of sinoatrial node 
lesions should be continued not only in dogs but in 
other domestic and wild species. 

 
ACKNOWLEDGEMENTS 
 

This study was financed in part by the 
Coordenação de Aperfeiçoamento de Pessoal de 
Nível Superior – Brasil (CAPES) – Finance Code 
001. The authors thanks Veterinary Hospital of 
Federal University of Uberlândia for support the 
project. 

 
 

 
RESUMO: A cinomose canina é uma doença viral que afeta vários sistemas, dentre eles o 

cardiovascular. Objetivou-se identificar o vírus da cinomose canina no nó sinoatrial (NSA) de cães 
sorologicamente positivos para cinomose, através da reação em cadeia da polimerase, precedida de transcrição 
reversa (RT-PCR), além de analisar os achados macroscópicos e histológicos da cinomose no coração e outros 
tecidos. Foram coletados fragmentos de tecidos e do NSA de 17 cães sorologicamente positivos para cinomose 
que vieram a óbito e foram necropsiados no período de outubro de 2015 a dezembro de 2016. No coração 



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Biosci. J., Uberlândia, v. 36, n. 2, p. 487-495, Mar./Apr. 2020 
http://dx.doi.org/10.14393/BJ-v36n2a2020-42122 

observou-se dilatação cardíaca direita em 76,47% dos cães e hipertrofia concêntrica esquerda em 11,76% dos 
cães. Microscopicamente observou-se miocardite linfocítica em 23,53% dos cães e 41,18% apresentou 
corpúsculos de inclusão viral no epitélio vesical. Somente um (5,88%) cão apresentou fragmento alvo de 319 
bp para cinomose utilizando os primers VCC1 e VCC2, no nó sinoatrial. Conclui-se que o VCC pode localizar-
se no nó sinoatrial de cães naturalmente infectados, como demonstrados neste estudo pela técnica de RT-PCR, 
reforçando a hipótese de que o VCC é capaz de provocar lesões inflamatórias no nó sinoatrial dessa espécie. 
Alterações cardíacas macroscópicas e microscópicas, principalmente dilatação cardíaca e miocardite, são 
frequentemente observadas em cães com cinomose. Inclusões virais nas células epiteliais da bexiga são 
importantes achados microscópicos para diagnóstico da cinomose.  
 

PALAVRAS-CHAVE: Sistema de Condução Cardíaco. Vírus da Cinomose Canina. Cardiomiopatias. 
 
 
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