Introduction

Canine adenovirus (CAV), a non-enveloped dsDNA virus, is a member of the genus Mastadenovirus under the family Adenoviridae. Based on genetic and antigenic characteristics, canine adenoviruses are divided into two types: canine adenovirus type 1 (CAV-1) and canine adenovirus type 2 (CAV-2) [1]. Although CAV-1 affects the digestive tract and causes infectious canine hepatitis (ICH) accompanied by uveitis and interstitial nephritis in dogs, CAV-2 is mainly associated with respiratory type of disease [2]. Currently, the control of canine adenoviral disease in canids is mainly based on the use of live attenuated vaccines containing attenuated strains of CAV-2, which also cross-protects against CAV-1 [3]. However, besides the widespread use of vaccines to prevent adenovirus infection in canids, recurrent CAV-1- or CAV-2-associated infections have been documented in dogs and many wildlife species raising the concern about the real epidemiological picture of canine adenovirus in dogs [4,5,6,7].

Although CAV-2 is supposed to cause a transient and asymptomatic or mild form of respiratory disease and remains restricted to the upper respiratory tract causing laryngeotracheitis, in presence of other pathogens or in immune-compromised host, it has been reported to cause severe necrotising bronchitis and interstitial pneumonia [3]. CAV-2 is also associated with fatal cases of diarrhoea [8, 9] and neurological disease in dogs [5]. With the widespread use of modified-live vaccines to protect dogs from infectious agents such as canine adenovirus, it is now being considered as a pathogen of less importance and is neglected by clinicians. Nevertheless, fatal outbreaks of CAV-2 are being reported across the globe including some more recent studies [1, 10]. This study reports the CAV-2 infection in a dog with neurological and respiratory symptoms which was confirmed by the sequencing of the partial E3 gene and virus isolation in MDCK cells. The sequence generated in this study was also compared with the CAV-2 sequences available from different parts of the world to elucidate the genetic heterogeneity among the CAV-2 strains.

Materials and methods

Sampling

In November 2018, a Labrador retriever dog of 6 months of age from Bareilly, Uttar Pradesh, was presented with the symptoms of coughing, neurological spasms and vomit after food intake. No fever was noticed in the dog and the nasal, conjunctival and rectal swabs were collected in the viral transport media suspecting canine distemper. As these samples were collected for the purpose of disease diagnosis in clinics, therefore, no ethical approval was required. As per the history provided by the owner, vaccination was carried out with a single shot of multivalent vaccine at 3 months of age. The animal had been intensively treated with antibiotics and supportive fluid therapy but it was reported to have died the next day, as conveyed by the owner, and thus, further samples could not be collected.

PCR assays and sequencing

While nasal and conjunctival swabs were tested for the presence of canine distemper virus (CDV), the rectal swab was tested for the presence of canine parvovirus (CPV) and canine adenovirus–specific nucleic acids through polymerase chain reaction (PCR). RNA and DNA were isolated from nasal, conjunctival and rectal swabs using RNeasy Mini Kit (Qiagen, Germany) and DNeasy kit (Qiagen, Germany) according to the manufacturer’s instructions. Extracted nucleic acids were subjected for PCR amplification using previously published primers for detection of CDV, CPV and CAV-1/2 [2, 11,12,13]. The plasmid carrying the E3 gene of CAV-1 isolate (GenBank Accession no. KX181846), Nucleocapsid gene of CDV (GenBank Accession no. MF964188) and VP2 region of CPV (GenBank Accession no. KC429662) available in our laboratory were used as a positive control in the PCR assay for respective viral agents. The amplified product was gel purified using QIA Quick Gel Extraction Kit (Qiagen, Germany) and cloned into pJET 1.2 blunt vector (Thermo Fisher Scientific) followed by sequencing (Eurofins Genomics, India).

Phylogenetic analysis

For phylogenetic reconstruction, available sequences representing the E3 region of CAV-2, CAV-1 and other related adenoviruses were retrieved from NCBI and aligned using online MAFFT (Multiple Alignment using Fast Fourier Transform) version 7 software (http://mafft.cbrc.jp/alignment/server/index.html) in MSA program. The best-fit nucleotide substitution model was predicted in the Molecular Evolutionary Genetics Analysis software version X (MEGA-X) [14] and the phylogenetic tree was constructed employing the Maximum-Likelihood method using Kimura 2-parameter model with 1000 bootstrap replications to confirm the authenticity of the taxa analysed for each node.

Virus isolation

For virus isolation, filtered supernatant of the rectal swab was inoculated onto a monolayer of Madin-Darby Canine Kidney (MDCK) cells in 25 cm2 tissue culture flasks and incubated at 37 °C for 1 h. After 1 h of adsorption, Minimum Essential Medium Eagle (Sigma-Aldrich, USA) containing 10% foetal bovine serum along with 10,000 units penicillin, 10 mg streptomycin and 25 μg amphotericin B per millilitre (Antibiotic Antimycotic Solution, 100 × Sigma-Aldrich, USA) was added and the flask was incubated at 37 °C. The cells were examined daily under the microscope and blind passaged until visible CPE was evident.

Fluorescent antibody test (FAT)

To confirm the identity of isolated virus, direct fluorescent antibody test (DFAT) was performed in a 96-well cell culture plate seeded with MDCK cells (Fig. 1). The MDCK cells were inoculated with the 200 TCID50 of isolated virus and incubated at 37 °C for 96 h. After 96 h, the cells were washed with PBS and fixed with chilled acetone/PBS (phosphate-buffered saline; 80:20) for 30 min at 4 °C. Thereafter, acetone/PBS solution was discarded and anti-CAV-2 polyclonal antiserum conjugated to fluorescein isothiocyanate (Canine adenovirus FITC conjugated; VMRD, Pullman, Washington) was added to the virus-infected and control wells followed by incubation at 37 °C for 30 min. After incubation, the plate was washed several times with FA rinse buffer (pH 9.0) and observed under a fluorescent microscope after adding the mounting fluid.

Fig. 1
figure 1

Virus isolation in MDCK Cell line: a Infected monolayer of MDCK cells shows cell rounding, detachment, cytoplasmic fusion, vacuolation and cell death at 3 dpi (20 × magnification). b Mock-infected MDCK cells at 3 dpi (20 ×). c VNT in MDCK cell line showing clear neutralization with no observable CPE (20 ×). d Direct FAT (fluorescent antibody test) showing MDCK cells infected with 10−1 dilution of CAV-2 with characteristic CPE (20 ×). e Mock-infected MDCK cells at 3 dpi (20 ×) and f VNT in MDCK cell line showing clear neutralization with no noticeable fluorescence (20 ×)

Virus neutralization assay

The identity of the isolated virus was also confirmed by virus neutralization test (VNT). In brief, the MDCK-adapted virus (200 TCID50/ml) was incubated with an equal volume of anti-CAV-2 antibody serum for 1 h at 37 °C and inoculated in 96-well plate seeded with MDCK cells followed by incubation at 37 °C for 96 h. The VNT plate was observed under the microscope 96 h post-inoculation to record the results.

Results and discussion

Canine adenovirus type 2 is a common respiratory pathogen and causes a mild disease in dogs. Only occasionally, it has been reported to cause gastrointestinal or neurological complications [5, 8]. In this study, the samples collected from a dog showing respiratory signs with nervous system involvement were tested for the presence of CDV, CPV and CAV1/2. While the samples were tested negative for CDV and CPV, an amplicon of 1032 bp length was amplified in PCR using E3 gene–based differential PCR for CAV1/2 [2, 12]. The amplified product was sequenced and 858 bp sequence representing E3 region of CAV-2 was submitted to NCBI with the accession number MT318141. Nucleotide BLAST analysis of sequence generated in this study confirmed the presence of CAV-2-specific nucleic acid in the positive sample.

The nt. alignment of CAV-2 sequence generated in this study with the other CAV-2 sequences available from different countries revealed a “G” nucleotide insertion at the nt. position 1077 in the E3 gene (ORF2) (Fig. 2a). These findings are in agreement with a recent study from India [9] and reinforce the unique signature “G” nt. insertion in E3 gene of Indian CAV-2 isolates. The addition of “G” residue resulted in a frameshift and imparted additional eleven amino acids (aa) to the E3 protein of Indian CAV-2 isolates (Fig. 2b). As it is suggested that the E3 protein of CAV-2 is crucial for modulating the host immune response in adenovirus-infected cells [15], it will be imperative to investigate the effect of a comparatively larger E3 protein on host–virus interactions and disease progression.

Fig. 2
figure 2

Aligned nucleotide sequence of E3 region of CAV-2 generated in this study along with CAV-2 sequences from different parts of the world (a) and deduced amino acid sequence alignment of different CAV-2 isolates (b). [The insertion of “G” nt. in the Indian isolates is represented by eclipse (a) and the extension of reading frame by eleven aa in the Indian isolates is indicated by a rectangle (b)]

On phylogenetic reconstruction, while CAV-1 and CAV-2 were clustered in different groups, bat and equine adenovirus sequences formed the out-group (Fig. 3). Among the CAV-2 sequences, as was previously described [1], Chinese and Turkish strains formed a different subgroup separated from the America-Europe subgroup. The CAV-2 sequences from India including the sequence generated in this study formed a monophyletic group separated from the previously identified two subgroups of CAV-2 (Fig. 3). The comparison of the region corresponding to terminal 245 aa of putative E3 region ORF2 of canine adenovirus type 2 revealed an evolutionary divergence of 3.3% at aa level between the Indian strain and the Toronto A26/61 strain (Accession no. U77082) (Table 1) grouped under America-Europe subgroup in the phylogenetic tree. Indian CAV-2 isolated in the current study appears to be more closely related to the strains from Italy and Brazil than the Chinese and Turkish isolates of CAV-2. However, this study is based on only the partial sequence of E3 region and therefore, further studies with more sequence data are augmented to get a clear picture of the evolutionary history of CAV-2 circulating in India.

Fig. 3
figure 3

Phylogenetic tree based on the sequence of partial E3 region from 33 strains of adenoviruses (CAV-1, CAV-2, EqAV-1 and Bat adenovirus) generated by using the Maximum-Likelihood method and Kimura 2-parameter model with 1000 bootstrap replications using MEGA-X software. Equine and Bat adenoviruses were used as an outgroup. GenBank accession numbers are provided for all the sequences

Table 1 Uncorrected evolutionary divergence between amino acid sequences corresponding to terminal 245 aa of putative E3 region ORF2 of CAV-2 strains from different countries. Standard error estimates are shown (in italics) above the diagonal and were obtained by a bootstrap procedure with 1000 replicates

The virus was successfully isolated in MDCK cells using rectal swab found positive for CAV-2-specific nucleic acids as a source of inoculum. The visible CPE, characterized by cell rounding, detachment, cytoplasmic fusion, vacuolation and cell death, was seen as early as 72 h post-infection from the 5th passage onwards (Fig. 1). In DFAT, green fluorescence could be seen in the virus-infected cells while no colour signal was detected in the control wells which confirmed the presence of CAV-2 in the infected wells (Fig. 1). The results of DFAT were further validated in VNT using CAV-2-specific antisera. While CAV-2-specific CPE could be seen after 96 h of incubation in control wells infected with the virus, mock-infected and the test wells inoculated with virus-antibody mixture did not show any visible CPE. Further, testing of VNT plate by DFAT revealed no colour signal in test wells inoculated with virus-antibody mixture indicating complete neutralization of virus by anti-CAV-2 antibody (Fig. 1).

The detection and isolation of CAV-2 from a dog showing nervous signs which was subsequently found negative for other canine pathogens reinforce the neuronal tropism of CAV-2, as was described previously [5]. As the dog was vaccinated with the multivalent vaccine 3 months before the appearance of clinical signs, the chances of vaccine strain–induced disease are negligible. Also, a previous study has shown that dogs vaccinated with CAV-2 vaccine do not shed vaccine virus beyond the 6th day post-vaccination [16, 17]. Sequencing results also ruled out any chances of vaccine strain–induced disease in the dog. To our limitation, as the outcome of infection was fatal, studies to investigate pathological changes in the brain and other tissues could not be carried out due to the non-compliance of the dog owner.

The reason for the development of neurological signs could be assigned to the involvement of the brain or the hypoxia due to involvement of the respiratory system as suggested in a previous study where the nervous symptoms were noticed in the pups infected by CAV-2 but any appreciable changes in the nervous tissue were not observed [5]. It is to mention here that CAV-2 engages the coxsackievirus and adenovirus receptor (CAR), a member of the CTX subfamily of immunoglobulin (Ig) superfamily to transduce the motor neurons and undergo retrograde transport [18]. Soudais and co-workers reported the preferential transduction of neuron by CAV-2 following intramuscular injection [18]. Additionally, retrograde axonal transport is also used by other viruses like poliovirus and bacterial tetanus toxin which also induce nervous symptoms [19]. Although a similar mechanism of retrograde transport may be responsible for neurological disease in CAV-2-infected dogs, the association of CAV-2 with the neurological disease should be used with caution unless it is proven with sufficient experimental data.

After the introduction of live-modified vaccines and their widespread use to control disease, the incidence of canine adenoviral infections has reduced [20] and until a recent study [9], the prevalence of CAV-2 in the dog population in India was unreported. It is to mention that there are only a few reports of CAV-2-associated neurological disease of dogs and hence, the possibility of CAV-2 causing the nervous signs is ignored by the clinicians which could be the reason that CAV-2 remained unreported in the past. Moreover, the clinical picture of CAV-2 overlaps with that of other canine pathogens like canine herpes virus, canine parainfluenza virus, canine distemper virus and Bordetella bronchiseptica which further complicates the diagnostic approach by the clinicians. As the dog was vaccinated 3 months back and proper vaccination schedule was not followed, there is no point of vaccine ineffectiveness although reported previously [7, 21]. The reason for CAV-2-associated disease may be ascribed to the non-adherence of dog owners to the proper vaccination schedule and large free-roaming population of canids acting as reservoirs of infection.

Conclusion

This study could establish the presence of CAV-2 in a dog showing respiratory and nervous symptoms. The virus could successfully be isolated in MDCK cells and was characterized by sequencing of partial E3 region, immunofluorescence and virus neutralization test. Detection of a novel CAV-2 in cases of gastroenteritis and dog showing nervous signs from two distant locations in the country augments the need for generation of more sequence data from different geographical areas and involving the longer regions of viral genome to get a clear picture of molecular epidemiology of CAV-2 in India. The study also reinforces the importance of adherence to proper vaccination protocols in order to prevent the disease in susceptible population.