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Article

First Molecular Detection of Babesia gibsoni in Stray Dogs from Thailand

1
Department of Parasitology, Faculty of Veterinary Medicine, Kasetsart University, Bangkok 10900, Thailand
2
Faculty of Veterinary Science, Prince of Songkla University, Songkhla 90110, Thailand
3
Department of Parasitology, Faculty of Medicine, Khon Kaen University, Khon Kaen 40000, Thailand
4
National Research Center for Protozoan Diseases, Obihiro University of Agriculture and Veterinary Medicine, Obihiro, Hokkaido 080-8555, Japan
*
Authors to whom correspondence should be addressed.
Pathogens 2021, 10(6), 639; https://doi.org/10.3390/pathogens10060639
Submission received: 6 May 2021 / Revised: 18 May 2021 / Accepted: 20 May 2021 / Published: 22 May 2021

Abstract

:
In southern Thailand, the increasingly growing population of stray dogs is a concern to public health and environmental safety because of the lack of medical attention and control. More importantly, these animals are considered reservoirs for many zoonotic pathogens. The objective of this study was to molecularly detect canine vector-borne pathogens, and to perform genetic characterization of Babesia gibsoni present in stray dogs from southern Thailand. Blood samples were collected from 174 stray dogs in two provinces (Songkhla and Narathiwat) in southern Thailand. PCR analyses were executed using specific primers based on the Babesia spp. 18S rRNA gene, Babesia gibsoni Internal transcribed spacer 1 (ITS1) region, Ehrlichia canis citrate synthase (gltA) gene, Hepatozoon spp. 18S rRNA gene and Anaplasma platys heat shock protein (groEL) gene. The most common canine vector-borne pathogen found infecting stray dogs in this study was Hepatozoon canis (24.7%) followed by A. platys (14.9%), Babesia vogeli (8.0%), B. gibsoni (6.3%), and E. canis (1.72%). Concurrent infection with more than one pathogen occurred in 72 cases. Phylogenetic analysis based on the ITS1 region and 18S rRNA gene revealed that the B. gibsoni isolates from this study shared a large proportion of their identities with each other and with other reported B. gibsoni genotypes from Asia. This study highlights the molecular detection of B. gibsoni in dogs in Thailand for the first time and presents the genetic characterization by sequencing the ITS1 region and 18S rRNA gene of B. gibsoni from Thailand. Follow-up studies are needed to elucidate the origin, distribution, and vectors of B. gibsoni parasites circulating in dogs in Thailand, as well as to determine to what extent dogs are important reservoir hosts for zoonotic canine vector-borne disease infection in the studied area.

1. Introduction

Canine vector-borne diseases (CVBDs) including ehrlichiosis, anaplasmosis, babesiosis, and hepatozoonosis are common infectious diseases in dogs caused by various bacteria and protozoa [1,2,3,4]. Anaplasma and Ehrlichia are obligate intracellular bacteria belonging to the family Anaplasmataceae [5], and are mostly detected in canids in tropical and subtropical areas [6,7]. Of the common Ehrlichia species, Ehrlichia canis is the etiologically important agent of canine monocytic ehrlichiosis [8]. Anaplasma phagocytophilum and Anaplasma platys have been documented as the main causative agents of canine anaplasmosis in temperate zones and canine cyclic thrombocytopenia in the tropical area, respectively [7,8]. In addition, of the recently emerged protozoan genera, Babesia and Hepatozoon are among the most widespread apicomplexan protozoan parasites causing severe diseases ranging from subclinical mild anemia to multiple organ failure, and sometimes death in infected dogs [9]. Specifically, at least four species of Babesia (Babesia gibsoni, Babesia canis, Babesia rossi, and Babesia vogeli) and two Hepatozoon species (Hepatozoon canis and Hepatozoon americanum) are agents of canine babesiosis and hepatozoonosis, respectively [5]. Most of the earlier mentioned canine vector-borne pathogens (CVBPs) can be transmitted to other dogs by tick bites, blood transfusion, or dog fighting, except for Hepatozoon, which is transmitted primarily through the ingestion of ticks containing mature H. canis oocysts [3,10].
Babesia gibsoni is found in almost all parts of Asia and is considered a notable threat to canine health, causing the acute form of babesiosis in dogs, typically related to fever, anemia, thrombocytopenia, splenomegaly, and hepatomegaly [11]. In chronic infections, the dogs commonly remain asymptomatic carriers [12]. Genetic characterization and phylogenetic analysis of the 18S rRNA gene demonstrated that there are three genotypically different small Babesia of canines [13] including B. gibsoni sensu stricto [14], Babesia microti-type [15], and Babesia conradae [16]. Moreover, the Internal transcribed spacer 1 (ITS1) region is often used to determine the divergence among species and even among strains of canine Babesia [17]. The high degree of variation in the ITS1 region is commonly employed to genetically differentiate the subspecies level of Babesia spp., which 18S rRNA has failed to demonstrate [17]. Specifically, intraspecific variation within the ITS1 region has already been reported in isolates of three subspecies of B. canis [17]. As for the B. gibsoni Asian genotype, limited studies have been carried out using partial sequence of the ITS1 region for phylogenetic placements of different isolates and to study the intraspecific genetic variability between isolates [18].
Recently, several programs of sterilization under the Thai government for the restriction of stray animal population have been frequently conducted. The epidemiology and clinical importance of B. gibsoni infections in Thailand are not well understood, and limited information is available on genetic characterization of B. gibsoni of dogs in Thailand. The present study was designed to determine the CVBPs present in stray dogs from southern Thailand, using molecular techniques and to further characterize B. gibsoni, using the ITS1 region.

2. Results

2.1. Occurrence of Single and Co-Infections

The PCR-based results showed that the occurrence of CVBPs in stray dog blood samples collected from Songkhla and Narathiwat provinces was 43.1% (75/174). The most common CVBP found infecting stray dogs in this study was H. canis (24.7%) followed by A. platys (14.9%), B. vogeli (8.0%), B. gibsoni (6.3%), and E. canis (1.7%). Co-infections were also present in this study. Infection with A. platys and H. canis (8.0%, 14/174) was the most prevalent concurrent infection, and only one sample (0.6%, 1/174) was found positive for three pathogens in the screened population (Table 1).

2.2. Sequence Analysis

The representative sequences of CVBPs detected in this study were submitted to Genbank under accession numbers MW404321–MW404324 (A. platys), MW404325–MW 404327 (E. canis), MW402988–MW402992 (H. canis), MW403069–MW403073 (B. vogeli), MW403495–MW403499 (B. gibsoni–18S rRNA gene), and MW403987–MW403991 (B. gibsoni–ITS1 region). Subsequently, the obtained sequences of CVBPs in the present study subjected to BLAST analysis were found to share 100% identity with the published sequences from Genbank (Table 2).

2.3. Phylogenetic Analysis of B. gibsoni Using the ITS1 Region and 18S rRNA Sequences

Phylogenetic trees of B. gibsoni were constructed based on the 254 bp-fragments of the ITS1 region and 208 bp-fragments of the 18S rRNA gene from dogs in this study, with the corresponding available database isolates using Maximum Likelihood method with Kimura two-parameter model. In the representing tree, Toxocara canis and Plasmodium falciparum were used as outgroup species to root the tree, respectively. In the ITS1-based phylogenetic tree, the isolates of each considered species including B. gibsoni, B. vogeli, B. microti, and B. canis formed separate clades with high bootstrap support (100%) (Figure 1). In the 18S rRNA- based phylogenetic tree, all the B. gibsoni showed low variability between the sequences obtained from this study and those from other geographic regions, including Malaysia, Japan, China, India, Taiwan, Germany and Asian genotype USA (Figure 2).

3. Discussion

Stray dogs are considered a major concern to the public and the environment [19] since they are not given medical care and are reservoirs for various infectious diseases, including canine vector-borne pathogens [20]. The attempt of reducing the population to prevent some infectious diseases in stray dogs is increasing in the south of Thailand, wherein a project of rabies vaccination prophylaxis and sterilization under the management of the provincial Livestock Development Department and Faculty of Veterinary Science, Prince of Songkla University was conducted. Simultaneously, a study of CVBPs detection by using molecular has been established to report the status of these pathogens circulating in the animals in this area. Our results show that CVBPs including A.platys, E. canis, H. canis, B. vogeli, and B. gibsoni are endemic in the Songkhla and Narathiwat provinces.
The occurrence of CVBPs were frequent in stray dogs in studied areas (43.1%, 75/174), of which H. canis, the causative agent of canine hepatozoonosis, was the most PCR-detected intracellular protozoan parasite (24.7%, 43/174) contracted by canine. The detection rate of these pathogens varies compared to previous reports conducted in the northern areas (41.2%, 28/68) [21] and in the southern areas (43.1%, 78/181) [22]. The variability observed in this study with regard to others could be due to the difference in the number of dogs, the selection criteria, the sampling size, the geographical area, and the sampling season [6,22]. In addition, among the common bacteria infecting the dogs, A. platys, an obligate intracellular Anaplasmataceae bacteria, was previously known as the most prevalent tick-borne bacteria in canids in tropical and subtropical areas in several reports [6]. The Anaplasma platys detection rate (14.9%) from our study showed that it was the most common bacteria found in stray dogs, which reinforced the mentioned statement. Concurrent infections with two or more CVBPs were identified in the studied dogs. This was determined in 21 individuals (12.06%), of which the most prevalent co-infection pattern was H. canis and A. platys (8%, 14/174) (Table 1). The occurrence of co-infection may cause greater pathogenicity whereby greater variable signs were exhibited by the affected dogs, resulting in a more challenging diagnosis. Our finding is in agreement with previous statements on the importance of testing for more than one CVBP [3,6].
The present study provides the first molecular evidence of B. gibsoni infection detected in 11 dog blood samples. This finding is important in molecular phylogenetic studies by contributing to the literature about Babesia epidemiology in Thailand. B. gibsoni have been previously documented from dogs in different countries in Asia such as Malaysia [23], Philippines [24], China [25], and Japan [26]. The most common Babesia species found in dogs in Thailand are B. canis [27] and B. vogeli [21,28,29]. Ticks have been considered as the main vector of Babesia transmission [30], in which Rhipicephalus Sanguineus ticks is the most common tick species in Thailand have been reportedly as carriers of B. canis and B. vogeli [29,31]. The transmission of B. gibsoni through tick species found in dogs in the studied area should be taken into account in further research in order to overcome the limitation of the present investigation as the lack of the pathogen detection in ticks. Furthermore, other ways for CVBPs to spread include blood transfusions or dog fighting [3,10]. Specifically, stray dogs with their roaming behavior might spread ticks from one place to another, thereby playing an important role in CVBP spreading [6]. In the current study, sampling was conducted in the Narathiwat province and the Songkhla province. Interestingly, all samples from Narathiwat (11 samples) were positive with B. gibsoni, while there were no B. gibsoni-positive cases found in Songkha. It is found that Narathiwat shares a long border with Malaysia (Figure 3), which had reported B. gibsoni infection in dogs and their ticks previously [23,32,33]. Thus, this more likely deduces that the detection of B. gibsoni in stray dogs in the Narathiwat province might have been due to the spreading of B. gibsoni-infected dogs or ticks from Malaysia areas [32,33]. The attempt to analyze and compare the phylogenetic of B. gibsoni isolates from this study and those from Malaysia revealed that they shared a 100% identity with each other based on the 18S rRNA gene (Figure 2). However, a 100% identity in the 18S rRNA gene might not accurately reflect genetic diversity between isolates due to its low sensitivity compared to the ITS1 region, as shown in previous reports [17]. Upon phylogenetic analysis of ITS1 sequences, eleven isolates were confirmed as B. gibsoni and representative isolates clustered together in the B. gibsoni clade, with other reported B. gibsoni Asian genotype isolates from Japan, Taiwan, China, and the USA. The B. gibsoni Asian genotype isolates clustered away from the other Babesia spp. The genetic characterization of the ITS1 region of B. gibsoni from Thailand reinforced the ITS1 region as a useful genetic marker to study the genetic divergence, evolution, and relationship among B. gibsoni isolates. Moreover, the attempt of aligning the ITS1-based sequences of B. gibsoni from this study with that of Malaysia failed since the ITS1-based isolates of B. gibsoni are not available in Malaysia. Further investigation of B. gibsoni molecular characteristic should be conducted based on this genetic region to demonstrate the mentioned hypothesis. By sharing the common environment with humans and other domestic animals, the finding of B. gibsoni in dogs from the current study should alert Thai people about the risk of CVBPs infection transmitted from these stray animals to their pets. Therefore, a survey of the evaluation of the risk factors associated with B. gibsoni infection in dogs in this area should also be considered to overcome the limitation of the current study and to develop effective prevention and control strategies to minimize infections by CVBPs.

4. Materials and Methods

4.1. Ethical Consent

All the procedures were conducted according to ethical guidelines for the use of animal samples approved by the ethics committee and decision board of Prince of Songkla University (No. 416/2017) and Obihiro University of Agriculture and Veterinary Medicine (Permit for animal experiment: 290131; DNA experiment: 1724-2).

4.2. Study Area and Sample Collection

The sampling was conducted in the Narathiwat provinces (n = 11) and Songkhla (n = 163), located in the southern part of Thailand (Figure 2). The blood samples were collected from stray dogs under the sterilization services program between September 2014 and December 2015. Each dog was humanely restrained and at least 2 mL of blood sample was obtained from the cephalic vein into a vacutainer blood collection tube containing ethylenediamine tetra-acid (EDTA), performed by a qualified veterinary technician. Subsequently, blood samples were stored in a freezer (−20 °C) at the Faculty of Veterinary Science, Prince of Songkla University, Songkhla, Thailand, until retrieval for further laboratory investigations.

4.3. DNA Extraction and Molecular Detection

The genomic DNA was extracted using the Genomic DNA Mini Kit (Blood/Cultured cell) (Geneaid Biotech Ltd., New Taipei City, Taiwan) following the manufacturer’s instructions. Subsequently, conventional PCR was employed to identify the presence of DNA of Hepatozoon spp., Babesia spp., A. platys, and E. canis with specific primer sets (Table 3). The amplifications were performed in a 25 µL reaction mixture encompassed by distilled deionized water, 3 µL of template DNA (10–80 ng/µL), 10 pmol of each primer, 250 µM of each deoxynucleotide triphosphate, 2 µL of 10X Ex Taq buffer, and 1 unit of Ex Taq DNA polymerase (Takara Bio, Kyoto, Japan). Amplifications were performed using MyCycler Thermal Cycler (Bio-Rad, Hercules, CA, USA) under the conditions described in Table 3. Negative controls (distilled deionized water) and positive controls (DNA of each pathogen) were used in each PCR reaction. The PCR products were checked by electrophoresis in 1.5% agarose gel (LE agarose, Thermo Fisher Scientific, Waltham, MA, USA) and TAE (Tris-acetate-EDTA) buffer.

4.4. Sequence and Phylogenetic Analysis

The positive amplicons were snipped from the gel and purified using QIAquick Gel Extraction Kit (QIAGEN GmbH, Hilden, Germany) according to the manufacturer’s instructions. Subsequently, the nucleotide sequences of the target DNA fragments from both directions were determined using an ABI PRISM 3100 Genetic Analyzer (Applied Biosystems, Waltham, MA, USA). After obtaining the sequence results, the sequences were compared with published isolates using the Basic Local Alignment Search Tool (BLAST) of the U.S. National Center for Biotechnology Information (https://blast.ncbi.nlm.nih.gov/Blast.cgi, accessed on 17 May 2021) and alignment was achieved using the BioEdit program version 7.5.2 (https://bioedit.software.informer.com/, accessed on 17 May 2021).
The genetic relationship of Babesia gibsoni based on the ITS1 region and the 18S rRNA gene obtained in the Narathiwat province in the present study, and that from other regions of the world, was determined by phylogenetic analyses using the MEGA version X program (accessed on 17 May 2021) [39]. The maximum-likelihood method with Kimura two-parameter model was employed to construct the phylogenetic trees. Bootstrap analysis with 1000 replications was set to estimate the reliability of the branching patterns of the trees.

4.5. Statistical Analysis

The detection rate and confidence intervals (95%) for each species were calculated using the R software [40].

5. Conclusions

The present study was the first to record and characterize the phylogeny of B. gibsoni based on the ITS1 region and the 18S rRNA gene in dogs in southern Thailand. Further survey with additional samples from dogs and their tick vectors should be conducted to evaluate the risk factors associated with CVBPs infection in dogs in these areas to prevent and minimize the infections.

Author Contributions

Conceptualization, T.I. and X.X.; sample and data collection, R.N., V.S., and O.P.; methodology, T.I., T.D., R.N. and M.L.; data analysis, T.I., T.D. and R.N.; funding acquisition, T.I. and X.X.; writing—Original draft preparation, T.I. and T.D.; writing—Review and editing, T.I., R.N. and X.X. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by a grant from the Japan Society for the Promotion of Science (JSPS) Core-to-Core Program.

Institutional Review Board Statement

The study was conducted according to ethical guidelines for the use of animal samples approved by the ethics committee and decision board of Prince of Songkla University (No. 416/2017) and Obihiro University of Agriculture and Veterinary Medicine (Permit for animal experiment: 290131; DNA experiment: 1724-2).

Informed Consent Statement

Not applicable.

Data Availability Statement

Data are contained within the article.

Acknowledgments

The authors gratefully acknowledge the staff of the Livestock Department in Songkhla and Narathiwat provinces for providing help in collecting samples.

Conflicts of Interest

The authors declare that they have no conflicting or competing financial or personal interests that could influence the work reported in this study.

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Figure 1. Phylogenetic tree of Babesia gibsoni based on the 254 bp-fragment of the ITS1 region using Maximum Likelihood method (Kimura two-parameter model). Numbers at the nodes represent percentage occurrences clades based on 1000 bootstrap replication of data. The sequence of Toxocara canis (JN593098) was used as outgroup.
Figure 1. Phylogenetic tree of Babesia gibsoni based on the 254 bp-fragment of the ITS1 region using Maximum Likelihood method (Kimura two-parameter model). Numbers at the nodes represent percentage occurrences clades based on 1000 bootstrap replication of data. The sequence of Toxocara canis (JN593098) was used as outgroup.
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Figure 2. Phylogenetic tree of Babesia gibsoni based on the 18S rRNA region using Maximum Likelihood method (Kimura two-parameter model). Numbers at the nodes represent percentage occurrences clades based on 1000 bootstrap replication of data. The sequence of Plasmodium falciparum (JQ627149) was used as outgroup.
Figure 2. Phylogenetic tree of Babesia gibsoni based on the 18S rRNA region using Maximum Likelihood method (Kimura two-parameter model). Numbers at the nodes represent percentage occurrences clades based on 1000 bootstrap replication of data. The sequence of Plasmodium falciparum (JQ627149) was used as outgroup.
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Figure 3. Map of Songkhla and Narathiwat province in Thailand where the dog blood samples were collected.
Figure 3. Map of Songkhla and Narathiwat province in Thailand where the dog blood samples were collected.
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Table 1. Occurrence of tick-borne pathogens in stray dogs from Songkhla and Narathiwat provinces, Thailand.
Table 1. Occurrence of tick-borne pathogens in stray dogs from Songkhla and Narathiwat provinces, Thailand.
PathogenNo. Positive
(N = 174)
Detection Rate
(95% CI)
Single infection
Anaplasma platys105.7 (2.26–9.15)
Ehrlichia canis10.6 (0–1.75)
Hepatozoon canis2313.2 (8.17–18.23)
Babesia gibsoni116.3 (2.69–9.91)
Babesia vogeli95.2 (1.9–8.49)
Mixed infection
Anaplasma platys + Hepatozoon canis148.0 (3.96–12.03)
Anaplasma platys + Babesia vogeli10.6 (0–1.75)
Ehrlichia canis + Hepatozoon canis10.6 (0–1.75)
Hepatozoon canis + Babesia vogeli42.3 (0–4.53)
Anaplasma platys + Ehrlichia canis+ Hepatozoon canis10.6 (0–1.75)
Total positive7543.1 (35.74–50.46)
Negative samples9956.9 (49.64–64.26)
Table 2. Representative sequences of canine vector-borne pathogens detected in the study.
Table 2. Representative sequences of canine vector-borne pathogens detected in the study.
No.SpeciesGeneLength (Base-Pair)Accession no.
(Submitted)
Accession no.
(Reference)
Query Cover (%)Percent Identity (%)
1A. platysgroEL694MW404321–MW404324KU765205; KY425417100100
2E. canisgltA1249MW404325–MW 404327KU765198; CP025749100100
3H. canis18S rRNA666MW402988–MW402992KU765202; MK091085100100
4B. vogeli18S rRNA208MW403069–MW403073MT386936; MT012237100100
5B. gibsoni18S rRNA208MW403495–MW403499MN134517; MG604547100100
6B. gibsoniITS1254MW403987–MW403991MN928851; KP666153100100
Abbreviations: groEL: heat shock protein gene, gltA: citrate synthase gene, ITS1: Internal transcribed spacer 1.
Table 3. Sequences of primer sets used for the detection of canine vector-borne pathogens.
Table 3. Sequences of primer sets used for the detection of canine vector-borne pathogens.
Pathogen
(Target Gene)
Oligonucleotide Sequences (5′→3′)Product Size (bp)Annealing Temp (°C)Reference
Babesia spp. (18S rRNA)F: GCATTTAGCGATGGACCATTCAAG
R: CCTGTATTGTTATTTCTTGTCACTACCTC
20860[34]
Babesia gibsoni (ITS1)F: ACATTGAAACTTGTCGAGCTGCG
R: AGATCCCGCACCCAGCCAC
25460[35]
Ehrlichia canis (gltA)F: TTATCTGTTTATGTTATATAAGC
R: CAGTACCTATGCATATCAATCC
137253[36]
Hepatozoon spp. (18S rRNA)F: ATACATGAGCAAAATCTCAAC
R: CTTATTATTCCATGCTGCAG
66657[37]
Anaplasma platys (groEL)F: AAGGCGAAAGAAGCAGTCTTA
R: CATAGTCTGAAGTGGAGGAC
72458[38]
Abbreviations: F: Forward, R: Reverse, groEL: heat shock protein gene, gltA: citrate synthase gene, ITS1: Internal transcribed spacer 1.
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Do, T.; Ngasaman, R.; Saechan, V.; Pitaksakulrat, O.; Liu, M.; Xuan, X.; Inpankaew, T. First Molecular Detection of Babesia gibsoni in Stray Dogs from Thailand. Pathogens 2021, 10, 639. https://doi.org/10.3390/pathogens10060639

AMA Style

Do T, Ngasaman R, Saechan V, Pitaksakulrat O, Liu M, Xuan X, Inpankaew T. First Molecular Detection of Babesia gibsoni in Stray Dogs from Thailand. Pathogens. 2021; 10(6):639. https://doi.org/10.3390/pathogens10060639

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Do, Thom, Ruttayaporn Ngasaman, Vannarat Saechan, Opal Pitaksakulrat, Mingming Liu, Xuenan Xuan, and Tawin Inpankaew. 2021. "First Molecular Detection of Babesia gibsoni in Stray Dogs from Thailand" Pathogens 10, no. 6: 639. https://doi.org/10.3390/pathogens10060639

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