|Year : 2019 | Volume
| Issue : 10 | Page : 457-462
Detection of Trypanosoma spp. in Bandicota indica from the Thai-Myanmar border area, Mae Sot District Tak Province, Thailand
Phuangphet Waree Molee1, Natthiya Sakulsak2, Somchai Saengamnatdej1
1 Department of Microbiology and Parasitology, Faculty of Medical Science, Naresuan University, Phitsanulok, Thailand
2 Department of Anatomy, Faculty of Medical Science, Naresuan University, Phitsanulok, Thailand
|Date of Submission||10-Apr-2019|
|Date of Decision||10-Oct-2019|
|Date of Acceptance||12-Oct-2019|
|Date of Web Publication||30-Oct-2019|
Phuangphet Waree Molee
Department of Microbiology and Parasitology, Faculty of Medical Science, Naresuan University, Phitsanulok
Source of Support: None, Conflict of Interest: None
Objective: To investigate the prevalence of trypanosome infection and their phylogeny in Bandicota indica rats from the cadmium-contaminated area of Mae Sot and the Myanmar border.
Methods: Blood samples were taken from 100 animals, and parasite infection was examined by light microscopy observation and polymerase chain reaction (PCR) studies.
Results: Trypanosoma spp. infection was found in 20% of the thin blood smear samples. PCR showed positive 623 bp DNA bands in 21 samples (21%). The sequencing analysis showed that all of the samples (100%) had the Trypanasoma lewisi 18S ribosomal RNA gene. Phylogenetic analysis confirmed that these 16 isolates of Trypanosoma spp. were closely related to Trypanasoma lewisi.
Conclusions: Molecular detection using PCR is as effective as conventional light microscopy analysis. This study confirms that trypanosomal infection in rodents is still high; therefore, fleas as their vectors need to be controlled in order to prevent transmission to humans.
Keywords: Trypanosoma, spp., Polymerase chain reaction, Phylogenetic analysis, Zoonoses, Bandicota indica
|How to cite this article:|
Molee PW, Sakulsak N, Saengamnatdej S. Detection of Trypanosoma spp. in Bandicota indica from the Thai-Myanmar border area, Mae Sot District Tak Province, Thailand. Asian Pac J Trop Med 2019;12:457-62
|How to cite this URL:|
Molee PW, Sakulsak N, Saengamnatdej S. Detection of Trypanosoma spp. in Bandicota indica from the Thai-Myanmar border area, Mae Sot District Tak Province, Thailand. Asian Pac J Trop Med [serial online] 2019 [cited 2020 Jul 4];12:457-62. Available from: http://www.apjtm.org/text.asp?2019/12/10/457/269907
| 1. Introduction|| |
Trypanosoma spp. is a parasitic protozoon living in the blood and tissues of vertebrates and mammals including humans. Trypanosoma spp. can be transmitted from animals to people via insect vectors bites, causing trypanosomiasis with the pathogen in a metacyclic trypomastigotes form. All 44 species, that can be transmitted from animals to humans (Zoonoses) contribute to various diseases depending on the strain and route of infection. For example, in Africa, Trypanosoma (T.) brucei causes African trypanosomiasis or sleeping sickness. The disease is restricted to tropical areas of Africa with the insect vector, the tsetse fly. While T. cruzi found in North and South America causes American trypanosomiasis (Chagas’ disease) with the insect killer (Reduviid bugs) as vectors. Study on infectious Trypanosoma spp. in blood samples from mice using the polymerase chain reaction (PCR) reported that in Southeast Asia, infection of Trypanosoma spp. is mainly from two species that can be transmitted from animals to humans: T. lewisi , and T. evansi, in Malaysia, Thailand, Sri Lanka and India. These two species cause disease in humans, and have different carriers: fleas living on rats and voles as the carriers for T. lewisi, and blood-sucking insects, such as midges as the main vectors for T. evansi,. The assumed life cycle of T. lewisi [Figure 1] begins with rat fleas taking a blood meal from vertebrate hosts, and then the metacyclic trypomastigotes penetrate various cells at the bite wound site. Amastigotes multiply by binary fission in the infected cells and form a pseudocyst. When the pseudocysts rupture, the trypomastigotes are released into the bloodstream where they infect other cells, and transform into amastigotes, or are taken with a blood meal by rat fleas and transformed into epimastigotes. Inside the rat flea vector, the epimastigotes multiply in the midgut, then migrate to the hind gut and differentiate into the infective metacyclic trypomastigotes stage.
Most infections in Thailand are caused by T. lewisi with infection rates as 48.8%, 22.3%, 13.9%, 8.3% and 2.2% in Bangkok, Kanchanaburi, Buriram, Nan and Loei, respectively. The first case of T. lewisi infection in humans was reported in a premature Asian child, who lived in a rat-infested dwelling. Other human infections caused by this parasite were described mainly in Asia,,, including fatal cases, and also in Africa. In the North of Thailand, a report about a child with the symptoms as high fever, anemia, coughing, anorexia and depression found T. lewisi as the causative agent through hematological analysis. Bandicota (B.) indica is one of the important reservoir hosts of the zoonotic trypanosome. T. lewisi-like parasites were first reported in rats from Chiang Mai Province. T. lewisi and other Herpetosoma are commonly found in the blood of rats worldwide, and members of this subgenus are generally considered to be non-pathogenic and rarely found in humans. T. lewisi was found in 14.3% of Rattus spp. and 18.0% in B. indica from the rodents trapped in urban and rural areas of three Thailand provinces between 2006 and 2007. Thus, Rattus and Bandicota species are possible sources for human exposure to these parasites. Since Thailand joined the Association of Southeast Asian Nations Economic Community, members and animals have moved freely throughout Asia. Monitoring parasites in the B. indica should be regularly performed because the pathogens can spread from animals to people. The aim of this study was to investigate the prevalence of the trypanosome infection in B. indica from the cadmium-contaminated area of Maesot and the Myanmar border by microscopic analysis and polymerase chain reactions detection. Besides, the phylogenetic relationship was analyzed using the bioinformatics program. The identification of the Trypanosoma spp. species infecting the B. indica rats should be helpful for controlling and prevention of the infection.
| 2. Materials and methods|| |
One hundred (B. indica) rats trapped in Mae Sot, Tak Province, Northern Thailand were selected. The geographical location of Mae Sot District, Tak Province, Thailand in the Thai-Myanmar border area is shown in [Figure 2]. The animals were housed and acclimatized in cages containing food and water as appropriate. The animals were euthanized using the cervical dislocation method. Following euthanasia of small rodents (NUCAR SOP No.05-14), the carcasses were collected in a red bag, and placed in a freezer at -20 °C before being incinerated.
|Figure 2: Geographical location of Mae Sot District, Tak Province, Thailand in the Thai-Myanmar border area.|
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This study was approved by the Naresuan University Animal Care and Use on June 26th, 2015, with certificate No. 5802003.
2.2.1. Blood sample collection
The rats were dissected following standard operating procedures to reveal their abdomen and chest cavity, and 2 mL of blood was removed from the left ventricle using a syringe. A drop of the blood sample was collected for the smear test, and the remainder was preserved in citrate salt tubes, and stored at -20 °C for the PCR detection.
2.2.2. Microscopic diagnosis (thin blood film)
Blood films were made by placing a drop of blood on one end of a slide, and then smeared using a spreader in order to obtain a thin film of blood for counting and differentiation. The smeared slides were left to air-dry, fixed in methanol, and then subjected to the process of Giemsa’s staining. After this process, the slides were examined for Trypanosoma spp. infection under a light microscope.
2.2.3. Molecular diagnosis
All 100 samples were detected by the PCR technique. Following the extraction of DNA by a NucleoSpin blood DNA kit, the concentrations were measured with a Nanodrop. Primers TRYP1S (5’CGT CCC TGC CAT TTG TACA CA-3’) and TRYP1R (5’-GGA AGC CAA GTC ATC CAT CG-3’) were used for the amplification of the internal transcribed spacer 1 (ITS)-1 fragment. The PCR was carried out in 20 μL solution, which consisted of Master mix 10 μL containing Buffer MgCl2 dNTPs (dTTP, dGTP, dCTP, and dATP) and Taq polymerase, 0.4 μL of each primer, 2 μL DNA template and 7.2 μL deionized water (18 M ). PCR was run with an initial denature at 94 °C for 2 min, followed by 30 cycles of 30 s at 94 °C, 30 s at 61.5 °C and 30 s at 72 °C with a final extension of 72 C for 10 min. The PCR products were then electrophoresed on a 2% agarose gel and stained with nucleic acid staining solution (Red SafeTM, iNtRON Biotecnology, Inc.) for analysis. The visualization of a 623 bp was considered as a positive result.
2.2.4. Phylogenetic analysis
The PCR products were purified using NucleoSpin Gel and a PCR Clean-up kit (Macherey-Nagel, Germany) as recommended by the manufacturer. The DNA sequencing was performed by Macrogen Inc. service in Korea. The gene sequences were analyzed using a nucleotide BLAST search via NCBI. The nucleotide sequences were aligned using Clustal W. A phylogenetic tree was reconstructed using the maximum likelihood method with the MEGA Version 7.0 program.
| 3. Results|| |
3.1. Prevalence of Trypanosoma spp. infection
Microscopic analysis showed a prevalence of 20% for Trypanosoma spp. infection [Figure 3], while PCR analysis demonstrated a prevalence of 21%.
|Figure 3: Light microscopic images of thin blood films showing presence of Trypanosoma spp. (A) The trypomastigote stage under a magnification of 400×(arrows), and (B) under a magnification of 1 000× in oil immersion (arrows).|
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3.2. Phylogenetic results
Sequence trace files identified the Trypanosoma spp. as T. lewisi [Figure 4]. The BLAST search (87%-98%) via NCBI showed that all of them (100%) were T. lewisi [Figure 5]. From 100 samples, 21 were PCR-positive. We could sequence only 16 samples of these PCR-positive samples because of failure to obtain enough PCR products for sequencing RE38, RE58, RE77, RE90 and RE93. Sixteen of the 21 PCR positive samples were analyzed by the BLAST sequencing application. All of them (100%) contained T. lewisi 18S ribosomal RNA gene [Table 1].
|Figure 5: Sequencing compared to the NCBI database for Trypanosoma lewisi.|
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|Table 1: BLAST results showing identity of the pathogenic isolates of Trypanosoma lewisi.|
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Based on phylogenetic analysis, 16 of the 21 samples were Trypanosoma spp. positive, and were closely related to T. lewisi [Figure 6].
| 4. Discussion|| |
In our study, the microscopic analysis revealed infection of Trypanosoma spp. in 20 of the specimens: RE2, RE5, RE38, RE47, RE56, RE58, RE63, RE64, RE68, RE69, RE71, RE73, RE75, RE77, RE78, RE82, RE83, RE85, RE86 and RE90. Our results were similar to a comparative study of the techniques using 423 mice blood samples in Peninsular, Malaysia, which reported the prevalence rate of Trypanosoma spp. infection in the quantitative buffy coat was 20.8% and in the Giemsa-stained technique was 22.0%. In fact, different geographic locations in Thailand seemed to have a wide-range of infections of T. lewisi. Five regions in Thailand, Bangkok, Kanchanaburi, Buriram, Nan and Loei were found to have an infection rate of 48.8%, 22.3%, 13.9%, 8.3% and 2.2%, respectively. Interestingly, a similar prevalence rate was found in Kanchanaburi, a province bound to Myanmar.
We also estimated the prevalence of this parasitic protozoon by PCR using genus-specific primers, TRYP1S and TRYP1R. These have also been used to detect and diagnose T. lewisi infection in an infant living in Lampang, Thailand and T. lewisi infection in rodents Thailand. This molecular technique could amplify the ITS1 sequence (623 bp) between 18S and 5.8S rDNA region of trypanosome in all the blood smear positive samples with one more sample (RE93) not detected by the light microscopy. The prevalence rate detected by this molecular technique was 21%. Detection of the trypanosome infection with PCR was previously reported to be more sensitive than the thin blood film method. The possible reason may be due to the total number of protozoa in the blood samples. If it is too low, it may not be detected by the blood smear method.
Although the right size of the PCR product could ensure trypanosomal infection, the analysis of the sequence inside the ITS1 is essential to identify the species. The specific and the variable sequence inside ITS1 could define T. lewisi. In this study, we sequenced all the PCR products and the analysis was performed with BLAST-search in the database, which was also used to find out the type of infection in the rodents in Thailand. Our result showed that the species of all the positive samples were T. lewisi. High prevalence of T. lewisi was previously observed in rodents living near human settlements and in areas with high cover of built-up habitat. Different species of Trypanosoma spp. were transmitted by various kinds of vectors. The T. brucei which causes African trypanosomiasis or sleeping sickness was transmitted by tsetse flies; while T. brucei which causes Chagas’ disease was transmitted by triatomine bugs. From our findings and former work, we assumed that T. lewisi might be transmitted by rat fleas. Thailand has joined the Association of Southeast Asian Nations Economic Community that allows people and animal populations to move freely. Therefore, the trypanosome infection should be monitored as the transmission of pathogens from animals to humans can cause disease.
This study reveals the prevalence of Trypanosoma spp. detected by PCR to be 21% in the Thailand-Myanmar border region of Mae Sot, Tak Province. The parasite species is confirmed as T. lewisi by PCR and nucleotide sequences. This dominant rodent pathogen can be transmitted to humans and cause disease. Our finding can provide reference for the prevention and control of outbreaks of the disease caused by T. lewisi.
Conflict of interest statement
We declare that we have no conflict of interest.
The authors would like to thank Mr. Payao Kanju for his help in animal trapping. We would like to thank Professor Jorge Aigla, M.D., visiting Professor at Naresuan University and Mr. Peter Barton, Division at International Affairs and Language Development for his assistance in editing this manuscript.
This study was granted by Naresuan University, Phitsanulok, Thailand (Grant No. R2559C136).
P.W.M. and S.S developed the theoretical formalism, performed the analytic calculations and performed the numerical simulations. P.W.M, S.S., and N.S. authors contributed to the final version of the manuscript. P.W.M supervised the project.
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