Molecular Differentiation of Schistosoma japonicum and Schistosoma mekongi by Real-Time PCR with High Resolution Melting Analysis

Article information

Korean J Parasito. 2013;51(6):651-656

Publication date (electronic) : 2013 December 31

doi : https://doi.org/10.3347/kjp.2013.51.6.651

¹Department of Parasitology, Faculty of Medicine, Khon Kaen University, Khon Kaen 40002, Thailand.

²Research and Diagnostic Center for Emerging Infectious Diseases, Faculty of Medicine, Khon Kaen University, Khon Kaen 40002, Thailand.

³Department of Biochemistry, Faculty of Medical Science, Naresuan University, Phitsanulok, 65000 Thailand.

⁴Faculty of Medicine, Mahasarakham University, Mahasarakham 44000, Thailand.

⁵Department of Microbiology, Faculty of Medicine, Khon Kaen University, Khon Kaen 40002, Thailand.

⁶Applied Malacology Center, Department of Social and Environmental Medicine, Faculty of Tropical Medicine, Mahidol University, Bangkok 10400, Thailand.

Corresponding author (wanch_ma@kku.ac.th)

Received 2013 May 30; Revised 2013 August 07; Accepted 2013 October 11.

Abstract

Human schistosomiasis caused by Schistosoma japonicum and Schistosoma mekongi is a chronic and debilitating helminthic disease still prevalent in several countries of Asia. Due to morphological similarities of cercariae and eggs of these 2 species, microscopic differentiation is difficult. High resolution melting (HRM) real-time PCR is developed as an alternative tool for the detection and differentiation of these 2 species. A primer pair was designed for targeting the 18S ribosomal RNA gene to generate PCR products of 156 base pairs for both species. The melting points of S. japonicum and S. mekongi PCR products were 84.5±0.07℃ and 85.7±0.07℃, respectively. The method permits amplification from a single cercaria or an egg. The HRM real-time PCR is a rapid and simple tool for differentiation of S. japonicum and S. mekongi in the intermediate and final hosts.

Keywords: Schistosoma japonicum; Schistosoma mekongi; differentiation; high resolution melting analysis; real-time PCR

INTRODUCTION

Schistosomiasis is a neglected tropical disease caused by blood flukes of the genus Schistosoma, which remains prevalent in several nations. About 200 million people are infected worldwide, and more than 600 million reside in endemic zones [1]. Although the most important causative species for human diseases are Schistosoma mansoni, Schistosoma haematobium, and Schistosoma japonicum, a further species, Schistosoma mekongi, found along the Mekong River in Cambodia and Lao People's Democratic Republic (Lao PDR), also infects humans. Mortality rates are high in all species infections [2]. Schistosomiasis japonica is widespread in China, Indonesia, and the Philippines [3]. Recent increases in the movements of foreign workers, migrants, and travelers have meant that infected individuals might seek medical help and diagnosis far from the endemic source of their infection [4-7].

Microscopic methods to detect Schistosoma eggs in stools of final hosts or cercariae shed from snail intermediate hosts are time-consuming. The stool examination has certain problems; it is difficult to differentiate between eggs of S. japonicum and S. mekongi, eggs cannot be detected during the pre-patent period, and it has low sensitivity in cases of light intensity of infection. Moreover, morphological identification of Schistosoma cercariae from snail intermediate hosts is also difficult.

There are several reports dealing with molecular-based methods for the diagnosis of schistosomiasis. Most have focused on finding parasite DNA in samples such as feces [8-10], sera [11,12], urine [13], and in intermediate snail hosts [14]. Identification and differentiation of major human schistosomes by real-time PCR has been reported for the detection of S. japonicum [15-19], S. mekongi [20], S. mansoni [21,22], and S. haematobium [22,23]. However, simultaneous differentiation and detection of S. japonicum and S. mekongi eggs or cercariae in a single real-time PCR assay has not been reported yet. Here, we report that the high resolution melting (HRM) real-time PCR can be a useful method for differential identification of S. japonicum and S. mekongi cercariae from infected snails, and also eggs in fecal samples from infected mice and rats.

MATERIALS AND METHODS

Parasites and DNA samples

S. japonicum (Japanese Yamanashi strain) cercariae were obtained from experimentally infected Oncomelania nosophora snails and adult worms from experimentally infected mice. Similarly, S. mekongi (Loatian strain) cercariae were obtained from experimentally infected Neotricula aperta (beta race) snails, and adult worms were from experimentally infected rats. All those infected snails were obtained from the Applied Malacology Center, Department of Social and Environmental Medicine, Faculty of Tropical Medicine, Mahidol University, Thailand. All animal experiments were approved by the Animal Ethics Committee of Khon Kaen University, based on the Ethics of Animal Experimentation of the National Research Council of Thailand (reference no. 0514.1.12.2/70).

DNAs extracted from individual S. japonicum and S. mekongi adults and from experimentally infected snails were prepared using the Nucleospin Tissue kit (Macherey-Nagel GmbH & Co, Duren, Germany). Copro-DNAs were extracted from 100 mg each of S. japonicum-infected mouse feces and S. mekongi-infected rat feces using the QIAamp® DNA stool mini kit (Qiagen, Hilden, Germany). DNA was eluted in 50 µl of distilled water, 5 µl of which was used for each HRM real-time PCR reaction. The DNA samples were kept at -70℃ until use.

The number of S. japonicum eggs in infected mice feces (n=9) was determined and expressed as eggs per gram (EPG) of feces (ranging from 100-1,100 EPG; geometric mean=367 EPG). Similarly, numbers of S. mekongi eggs in infected rats feces (n=12) were determined (ranging from 1,100-22,000 EPG; geometric mean=3,805 EPG).

Determination of analytical sensitivity and specificity

To determine analytical sensitivity, non-infected N. aperta or O. nosophora snails were crushed separately. Subsequently, individual aliquots of 1, 5 (pooled), and 10 (pooled) non-infected N. aperta and O. nosophora snail samples were each separately inoculated with 1, 5, and 10 S. mekongi and S. japonicum cercariae. To determine detection limits for fluke eggs in fecal samples, 1, 2, 4, or 8 S. mekongi eggs were added to 100 mg aliquots of non-infected rat feces. Likewise, to 100 mg aliquots of non-infected mouse feces were added 1, 2, 4, or 8 S. japonicum eggs. Genomic DNA was then extracted from these samples (see above) and used for PCRs.

For evaluation of specificity, genomic DNAs from parasites other than S. mekongi and S. japonicum were used, e.g., human hookworms, intestinal lecithodendriid flukes, Taenia spp., Trichuris trichiura, Trichostrongylus spp., Strongyloides stercoralis, Stellantchasmus spp., Paragonimus heterotremus, Opisthorchis viverrini, Haplorchoides spp., Haplorchis taichui, Isospora belli, Giardia duodenalis, Echinostoma malayanum, Capillaria philippinensis, Clonorchis sinensis, and Ascaris lumbricoides. DNAs extracted from human leukocytes, feces of non-infected mice or rats, and non-infected snails were also used as controls.

Primer design and positive control plasmids

The 18S ribosomal RNA sequence (18S rRNA) of S. japonicum (FJ176682) and S. mekongi (U89871) were selected and used to differentiate the 2 species. The PCR primers (Schis_F; 5'-GAC TTT CGG GTT GCC TGA TC -3' and Schis_R; -5'- ACC GGA TCG CTT CAA CAG T-3') were designed to amplify a particularly variable region [24]. For the positive controls, plasmids were constructed by ligation of amplified products from each species into pGEM-T easy vectors (Promega, Madison, Wisconsin, USA), according to the manufacturer's instructions. The PCR products were obtained by conventional PCR using the Schis_F and Schis_R primers and control plasmids as template. Each recombinant plasmid was produced in Escherichia coli JM109. Each inserted amplicon was sequenced in both directions to confirm its identity.

HRM real-time PCR assay

For differential detection, a LightCycler 480 High Resolution Melting Master Kit (Roche Applied Science, Mannheim, Germany) was used. The reaction mixture contained 1× LightCycler 480 HRM Master Mix, which comprises HRM dye (Roche Applied Science), 2.25 mM MgCl₂, and each of 0.4 µM Schis_F and Schis_R primers. The total reaction volume was 20 µl. The PCR cycling for HRM curve presentation was done under the following conditions: 1 hold at 95℃ for 10 min; 45 cycles of 95℃ for 10 sec, 55℃ for 8 sec, and 72℃ for 15 sec; then, the mixture was held at 95℃ for 10 sec and 60℃ for 30 sec. The reaction products were then melted by increasing the temperature from 60℃ to 95℃, with an increment of 0.11℃/sec, to obtain melting profiles. Amplified product was then cooled to 40℃ for 30 sec. All samples were examined in duplicate in 96-well plates.

To determine the analytical specificity of the HRM real-time PCR, DNAs extracted from specificity control samples (see above) were evaluated separately. Each run included one distilled water sample as a negative control and S. japonicum or S. mekongi plasmids in water (10⁷ copies) as positive controls.

The melting temperatures (Tm) of each PCR product was determined by melting curve analysis using LightCycler 480 gene scanning software (version 1.5) (Roche Applied Science). The cycle number (Cn), representing the target sequence copy number, was taken to be the number of PCR cycles needed for the change in fluorescence signal of the amplicons to exceed the detection threshold value. The sensitivity and specificity values were calculated and expressed using the method described previously [25].

RESULTS

Standardization of the HRM real-time PCR

The analytical sensitivity of HRM real-time PCR was determined using 10-fold serial dilutions (4.3×10⁷-4.3×10² copies) of the equal concentration mixture of S. japonicum and S. mekongi positive control plasmids in distilled water. The lowest detection was equal to or less than 4.3×10² copies of each positive control plasmid (Fig. 1) which is equivalent to 4×10^-7 ng of each genomic DNA of S. japonicum and S. mekongi, when considering 40 cycles as the cut-off detection limit. As little as a single S. japonicum or S. mekongi egg (Fig. 2) mixed artificially in 100 mg of uninfected mouse or rat feces could be clearly detected. Similarly, a single S. japonicum or S. mekongi cercaria inoculated into an aliquot derived from 10 pooled non-infected N. aperta or O. nosophora snail samples could be detected. No fluorescence signal was detected when evaluated with the defined DNA controls (1 µg) other than S. japonicum and S. mekongi (see Materials and Methods).

Fig. 1

(A) Representative melting peaks (℃) for Schistosoma japonicum (a), Schistosoma mekongi (b), mixed-plasmids (c), and distilled water (d). Amplification plot of fluorescence vs cycle number showing analytical sensitivity of HRM real-time PCR for detection of S. japonicum (B) and S. mekongi (C) plasmids: e-j; 10-fold serial dilutions of S. japonicum or S. mekongi plasmids, from 4.3×10⁷ to 4.3 ×10² copies per reaction. k; distilled water (negative control).

Fig. 2

Analytical sensitivity for detection of cercariae (A, B) and eggs (C, D) of S. japonicum (A, C) and S. mekongi (B, D). Cycle numbers for detection of 4 cercariae (l), 2 cercariae (m), 1 cercaria (n), and for detection of 8 eggs (p), 4 eggs (q), 2 eggs (r), and 1 egg (s). o and t; distilled water (negative control).

HRM real-time PCR for detection of S. japonicum and S. mekongi in fecal and snail samples

The HRM real-time PCR yielded positive results for all fecal samples from S. japonicum-infected mice and S. mekongi-infected rats (Table 1). Under the conditions described here, the HRM real-time PCR successfully amplified a predicted 156 bp product from the DNA of the S. japonicum and S. mekongi-infected fecal and snail samples (Fig. 3). The analytical sensitivity and specificity were both 100% for differential detection of S. japonicum and S. mekongi.

Table 1.

The cycle number and melting temperature values of HRM real-time PCR

Fig. 3

Ethidium bromide staining patterns of the PCR products on a 1.5% agarose gel. The arrows indicate the 156 bp of S. mekongi and S. japonicum specific bands. Lane M: DNA size markers (1 kb plus DNA ladder from Invitrogen, Carlsbad, California, USA). Negative control containing no DNA (Lane 1); S. mekongi positive control plasmid (Lane 2); S. japonicum positive control plasmid (Lane 3); S. mekongi-infected Neotricula aperta snails (Lane 4); non-infected N. aperta snails (Lane 5); S. japonicum-infected Oncomelania nosophora snails (Lane 6); non-infected O. nosophora snails (Lane 7); S. mekongi-infected rat feces (Lane 8); negative healthy human feces (Lane 9); and S. japonicum-infected mice feces (Lane 10).

To ensure the accuracy of the method, the amplified products from S. japonicum and S. mekongi-infected fecal and snail samples were sequenced in both directions. The results showed that all sequences were completely identical (data not shown) with the corresponding gene sequences from the relevant species.

DISCUSSION

Since Wittwer et al. [26] revealed that the HRM real-time PCR assay can identify sequence variants, the method has been applied for rapid detection and identification of Brugia malayi, Brugia pahangi, Dirofilaria immitis [27], and human hookworms [28]. This allows closed-tube, homogeneous genotyping without fluorescence-labeled probes, consequently decreasing the expense on a cost per-sample. Different sequences are represented by a change in the shape of the different melting curve plotted.

We have developed the HRM real-time PCR for differential detection of S. japonicum and S. mekongi in fecal samples of final hosts and in tissues of snail intermediate hosts. A single Schistosoma egg in a 100 mg fecal sample (equivalent to 10 EPG) or a single cercaria in tissues from 10 pooled snails can be detected. These detection are quite similar with single-species detection limits for S. japonicum [19] or S. mekongi [20] using a real-time PCR assay with fluorescence resonance energy transfer (FRET) hybridization probes. Similar levels of sensitivity have been found using SYBR green based real-time PCR; 10 EPG of S. japonicum in fecal samples could be reliably detected [15]. However, Zhou et al. [29] showed that the TaqMan real-time PCR assay can detect 1 S. japonicum egg in 500 mg fecal sample (equivalent to 2 EPG) [29].

For analytical specificity, DNA samples of the parasites other than the Schistosoma species tested did not give rise to an identifiable melting temperature peak, and the primers used did not amplify a 156 bp product, indicating 100% specificity.

As a result of the increase of outbound tourism from Asia and the increase of migrants within Asia due to One Asian Economic Community policy, there is an increasing potential for overlapping infections of the 2 Schistosoma species, S. japonicum and S. mekongi. In the laboratory setting, the assay system reported here gave high sensitivity and specificity and will be most valuable for diagnosis of infection by either species, or to demonstrate co-infection.

In conclusion, the method established in the present study has enabled rapid, sensitive, and specific differential identification of S. japonicum and S. mekongi cercariae in infected snails and eggs in fecal samples of infected mice and rats. Its cost-effectiveness is much better than other probe-based real-time PCR methods.

ACKNOWLEDGMENTS

This research was funded by grants from the National Science and Technology Development Agency (Discovery Based Development Grant); the Higher Education Research Promotion and National Research University Project of Thailand, Office of the Higher Education Commission through the Health Cluster (SHep-GMS), Thailand; the Faculty of Medicine, Khon Kaen University. Wanchai Maleewong was supported by TRF Senior Research Scholar Grant, Thailand Research Fund grant no. RTA5580004. We wish to acknowledge the support of the Khon Kaen University Publication Clinic, Research, and Technology Transfer Affairs, Khon Kaen University, for their assistance.

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	Cycle numbers			Melting temperatures
	Range	Mean ± SD	Median	Range	Mean ± SD	Median
S. japonicum-infected mice (n = 9)	15.8-29.7	22.0 ± 4.2	21.9	84.4-84.6	84.5 ± 0.07	84.5
S. mekongi-infected rats (n = 12)	19.5-29.2	23.5 ± 3.4	22.6	85.6-85.7	85.7 ± 0.04	85.7