Analysis of COI and ITS2 regions of DNA obtained from <i>Paragonimus westermani</i> eggs in ancient coprolites on Joseon dynasty mummies

Hong, Jong Ha; Oh, Chang Seok; Seo, Min; Shin, Dong Hoon

doi:10.1590/0074-02760180595

Abstract

The genetic information of ancient Paragonimus westermani, the oriental lung fluke infecting over 20 million people worldwide, has not been thoroughly investigated thus far. We analysed genetic markers (COI and ITS2) of P. westermani from coprolite specimens (n = 6) obtained from 15th to 18th century Korean mummies. Our results indicated that all P. westermani sequences were generally distinct from the other species of the genus Paragonimus. The sequences were clustered into three groups: Group I for East Asia; Group II for South and Southeast Asia; and Group III for India and Sri Lanka. In this study, we found that ancient P. westermani sequences in Korea belong to Group I, adding invaluable information to the existing knowledge of Paragonimus paleogenetics.

Key words:
ancient parasite; Paragonimus westermani; ancient DNA

Paragonimiasis occurs in definitive hosts after ingestion of infected intermediate hosts.¹1. Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12. In general, Paragonimus eggs hatch before entering snails (the first intermediate hosts). When the cercariae penetrate crustaceans such as crayfishes or crabs (the second intermediate hosts), they encyst in gills, muscles, and viscera, developing into metacercariae. After definitive hosts (e.g. humans) eat the freshwater crustaceans raw, the metacercariae excyst in the small intestine, penetrating the intestinal wall. They then traverse the diaphragm, entering the peribronchiolar tissues of the lung where they mature into adults within 8-12 weeks.²2. Bogitsh B, Carter CE, Oeltmann TN. Human parasitology. 3rd ed. Cambridge: Academic Press; 2005. p. 218-20.

The genus Paragonimus constitutes a species-rich group from the tropical regions in South and Southeast Asia, Africa, and Central and South America as well as the temperate zone of North America and East Asia.³3. Blair D, Xu ZB, Agatsuma T. Paragonimiasis and the genus Paragonimus. Adv Parasitol. 1999; 42: 113-222. Almost 50 nominal species and subspecies of Paragonimus have been reported so far;¹1. Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12. and approximately 16 species have been revealed to cause human diseases. Paragonimiasis mainly affects the lung. The adult worms stimulate the formation of worm capsules which then ulcerate, potentially leading to clinical symptoms such as cough, blood-tinged sputum, and pulmonary pain. Paragonimiasis could also be induced by the migration of young adult worms to the ectopic organs.²2. Bogitsh B, Carter CE, Oeltmann TN. Human parasitology. 3rd ed. Cambridge: Academic Press; 2005. p. 218-20.^,⁴4. Choi DW. Paragonimus and paragonimiasis in Korea. Korean J Parasitol. 1990; 28(Suppl.): 79-102.^,⁵5. Kim EA, Juhng SK, Kim HW, Kim GD, Lee YW, Cho HJ, et al. Imaging findings of hepatic paragonimiasis: a case report. J Korean Med Sci. 2004; 19(5): 759-62.^,⁶6. Koh EJ, Kim S-K, Wang K-C, Chai J-Y, Chong S, Park S-H, et al. The return of an old worm: cerebral paragonimiasis presenting with intracerebral hemorrhage. J Korean Med Sci. 2012; 27(11): 1428-32.^,⁷7. Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10. Among Paragonimus, the most common species is P. westermani, the oriental lung fluke mainly reported in Korea, China, Taiwan, Japan, and the Philippines.¹1. Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12.^,⁸8. Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.^,⁹9. Kerbert C. Zur Trematoden-Kenntnis. Zoolog Anz. 1878; 1: 271-3. Scholars have estimated that over 20 million people are currently infected with P. westermani worldwide.¹1. Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12.^,¹⁰10. Zarrin-Khameh N, Citron DR, Stager CE, Laucirica R. Pulmonary paragonimiasis diagnosed by fine-needle aspiration biopsy. J Clin Micobiol. 2008; 46(6): 2137-40.

Recently, researchers have attempted to reveal the genetic characteristics of P. westermani through DNA analysis.¹1. Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12.^,⁸8. Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.^,¹¹11. Binchai S, Rangsiruji A, Ketudat P, Morishima Y, Sugiyama H. Molecular systematics of a new form of Paragonimus westermani discovered in Thailand. Southeast Asian J Trop Med Public Health. 2007; 38: 92-6.^,¹²12. Doanh PN, Shinohara A, Horii Y, Habe S, Nawa Y. Discovery of Paragonimus westermani in Vietnam and its molecular phylogenetic status in P. westermani complex. Parasitol Res. 2009; 104(5): 1149-55.^,¹³13. Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45.^,¹⁴14. Prasad PK, Tandon V, Biswal DK, Goswami LM, Chatterjee A. Phylogenetic reconstruction using secondary structures and sequence motifs of ITS2 rDNA of Paragonimus westermani (Kerbert, 1878) Braun, 1899 (Digenea: Paragonimidae) and related species. BMC Genomics. 2009; 10(suppl. 3): S25.^,¹⁵15. Sugiyama H, Morishima Y, Binchai S, Rangsiruji A, Ketudat P. New form of Paragonimus westermani discovered in Thailand: morphological characteristics and host susceptibility. Southeast Asian J Trop Med Public Health. 2007; 38(Suppl. 1): 87-91. Phylogenetic analyses of cytochrome c oxidase subunit I (COI) and internal transcribed spacer 2 (ITS2) DNA regions have revealed that P. westermani are clustered into at least two groups (East Asia and South/Southeast Asia), in association with geographically distinct distributions.¹1. Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12.^,⁸8. Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.^,¹¹11. Binchai S, Rangsiruji A, Ketudat P, Morishima Y, Sugiyama H. Molecular systematics of a new form of Paragonimus westermani discovered in Thailand. Southeast Asian J Trop Med Public Health. 2007; 38: 92-6.^,¹²12. Doanh PN, Shinohara A, Horii Y, Habe S, Nawa Y. Discovery of Paragonimus westermani in Vietnam and its molecular phylogenetic status in P. westermani complex. Parasitol Res. 2009; 104(5): 1149-55.^,¹³13. Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45. However, although ancient eggs have been detected in archaeological samples, very few parasitological reports regarding paleogenetics of ancient Paragonimus spp. have been published so far. The only report was our previous study on ITS2 DNA sequence of ancient P. westermani eggs obtained from a 17th century Korean mummy.⁷7. Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10. In that study, the ancient DNA sequence of P. westermani was very similar to that of modern P. westermani reported in East Asia, but was genetically distinct from the P. westermani sequences of Southeast Asia.⁷7. Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10.

Nevertheless, our previous study was performed with only one sample and a single genetic marker (ITS2). Over the past several years, the genetic information of another P. westermani genetic marker (COI) has been continuously accumulated by multiple researchers.¹¹11. Binchai S, Rangsiruji A, Ketudat P, Morishima Y, Sugiyama H. Molecular systematics of a new form of Paragonimus westermani discovered in Thailand. Southeast Asian J Trop Med Public Health. 2007; 38: 92-6.^,¹²12. Doanh PN, Shinohara A, Horii Y, Habe S, Nawa Y. Discovery of Paragonimus westermani in Vietnam and its molecular phylogenetic status in P. westermani complex. Parasitol Res. 2009; 104(5): 1149-55.^,¹³13. Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45.^,¹⁶16. Devi KR, Narain K, Agatsuma T, Blair D, Nagataki M, Wickramasinghe S, et al. Morphological and molecular characterization of Paragonimus westermani in northeastern India. Acta Trop. 2010; 116(1): 31-8.^,¹⁷17. Iwagami M, Rajapakse RP, Paranagama W, Okada T, Kano S, Agatsuma T. Ancient divergence of Paragonimus westermani in Sri Lanka. Parasitol Res. 2008; 102(5): 845-52. Our paleoparasitological studies have also microscopically detected ancient Paragonimus eggs in many more coprolite specimens (n = 6) from the 15th to 18th century Korean mummies.¹⁸18. Seo M, Oh CS, Chai JY, Jeong MS, Hong SW, Seo YM, et al. The changing pattern of parasitic infection among Korean population by paleoparasitological study of Joseon dynasty mummies. J Parasitol. 2014; 100(1): 147-50.^,¹⁹19. Seo M, Oh CS, Hong JH, Chai J-Y, Cha SC, Bang Y, et al. Estimation of parasite infection prevalence of Joseon people by paleoparasitological data updates from the ancient feces of pre-modern Korean mummies. Anthropol Sci. 2017; 125(1): 9-14. In this regard, we attempted to examine multiple genetic markers (COI and ITS2) in newly collected ancient P. westermani eggs in order to obtain more comprehensive information about the evolutionary history of P. westermani.

The samples used in this study were acquired from the 15th to 18th century Joseon-era mummies (Cheongdo, Dangjin, Hwasung, YG2-4, YG2-6, and Yongin). The specimens were ancient faeces from the intestines of mummies (Cheongdo and Hwasung) or the organic materials compiled upon the hipbones of half-mummified bodies (Dangjin, YG2-4, YG2-6 and Yongin).

To authenticate our work on ancient DNA (aDNA), we followed the Criteria of Authentication established by Hofreiter et al.²⁰20. Hofreiter M, Serre D, Poinar HN, Kuch M, Pääbo S. Ancient DNA. Nat Rev Genet. 2001; 2(5): 353-9. During aDNA analysis, we wore head caps, masks, protection gloves, and gowns. All the tools used in this study were sterilized before use. We also used specialised facilities that were exclusively dedicated to aDNA analysis.²¹21. Ho SY, Gilbert MT. Ancient mitogenomics. Mitochondrion. 2010; 10(1): 1-11. We performed experiments in this facility that were developed in accordance with the Criteria.²⁰20. Hofreiter M, Serre D, Poinar HN, Kuch M, Pääbo S. Ancient DNA. Nat Rev Genet. 2001; 2(5): 353-9. The Institutional Review Board (IRB) of Seoul National University Hospital confirmed that our aDNA analyses could be exempt from board review (IRB No. 2017-001). We also followed the Vermillion Accord on Human Remains adopted by the World Archaeological Congress.²²22. Fforde C. Vermilion accord on human remains (1989) (indigenous archaeology). In: Smith C, editor. Encyclopedia of global archaeology. New York: Springer; 2014.

For DNA extraction, we followed the method described in our previous report.²³23. Kim Y-S, Oh CS, Lee SJ, Park JB, Kim MJ, Shin DH. Sex determination of Joseon skeletons based on anatomical, cultural and molecular biological clues. Ann Anat. 2011; 193(6): 539-43. In brief, the samples (0.3 g each) were incubated at 56ºC in 1 mL of lysis buffer (pH 8.0; including 1 % SDS; 0.1M DTT; 50 mM of EDTA; 1 mg/mL of proteinase K) for 24 h. After DNA was extracted with an equal volume of phenol/chloroform/isoamyl alcohol (25:24:1), it was then treated with chloroform/isoamyl alcohol (24:1). DNA isolation and purification were performed using a QIAmp PCR purification kit (Qiagen, Hilden, Germany). The purified DNA was eluted in 40 μl of EB elution buffer (Qiagen, Hilden, Germany). Primers for the P. westermani COI and ITS2 regions were generated by Integrated DNA Technologies, Inc. (Iowa City, IA, USA). The information of the primers used in our study is summarised in Table I.

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TABLE I
List of primers used for amplification of Paragonimus westermani DNA in this study

DNA quantification was performed using a NanoDrop^TM ND-1000 Spectrophotometer (Thermo Fisher Scientific, MA, USA). Extracted DNA (10 μL) was treated at 37ºC with 1 unit of uracil-DNA-glycosylase (New England Biolabs, MA, USA) for 30 min. It (40 ng) was then mixed with the reagent premix containing 10 pmol of each primer and 1X AmpliTaq Gold® 360 Master Mix (Life Technologies, CA, USA). PCR conditions were as follows: pre-denaturation at 95ºC for 10 min, 45 cycles of denaturation at 95ºC for 30 s, annealing at 54-60ºC for 30 s, extension at 72ºC for 30 s, and final extension at 72ºC for 10 min. The polymerase chain reaction (PCR) products were separated on 2.5% agarose gel (Invitrogen, CA, USA), and then stained with ethidium bromide. Negative controls (extraction controls) were also applied to the electrophoresis at the same time. Electrophoresis results were photographed using a Vilber Lourmat ETX-20.M equipped with Biocapt software (Vilber Lourmat, Collégien, France).

The PCR amplicons were isolated using a QIAquick Gel Extraction Kit (Qiagen, Hilden, Germany). The bacteria were transformed using the pGEM-T Easy Vector system (Promega Corporation, Madison, USA). Transformed bacteria were grown on an agar plate containing X-GAL (40 μg/μL), ampicillin (50 μg/mL), and 0.5 mM IPTG for the 14 h. After selected colonies were grown in LB media for 12 h, the purification of cultured bacteria was performed using a QIAprep® Spin Miniprep kit (Qiagen, Hilden, Germany).

Each amplified strand was sequenced using an ABI Prism BigDye Terminator v3.1 Cycle Sequencing Ready Reaction Kit (Applied Biosystems, Waltham, USA) and the 3730xl Automatic Sequencer (Applied Biosystems, Waltham, USA). The obtained DNA sequences were aligned by MEGA7 program.²⁴24. Kumar S, Stecher G, Tamura K. MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for bigger datasets. Mol Biol Evol. 2016; 33(7): 1870-4. The consensus sequences were compared to those available in GenBank using NCBI/BLAST tools.²⁵25. Altschul SF, Madden TL, Schäffer AA, Zhang J, Zhang Z, Miller W, et al. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 1997; 25(17): 3389-402. The web browser module and Alignment Explorer of MEGA7 were used to retrieve sequences homologous to those of interest from NCBI GenBank database.

The evolutionary relationship of P. westermani and other taxa from NCBI GenBank was inferred from the Phylogeny Reconstruction analysis implemented in MEGA7.²⁴24. Kumar S, Stecher G, Tamura K. MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for bigger datasets. Mol Biol Evol. 2016; 33(7): 1870-4. We used the Maximum Likelihood (ML) method. Selected parameters of our method followed the Tamura-Nei model²⁶26. Tamura K. Estimation of the number of nucleotide substitutions when there are strong transition-transversion and G + C-content biases. Mol Biol Evol. 1992; 9(4): 678-87. for COI or the Kimura 2-parameter model²⁷27. Kimura M. A simple method for estimating evolutionary rate of base substitutions through comparative studies of nucleotide sequences. J Mol Evol. 1980; 16(2): 111-20. for ITS2; we selected Complete Deletion for Gaps/Missing data treatment, Uniform Rates for Rates among Sites, and Nearest-Neighbor-Interchange (NNI) for the ML Heuristic Method. To estimate the reliability of the tree, we performed a bootstrap test.²⁸28. Hall BG. Building phylogenetic trees from molecular data with MEGA. Mol Biol Evol. 2013; 30(5): 1229-35. The number of bootstrap replicates was 1000.

To select the specimens used for this experiment, we screened all the mummy coprolite samples using PCR with P. westermani-specific primers (COI1 and ITS2-1 in Table I). In agarose gel electrophoresis, the amplified products specific for P. westermani primer sets COI1 (106 bp) and ITS2-1 (133 bp) were detected in only two samples (Cheongdo and YG2-4) while negative controls (extraction controls) did not exhibit any amplified bands (Fig. 1). Thus, we used Cheongdo and YG2-4 mummy specimens for subsequent experiments.

Fig. 1:
agarose gel electrophoresis for the polymerase chain reaction (PCR) amplicons of Paragonimus westermani aDNA from Cheongdo and YG2-4 mummies. Note specific amplicons 1 (106 bp), 2 (150 bp), 3 (136 bp), 4 (114 bp), and 5 (183 bp) of the COI region and 1 (133 bp), 2 (169 bp), 3 (129 bp), 4 (165 bp), and 5 (170 bp) of ITS2 region.

To obtain the consensus sequences of COI and ITS2 regions, we repeated cloning and sequencing for each specific amplicon. From these trials, 9-12 clone sequences were successfully acquired for the COI (390 bp) and ITS2 (417 bp) regions. Next, multiple sequence alignment was performed using Clustal W implemented in MEGA7. We then obtained consensus sequences after alignment of the cloned sequences [Supplementary data (Fig. 1)]. The consensus sequences of the P. westermani COI and ITS2 regions from the Cheongdo and YG2-4 mummies were identical [Supplementary data (Fig. 2)].

Using NCBI/BLAST tools, we compared the consensus sequences with those available in GenBank [Supplementary data (Fig. 2)]. The BLAST results are summarised in Table II. Briefly, the current P. westermani COI sequences obtained from Joseon mummies exhibited significant similarities to the P. westermani COI sequences reported in Korea (AF333280.1; AF540958.1), Japan (U97205.1; U97208.1), China (AY140680.1; U97209.1), Vietnam (FJ434988.1), India (JN656169.1; KM280646.1), the Philippines (U97213.1), Thailand (AB354224.1), and Sri Lanka (AY240940.1). We also found moderate similarities to the GenBank sequences of P. siamensis (AB354231.1), P. paishuihoensis (AB679289.1), and P. mexicanus (KC562301.1) [Supplementary data (Fig. 2A); Table II].

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TABLE II
BLAST searching results for the coverage and percent identity of each taxon comparing to the consensus sequence of Paragonimus westermani COI and ITS2 from Korean mummies. GenBank accession numbers and geographical information are also indicated

In the case of the ITS2 region, the current Joseon P. westermani sequences exhibit similarities to P. westermani ITS2 sequences found in Korea (AF333277.1), Japan (U96907.1), China (KC417492.1; AB713404.1), India (AB938198.1; JN656208.1; DQ836243.1), Taiwan (U96908.1), Vietnam (LC144902.1; FJ434982.1), Malaysia (U96909.1), Thailand (AB354217.1; AF159604.1), and Sri Lanka (AY240942.1). Similar sequences were also found in the sequences of P. siamensis (AB354222.1), Euparagonimus cenocopiosus (AF159601.1), and P. skrjabini (AB703444.1). The P. westermani ITS2 sequence obtained from a Korean mummy reported in our previous study (Shin et al.⁷7. Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10. JF500452.1) also demonstrated 100% identity (coverage 87%) [Supplementary data (Fig. 2B); Table II].

Next, we performed phylogenetic analysis of P. westermani COI and ITS2 regions (Fig. 2). Every P. westermani taxon in the COI and ITS2 regions was clearly distinct from other Paragonimus species (P. siamensis, P. skrjabini, P. paishuihoensis and P. mexicanus). P. westermani sequences were clustered into several groups. In the case of the COI region, Group I included P. westermani sequences from East Asia (Korea, Japan, and China) whereas Group II included those from South and Southeast Asia (India, Philippines, and Thailand) and formed another cluster. We note that some sequences reported from India and Sri Lanka formed a separate cluster of the third separate group (Group III) (Fig. 2A). P. westermani COI sequences obtained from Korean mummies in this study evidently belong to the East Asia group. Our result was similar to those of the phylogenetic analyses conducted by Iwagami et al.¹³13. Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45.^,¹⁷17. Iwagami M, Rajapakse RP, Paranagama W, Okada T, Kano S, Agatsuma T. Ancient divergence of Paragonimus westermani in Sri Lanka. Parasitol Res. 2008; 102(5): 845-52. and Devi et al.,⁸8. Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.^,¹⁶16. Devi KR, Narain K, Agatsuma T, Blair D, Nagataki M, Wickramasinghe S, et al. Morphological and molecular characterization of Paragonimus westermani in northeastern India. Acta Trop. 2010; 116(1): 31-8. which yielded that the P. westermani COI region was clustered into East, Southeast, and South Asia groups (Fig. 2A).

Fig. 2:
maximum likelihood tree of Paragonimus (A) COI and (B) ITS2 DNA region. The percentage of replicate trees in which the associated taxa clustered in the bootstrap test are marked next to the branches. The ancient P. westermani sequences revealed in this study are represented by red dots.

Like the COI region, P. westermani ITS2 sequences reported from East Asia (Korea, Japan, and China; Group I), Southeast Asia (Thailand; Group II), and South Asia (India; Group III) were also separately clustered in the phylogenetic analysis (Fig. 2B). The P. westermani ITS2 sequences from Cheongdo and YG2-4 Korean mummies in our study belonged to the East Asia group as well. Taken together, our phylogenetic tree of the ITS2 region was generally similar to those reported in previous studies conducted by Iwagami et al.¹³13. Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45.^,¹⁷17. Iwagami M, Rajapakse RP, Paranagama W, Okada T, Kano S, Agatsuma T. Ancient divergence of Paragonimus westermani in Sri Lanka. Parasitol Res. 2008; 102(5): 845-52. and Devi et al.⁸8. Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.^,¹⁶16. Devi KR, Narain K, Agatsuma T, Blair D, Nagataki M, Wickramasinghe S, et al. Morphological and molecular characterization of Paragonimus westermani in northeastern India. Acta Trop. 2010; 116(1): 31-8. However, different from the COI region, there was also a unique finding of our examination of the ITS2 region of P. westermani. In brief, some P. westermani ITS2 sequences from South Asia (India: AB938198.1, JN656208.1, JN656205.1) and Southeast Asia (Vietnam: LC144902.1, FJ434982.1) were clustered with those of the East Asia group in this study (Fig. 2B). Similar findings have rarely been reported except for the research conducted by Doanh et al.¹²12. Doanh PN, Shinohara A, Horii Y, Habe S, Nawa Y. Discovery of Paragonimus westermani in Vietnam and its molecular phylogenetic status in P. westermani complex. Parasitol Res. 2009; 104(5): 1149-55.

According to the paleoparasitological estimation, the prevalence of P. westermani infection in the Joseon society might reach as high as 33.3%.¹⁸18. Seo M, Oh CS, Chai JY, Jeong MS, Hong SW, Seo YM, et al. The changing pattern of parasitic infection among Korean population by paleoparasitological study of Joseon dynasty mummies. J Parasitol. 2014; 100(1): 147-50.^,¹⁹19. Seo M, Oh CS, Hong JH, Chai J-Y, Cha SC, Bang Y, et al. Estimation of parasite infection prevalence of Joseon people by paleoparasitological data updates from the ancient feces of pre-modern Korean mummies. Anthropol Sci. 2017; 125(1): 9-14. Since Joseon people commonly enjoyed raw crayfish or raw crab dishes,⁷7. Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10.^,²⁹29. Sohn BS, Bae YJ, Cho YS, Moon HB, Kim TB. Three cases of paragonimiasis in a family. Korean J Parasitol. 2009; 47(3): 281-5.^,³⁰30. Yun DJ. Paragonimiasis in children in Korea: related to the custom of ingesting raw crayfish for the treatment of measles. J Pediatr. 1960; 56(6): 736-51. it is understandable that they were heavily infected by P. westermani. In this study, using coprolite samples obtained from Joseon dynasty mummies, we successfully analysed the COI and ITS2 regions of aDNA from P. westermani. As very few studies have examined ancient P. westermani DNA so far,⁷7. Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10. the current study significantly expands the existing gene pool of P. westermani paleogenetics. Nevertheless, we admit that aDNA reports of much wider geo-historical scope are still required to improve our knowledge about the exact evolutionary history of P. westermani.

REFERENCES

¹
Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12.
²
Bogitsh B, Carter CE, Oeltmann TN. Human parasitology. 3rd ed. Cambridge: Academic Press; 2005. p. 218-20.
³
Blair D, Xu ZB, Agatsuma T. Paragonimiasis and the genus Paragonimus. Adv Parasitol. 1999; 42: 113-222.
⁴
Choi DW. Paragonimus and paragonimiasis in Korea. Korean J Parasitol. 1990; 28(Suppl.): 79-102.
⁵
Kim EA, Juhng SK, Kim HW, Kim GD, Lee YW, Cho HJ, et al. Imaging findings of hepatic paragonimiasis: a case report. J Korean Med Sci. 2004; 19(5): 759-62.
⁶
Koh EJ, Kim S-K, Wang K-C, Chai J-Y, Chong S, Park S-H, et al. The return of an old worm: cerebral paragonimiasis presenting with intracerebral hemorrhage. J Korean Med Sci. 2012; 27(11): 1428-32.
⁷
Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10.
⁸
Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.
⁹
Kerbert C. Zur Trematoden-Kenntnis. Zoolog Anz. 1878; 1: 271-3.
¹⁰
Zarrin-Khameh N, Citron DR, Stager CE, Laucirica R. Pulmonary paragonimiasis diagnosed by fine-needle aspiration biopsy. J Clin Micobiol. 2008; 46(6): 2137-40.
¹¹
Binchai S, Rangsiruji A, Ketudat P, Morishima Y, Sugiyama H. Molecular systematics of a new form of Paragonimus westermani discovered in Thailand. Southeast Asian J Trop Med Public Health. 2007; 38: 92-6.
¹²
Doanh PN, Shinohara A, Horii Y, Habe S, Nawa Y. Discovery of Paragonimus westermani in Vietnam and its molecular phylogenetic status in P. westermani complex. Parasitol Res. 2009; 104(5): 1149-55.
¹³
Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45.
¹⁴
Prasad PK, Tandon V, Biswal DK, Goswami LM, Chatterjee A. Phylogenetic reconstruction using secondary structures and sequence motifs of ITS2 rDNA of Paragonimus westermani (Kerbert, 1878) Braun, 1899 (Digenea: Paragonimidae) and related species. BMC Genomics. 2009; 10(suppl. 3): S25.
¹⁵
Sugiyama H, Morishima Y, Binchai S, Rangsiruji A, Ketudat P. New form of Paragonimus westermani discovered in Thailand: morphological characteristics and host susceptibility. Southeast Asian J Trop Med Public Health. 2007; 38(Suppl. 1): 87-91.
¹⁶
Devi KR, Narain K, Agatsuma T, Blair D, Nagataki M, Wickramasinghe S, et al. Morphological and molecular characterization of Paragonimus westermani in northeastern India. Acta Trop. 2010; 116(1): 31-8.
¹⁷
Iwagami M, Rajapakse RP, Paranagama W, Okada T, Kano S, Agatsuma T. Ancient divergence of Paragonimus westermani in Sri Lanka. Parasitol Res. 2008; 102(5): 845-52.
¹⁸
Seo M, Oh CS, Chai JY, Jeong MS, Hong SW, Seo YM, et al. The changing pattern of parasitic infection among Korean population by paleoparasitological study of Joseon dynasty mummies. J Parasitol. 2014; 100(1): 147-50.
¹⁹
Seo M, Oh CS, Hong JH, Chai J-Y, Cha SC, Bang Y, et al. Estimation of parasite infection prevalence of Joseon people by paleoparasitological data updates from the ancient feces of pre-modern Korean mummies. Anthropol Sci. 2017; 125(1): 9-14.
²⁰
Hofreiter M, Serre D, Poinar HN, Kuch M, Pääbo S. Ancient DNA. Nat Rev Genet. 2001; 2(5): 353-9.
²¹
Ho SY, Gilbert MT. Ancient mitogenomics. Mitochondrion. 2010; 10(1): 1-11.
²²
Fforde C. Vermilion accord on human remains (1989) (indigenous archaeology). In: Smith C, editor. Encyclopedia of global archaeology. New York: Springer; 2014.
²³
Kim Y-S, Oh CS, Lee SJ, Park JB, Kim MJ, Shin DH. Sex determination of Joseon skeletons based on anatomical, cultural and molecular biological clues. Ann Anat. 2011; 193(6): 539-43.
²⁴
Kumar S, Stecher G, Tamura K. MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for bigger datasets. Mol Biol Evol. 2016; 33(7): 1870-4.
²⁵
Altschul SF, Madden TL, Schäffer AA, Zhang J, Zhang Z, Miller W, et al. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 1997; 25(17): 3389-402.
²⁶
Tamura K. Estimation of the number of nucleotide substitutions when there are strong transition-transversion and G + C-content biases. Mol Biol Evol. 1992; 9(4): 678-87.
²⁷
Kimura M. A simple method for estimating evolutionary rate of base substitutions through comparative studies of nucleotide sequences. J Mol Evol. 1980; 16(2): 111-20.
²⁸
Hall BG. Building phylogenetic trees from molecular data with MEGA. Mol Biol Evol. 2013; 30(5): 1229-35.
²⁹
Sohn BS, Bae YJ, Cho YS, Moon HB, Kim TB. Three cases of paragonimiasis in a family. Korean J Parasitol. 2009; 47(3): 281-5.
³⁰
Yun DJ. Paragonimiasis in children in Korea: related to the custom of ingesting raw crayfish for the treatment of measles. J Pediatr. 1960; 56(6): 736-51.

Financial support: National Research Foundation of Korea (NRF) — Grant funded by the Korean government (MSIP) (no. NRF-2016R1A2B4015669).

Publication Dates

Publication in this collection
16 May 2019
Date of issue
2019

History

Received
18 Dec 2018
Accepted
04 Apr 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Blair D, Nawa Y, Mitreva M, Doanh PN. Genetic diversity and genetic variation in lung flukes (genus Paragonimus). Trans R Soc Trop Med Hyg. 2016; 110(1): 6-12.

[2] ²
Bogitsh B, Carter CE, Oeltmann TN. Human parasitology. 3rd ed. Cambridge: Academic Press; 2005. p. 218-20.

[3] ³
Blair D, Xu ZB, Agatsuma T. Paragonimiasis and the genus Paragonimus. Adv Parasitol. 1999; 42: 113-222.

[4] ⁴
Choi DW. Paragonimus and paragonimiasis in Korea. Korean J Parasitol. 1990; 28(Suppl.): 79-102.

[5] ⁵
Kim EA, Juhng SK, Kim HW, Kim GD, Lee YW, Cho HJ, et al. Imaging findings of hepatic paragonimiasis: a case report. J Korean Med Sci. 2004; 19(5): 759-62.

[6] ⁶
Koh EJ, Kim S-K, Wang K-C, Chai J-Y, Chong S, Park S-H, et al. The return of an old worm: cerebral paragonimiasis presenting with intracerebral hemorrhage. J Korean Med Sci. 2012; 27(11): 1428-32.

[7] ⁷
Shin DH, Oh CS, Lee SJ, Lee E-J, Yim SG, Kim MJ, et al. Ectopic paragonimiasis from 400-year-old female mummy of Korea. J Archaeol Sci. 2012; 39(4): 1103-10.

[8] ⁸
Devi KR, Narain K, Mahanta J, Nirmolia T, Blair D, Saikia SP, et al. Presence of three distinct genotypes within the Paragonimus westermani complex in northeastern India. Parasitol. 2013; 140(1): 76-86.

[9] ⁹
Kerbert C. Zur Trematoden-Kenntnis. Zoolog Anz. 1878; 1: 271-3.

[10] ¹⁰
Zarrin-Khameh N, Citron DR, Stager CE, Laucirica R. Pulmonary paragonimiasis diagnosed by fine-needle aspiration biopsy. J Clin Micobiol. 2008; 46(6): 2137-40.

[11] ¹¹
Binchai S, Rangsiruji A, Ketudat P, Morishima Y, Sugiyama H. Molecular systematics of a new form of Paragonimus westermani discovered in Thailand. Southeast Asian J Trop Med Public Health. 2007; 38: 92-6.

[12] ¹²
Doanh PN, Shinohara A, Horii Y, Habe S, Nawa Y. Discovery of Paragonimus westermani in Vietnam and its molecular phylogenetic status in P. westermani complex. Parasitol Res. 2009; 104(5): 1149-55.

[13] ¹³
Iwagami M, Rajapakse RPVJ, Paranagama W, Agatsuma T. Identities of two Paragonimus species from Sri Lanka inferred from molecular sequences. J Helminthol. 2003; 77(3): 239-45.

[14] ¹⁴
Prasad PK, Tandon V, Biswal DK, Goswami LM, Chatterjee A. Phylogenetic reconstruction using secondary structures and sequence motifs of ITS2 rDNA of Paragonimus westermani (Kerbert, 1878) Braun, 1899 (Digenea: Paragonimidae) and related species. BMC Genomics. 2009; 10(suppl. 3): S25.

[15] ¹⁵
Sugiyama H, Morishima Y, Binchai S, Rangsiruji A, Ketudat P. New form of Paragonimus westermani discovered in Thailand: morphological characteristics and host susceptibility. Southeast Asian J Trop Med Public Health. 2007; 38(Suppl. 1): 87-91.

[16] ¹⁶
Devi KR, Narain K, Agatsuma T, Blair D, Nagataki M, Wickramasinghe S, et al. Morphological and molecular characterization of Paragonimus westermani in northeastern India. Acta Trop. 2010; 116(1): 31-8.

[17] ¹⁷
Iwagami M, Rajapakse RP, Paranagama W, Okada T, Kano S, Agatsuma T. Ancient divergence of Paragonimus westermani in Sri Lanka. Parasitol Res. 2008; 102(5): 845-52.

[18] ¹⁸
Seo M, Oh CS, Chai JY, Jeong MS, Hong SW, Seo YM, et al. The changing pattern of parasitic infection among Korean population by paleoparasitological study of Joseon dynasty mummies. J Parasitol. 2014; 100(1): 147-50.

[19] ¹⁹
Seo M, Oh CS, Hong JH, Chai J-Y, Cha SC, Bang Y, et al. Estimation of parasite infection prevalence of Joseon people by paleoparasitological data updates from the ancient feces of pre-modern Korean mummies. Anthropol Sci. 2017; 125(1): 9-14.

[20] ²⁰
Hofreiter M, Serre D, Poinar HN, Kuch M, Pääbo S. Ancient DNA. Nat Rev Genet. 2001; 2(5): 353-9.

[21] ²¹
Ho SY, Gilbert MT. Ancient mitogenomics. Mitochondrion. 2010; 10(1): 1-11.

[22] ²²
Fforde C. Vermilion accord on human remains (1989) (indigenous archaeology). In: Smith C, editor. Encyclopedia of global archaeology. New York: Springer; 2014.

[23] ²³
Kim Y-S, Oh CS, Lee SJ, Park JB, Kim MJ, Shin DH. Sex determination of Joseon skeletons based on anatomical, cultural and molecular biological clues. Ann Anat. 2011; 193(6): 539-43.

[24] ²⁴
Kumar S, Stecher G, Tamura K. MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for bigger datasets. Mol Biol Evol. 2016; 33(7): 1870-4.

[25] ²⁵
Altschul SF, Madden TL, Schäffer AA, Zhang J, Zhang Z, Miller W, et al. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 1997; 25(17): 3389-402.

[26] ²⁶
Tamura K. Estimation of the number of nucleotide substitutions when there are strong transition-transversion and G + C-content biases. Mol Biol Evol. 1992; 9(4): 678-87.

[27] ²⁷
Kimura M. A simple method for estimating evolutionary rate of base substitutions through comparative studies of nucleotide sequences. J Mol Evol. 1980; 16(2): 111-20.

[28] ²⁸
Hall BG. Building phylogenetic trees from molecular data with MEGA. Mol Biol Evol. 2013; 30(5): 1229-35.

[29] ²⁹
Sohn BS, Bae YJ, Cho YS, Moon HB, Kim TB. Three cases of paragonimiasis in a family. Korean J Parasitol. 2009; 47(3): 281-5.

[30] ³⁰
Yun DJ. Paragonimiasis in children in Korea: related to the custom of ingesting raw crayfish for the treatment of measles. J Pediatr. 1960; 56(6): 736-51.

Region	Set	Primer	5’ to 3’	Annealing temp. (ºC)	Length (bp)
COI	COI1	COI-1F	GGG CAT CCG GAG GTG TAT GT	54	106
		COI-1R	TTC GGG TAC TAC GGG CTG G
	COI2	COI-2F	CTG ACC AAC AAC GAT TCC T	54	150
		COI-2R	TCC CGT GAC AGA ACT AAA GA
	COI3	COI-3F	GTC TGG GTA GTG TTG TGT GG	54	136
		COI-3R	AGC ATG AAC AAC CAA GAG AA
	COI4	COI-4F	TTA GTT CTG TCA CGG GAG TG	57	114
		COI-4R	GAA TTC ACC ACA AAA CAG GA
	COI5	COI-5F	TTC TCT TGG TTG TTC ATG CT	54	183
		COI-5R	GAC GTA ATG AAA ATG AGC C
ITS2	ITS2-1	ITS2-1F	GCG CAG CCA ACT GTG TGA A	57	133
		ITS2-1R	GGC GTC GCG ATA GTT TAT
	ITS2-2	ITS2-2F	TTA ATG CGA ACT GCA TAC TG	54	169
		ITS2-2R	AAG ACC AGA TTG GGG AGA T
	ITS2-3	ITS2-3F	GGT CGG CTT ATA AAC TAT CG	54	129
		ITS2-3R	CCC GAG TAT GTT AGG GAA A
	ITS2-4	ITS2-4F	AAT CTG GTC TTG TGC CTG T	60	165
		ITS2-4R	AAA CCA CAG ATG AAG ACA GG
	ITS2-5	ITS2-5F	GTG GCT CAG TGA ATG ATT TAT	54	170
		ITS2-5R	CCG CTT AGT GAT ATG CTT A

Brasil

Brasil

Analysis of COI and ITS2 regions of DNA obtained from Paragonimus westermani eggs in ancient coprolites on Joseon dynasty mummies

Abstract

REFERENCES

Publication Dates

History

DNA region	Species	Coverage	Percent identity	Accession number	Geographical region
COI	P. westermani	100%	100%	U97205.1	Japan
		100%	99%	AF333280.1	South Korea
		100%	99%	AF540958.1	South Korea
		100%	99%	U97208.1	Japan
		98%	99%	AY140680.1	China
		100%	98%	U97209.1	China
		99%	96%	FJ434988.1	Vietnam
		100%	93%	JN656169.1	India
		99%	86%	KM280646.1	India
		99%	90%	U97213.1	The Philippines
		99%	89%	AB354224.1	Thailand
		92%	84%	AY240940.1	Sri Lanka
	P. siamensis	99%	95%	AB354231.1	Thailand
	P. paishuihoensis	99%	84%	AB679289.1	Laos
ITS2	P. westermani	100%	100%	KC417492.1	China
		100%	100%	AB713404.1	China
		100%	100%	AB938198.1	India
		100%	99%	AF333277.1	South Korea
		100%	99%	JN656205.1	India
		100%	99%	JN656208.1	India
		100%	99%	U96908.1	Taiwan
		100%	99%	LC144902.1	Vietnam
		100%	99%	AB354217.1	Thailand
		100%	98%	DQ836243.1	India
		100%	98%	JN656199.1	India
		100%	97%	DQ351845.1	India
		100%	97%	AB354214.1	Thailand
		97%	99%	FJ434982.1	Vietnam
		87%	100%	JF500452.1	Ancient South Korea
		87%	100%	U96907.1	Japan
		87%	98%	U96909.1	Malaysia
		87%	97%	AF159604.1	Thailand
		68%	95%	AY240942.1	Sri Lanka
	P. siamensis	100%	96%	AB354222.1	Thailand
	Euparagonimus cenocopiosus	87%	93%	AF159601.1	China