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Korean J Parasitol > Volume 55(3):2017 > Article
Yang, Zhao, Zhang, and Liu: Prevalence of Hymenolepis nana and H. diminuta from Brown Rats (Rattus norvegicus) in Heilongjiang Province, China

Abstract

Hymenolepis nana and Hymenolepis diminuta are globally widespread zoonotic cestodes. Rodents are the main reservoir host of these cestodes. Brown rats (Rattus norvegicus) are the best known and most common rats, and usually live wherever humans live, especially in less than desirable hygiene conditions. Due to the little information of the 2 hymenolepidid species in brown rats in China, the aim of this study was to understand the prevalence and genetic characterization of H. nana and H. diminuta in brown rats in Heilongjiang Province, China. Total 114 fecal samples were collected from brown rats in Heilongjiang Province. All the samples were subjected to morphological examinations by microscopy and genetic analysis by PCR amplification of the mitochondrial cytochrome c oxidase subunit 1 (COX1) gene and the internal transcribed spacer 2 (ITS2) region of the nuclear ribosomal RNA gene. In total, 6.1% (7/114) and 14.9% (17/114) of samples were positive for H. nana and H. diminuta, respectively. Among them, 7 and 3 H. nana isolates were successfully amplified and sequenced at the COX1 and ITS2 loci, respectively. No nucleotide variations were found among H. nana isolates at either of the 2 loci. Seventeen H. diminuta isolates produced 2 different COX1 sequences while 7 ITS2 sequences obtained were identical to each other. The present results of H. nana and H. diminuta infections in brown rats implied the risk of zoonotic transmission of hymenolepiasis in China. These molecular data will be helpful to deeply study intra-specific variations within Hymenolepis cestodes in the future.

Hymenolepiasis is a neglected zoonotic disease in humans, caused by cestodes Hymenolepis nana (dwarf tapeworm) and H. diminuta (rat tapeworm) [1]. H. nana and H. diminuta are globally widespread, but endemic to Asia, Southern and Eastern Europe, Central and South America, and Africa [2]. Epidemiological data have revealed that H. nana is more commonly reported as the cause of human hymenolepiasis than H. diminuta. More than 175 million cases of hymenolepiasis caused by H. nana have been reported in humans worldwide [3]. In contrast, only a few hundred people have been described to be infected with H. diminuta [4]. Generally, human cases of hymenolepiasis mostly appear asymptomatic; however, humans infected with these parasites are sometimes responsible for mild clinical symptoms, mainly including diarrhea, abdominal pain, anorexia, and vague gastrointestinal manifestations [5,6]. Most seriously, infection of H. nana and H. diminuta ultimately can cause severe diseases, even life threatening conditions in immunosuppressed individuals with HIV [7,8].
Rodents are highly successful in adapting to a variety of environments throughout the world, which makes them extremely abundant. They are known as reservoirs or carriers of zoonotic bacteria, virus, and parasites, endangering public health by spreading various diseases via food or water destruction and contamination. Among them, brown rats (Rattus norvegicus) are the best known and most common, and usually live wherever humans live, especially in less than desirable hygiene conditions.
H. nana and H. diminuta have been detected in brown rats in many countries and areas. H. nana has been found in the Netherlands; 3.3% (1/30) in farms and 4.1% (2/49) in rural environments in 2016 [9]; 8.8% (10/112) in Brazil in 2016 [10]; 21.8% (7/32) in Taiwan in 2013 [11], and 100% (10/10) in Italy in 2015 [12]. H. diminuta has been found in the Netherlands; 50% (15/30) in farms, 10.2% (5/49) in rural environments, and 10.5% (4/38) in suburban environments in 2016 [9]; 6.3% (2/32) in Taiwan in 2013 [11]; 30.5% (92/302) in Serbia in 2011 [13], and 62.5% (5/8) in India in 2009 [14]. In China, to date, only 2 studies reported hymenolepiasis in brown rats: 3.3% (5/151) for H. nana and 27.8% (42/151) for H. diminuta in Guangdong in 2004 [15] and 10.3% (6/58) for H. nana in Xinjiang in 2003 [16].
In the diagnosis of hymenolepiasis and differentiation of causative species, eggs recovered from host feces usually play an important role for identifying their morphological features [17]. However, PCR-based molecular techniques not only increase detection rates of parasites, but also provide the accurate species differentiation and their genetic characterizations [18]. Currently, the first and second internal transcribed spacer regions (ITS1 and ITS2) of nuclear ribosomal RNA gene can be helpful for resolving remarkable taxonomic issues and discriminating closely related genera and species [18]. Meanwhile, mitochondrial (mt) genome sequences have been proven to be useful and reliable genetic markers for population genetics and systematic studies [18].
Northeastern China’s Heilongjiang Province is the biggest agricultural province and considered as the important commodity grain production base. To date, little information is available on H. nana and H. diminuta infections in these animals in this province [19]. During the period from April 2014 to March 2016, a total of 114 brown rats were captured using traps. They were collected from 4 different areas in Heilongjiang Province, including a granary in Xingren Town (n=23), a pig farm in Mingshui County (n=27), a pig farm in Qinggang County (n=27), and a sheep farm in Baoqing County (n=37). All the captured rats were euthanized by CO2 inhalation. Fecal materials were collected directly from the intestine section of each rodent. Each sample was detected for the presence of H. nana and H. diminuta eggs using direct smear method by bright-field microscopy under×100 and×400. The present study protocol was reviewed and approved by the Research Ethics Committee and the Animal Ethical Committee of Harbin Medical University, P. R. China (no. HMUIRB20130009).
Fecal samples were sieved and washed with distilled water by centrifugation for 10 min at 1,500 g. Processed samples were stored in −20°C prior to being used in molecular analysis. Genomic DNA was extracted from approximately 180–200 mg washed fecal pellets using a commercially available kit (QIAamp DNA Mini Stool Kit, Qiagen, Hilden, Germany) according to the manufacturer-recommended procedures. Eluted DNA (200 μl) was kept frozen at −20°C until its analysis with PCR. All the DNA samples were detected for the presence of H. nana and H. diminuta by PCR amplification of a 391 bp nucleotide fragment of COX1 gene and 671–741 bp ITS2 region. The 2 sets of primers and PCR cycling parameters were used as previously described [20,21]. TaKaRa TaqDNA Polymerase (TaKaRa Bio Inc., Tokyo, Japan) was used for all the PCR amplifications. A negative control with absence of DNA was included in all PCR tests. All the PCR products mentioned above were visualized by electrophoresis in 1.5% agarose gels stained with ethidium bromide before sequencing.
PCR products of COX1 gene and ITS2 region were sequenced in 2 directions with their respective PCR primers on an ABI PRISMTM3730 DNA Analyzer (Applied Biosystems, Carlsbad, California, USA), using a BigDye Terminator v3.1 Cycle Sequencing kit (Applied Biosystems). All the sequences obtained in the present study were compared with each other and reference sequences downloaded from GenBank database using the Basic Local Alignment Search Tool (BLAST) (http://blast.ncbi.nlm.nih.gov/Blast.cgi) and ClustalX 1.83 (http://www.clustal.org/). The sequences with single nucleotide substitutions, deletions or insertions compared to published sequences were all further confirmed by DNA sequencing of at least 2 PCR products. Representative nucleotide sequences obtained in this study were deposited in the GenBank database under the accession nos. KY079336 for H. nana and KY079337 to KY079339 for H. diminuta.
In the present study, 2 cestode species were detected in brown rats in the investigated areas, and H. diminuta (14.9%) showed a higher infection rate than H. nana (6.1%) (Table 1). Similar results occurred in brown rats in the Netherlands, with 10.2–50.0% for H. diminuta versus 0–4.1% for H. nana [9]. However, in a study of the endoparasites of brown rats conducted in Taiwan, H. nana (21.8%) was observed to be more common than H. diminuta (6.3%) [11].
H. diminuta eggs were observed in 5.3% (6/114) by microscopy while 14.9% (17/114) and 6.1% (7/114) at the COX1 and ITS2 loci by PCR, respectively. H. nana eggs were identified in 3.5% (4/114) by microscopy, while 6.1% (7/114) at the COX1 locus and 2.6% (3/114) at the ITS2 locus by PCR (Table 1). Here, PCR was observed to be 1.7 and 2.8 times as sensitive as microscopy in the diagnosis of H. nana and H. diminuta at the COX1 locus, respectively. Not surprisingly, PCR-based detection was more sensitive than microscopy. It is known that microscopic techniques are closely related to the infection intensity of parasite eggs in feces. In fact, usually, egg numbers can be very low with sporadic egg shedding, leading to under-diagnosis of hymenolepiasis [22]. Thus, PCR is recommended to be used in the future epidemiological studies of human and animal hymenolepiasis, which not only increases detection rate but also helps us to understand their molecular characterizations.
In the present study, PCR had a higher detection rate at the COX1 locus than at the ITS2 locus in detecting eggs of H. nana and H. diminuta, with 6.1% vs 2.6% for H. nana and 14.9% vs 6.1% for H. diminuta. Many factors can influence the efficiency of PCR amplification, mainly including the primers and genetic structure of target fragments, the quality and quantity of DNA templates, and the quality and characterization of DNA polymerase used. Here, since the same DNA preparations and DNA polymerase were used to amply the COX1 gene and ITS2 region of the 2 parasites, the degree of the primers binding DNA templates was likely to be the main reason for the amplification differences. The primers were originally designed from ‘conserved’ regions in the amplified genes. However, excessive mismatches in the binding regions of primer sequences might result in the failure of PCR amplification. In fact, numerous molecular data have confirmed both intra-specific genetic variations of H. nana and H. diminuta [2325].
The highest infection rates of H. nana (13.0%) and H. diminuta (26.0%) occurred in the rats from a granary, while the lowest (5.4%) from a sheep farm for either of the 2 parasites (Table 1). The current study is the first report of H. nana and H. diminuta in brown rats from a granary in China. It is well-known that granaries often have a high intensity of rats, and provide suitable environments for arthropods as intermediate hosts of the 2 parasites. This might increase the opportunity of H. nana and H. diminuta infection in these animals. In particular, H. diminuta does necessarily depend on arthropods including flour or grain beetles to complete its life cycle. Thus, measures should be taken to protect grains from rodents and insects.
In the present study, 7 COX1 gene sequences of H. nana were obtained, which were identical to each other (KY079336) and had the largest similarity (99.2%) with that from Mesocricetus auratus (AB494472). 3 ITS2 sequences of H. nana obtained here had 100% similarity with that from Mus musculus (HM536187). Likewise, at the ITS2 locus, 7 H. diminuta isolates were successfully amplified and produced the same sequence (KY079339), which had the largest homology (99.9%) with that from Rattus norvegicus (AB494475). However, intra-specific variation was found in H. diminuta isolates at the COX1 locus. 17 H. diminuta isolates produced 2 different COX1 gene sequences (KY079337 and KY079338), both of which had the largest similarity with that sequence (AF096244). The results of homology analysis of H. nana and H. diminuta isolates at the COX1 and ITS2 loci were shown in Table 2. The result that no intra-specific variation was found in H. nana isolates at the 2 loci might be related to the small number of H. nana isolates analyzed here. A previous study indicated extensive intra-specific variations of H. nana at the COX1 locus between 2 mouse-derived isolates as well as between human-derived and rodent-derived isolates [24]. A recent study revealed the presence of intra-specific variation of H. nana in the ITS2 region [23]. In fact, hymenolepidid species were observed to have larger intra-specific variations at the COX1 locus than at the ITS2 locus based on phylogenetic analysis [25]. Here, all the 3 representative COX1 gene sequences (1 from H. nana and 2 from H. diminuta) and 1 ITS2 sequence from H. diminuta were not reported previously.
In the present study, because only a few H. nana and H. diminuta isolates were analyzed genetically, no genetic difference was found in geographical distribution. Mohammadzadeh et al. [26] also believed that genetic characteristic was not always related with geographical distribution. The same conclusion was drawn by sequence and phylogenetic analyses of other mt genes (atp6, pnad5, and rrnS) of 42 H. nana isolates from 7 provinces in China [27]. However, it was reported on Canary Islands in Spain that the COX1 gene sequences of H. diminuta from 2 islands (Lazarote and Fuerteventrua) were genetically distant from those from other islands [28].
The present study described the occurrence of H. nana and H. diminuta in brown rats in Heilongjiang Province, suggesting that rodents infected with both cestodes have the potential to transmit hymenolepiasis to humans. In fact, human cases of hymenolepiasis caused by H. nana (n=14) and H. diminuta (n=1) have been reported in the investigated areas [29,30]. Clinically, hymenolepiasis is often neglected or underreported due to more asymptomatic infections in humans. However, 2 death cases caused by H. nana in immunosuppressed individuals highlight the severity of hymenolepiasis [7,8]. The importance and necessity to carry out epidemiological investigations of human hymenolepiasis is undeniable in the future, including assessment of transmission dynamic and the burden of human hymenolepiasis attributable to zoonotic transmission.
In conclusion, our present study demonstrated the occurrence of H. nana and H. diminuta in brown rats in Heilongjiang Province, China, implying that rodents infected with the 2 Hymenolepis species have the risk of transmitting hymenolepiasis to humans. Molecular data will be helpful to deeply study intra-specific variations within Hymenolepis cestodes in the future.

ACKNOWLEDGMENTS

The study was supported partially by the Heilongjiang Province Education Bureau of no.12531266 (Aiqin Liu). The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

CONFLICT OF INTEREST

CONFLICT OF INTEREST
The authors declare that they have no competing interests.

REFERENCES

1. Cheng T, Liu GH, Song HQ, Lin RQ, Zhu XQ. The complete mitochondrial genome of the dwarf tapeworm Hymenolepis nana—a neglected zoonotic helminth. Parasitol Res 2016;115: 1253-1262.
crossref pmid pdf
2. Thompson RC. Neglected zoonotic helminths: Hymenolepis nana, Echinococcus canadensis and Ancylostoma ceylanicum. Clin Microbiol Infect 2015;21: 426-432.
crossref pmid
3. Crompton DW. How much human helminthiasis is there in the world? J Parasitol 1999;85: 397-403.
crossref pmid
4. Tena D, Pérez Simón M, Gimeno C, Pérez Pomata MT, Illescas S, Amondarain I, González A, Domínguez J, Bisquert J. Human infection with Hymenolepis diminuta: case report from Spain. J Clin Microbiol 1998;36: 2375-2376.
pmid pmc
5. Karuna T, Khadanga S. A case of Hymenolepis diminuta in a young male from Odisha. Trop Parasitol 2013;3: 145-147.
crossref pmid pmc
6. Kim BJ, Song KS, Kong HH, Cha HJ, Ock M. Heavy Hymenolepis nana infection possibly through organic foods: report of a case. Korean J Parasitol 2014;52: 85-87.
crossref pmid pmc
7. Olson PD, Yoder K, Fajardo L-G LF, Marty AM, van de Pas S, Olivier C, Relman DA. Lethal invasive cestodiasis in immunosuppressed patients. J Infect Dis 2003;187: 1962-1966.
crossref pmid
8. Muehlenbachs A, Bhatnagar J, Agudelo CA, Hidron A, Eberhard ML, Mathison BA, Frace MA, Ito A, Metcalfe MG, Rollin DC, Visvesvara GS, Pham CD, Jones TL, Greer PW, Vélez Hoyos A, Olson PD, Diazgranados LR, Zaki SR. Malignant transformation of Hymenolepis nana in a human host. N Engl J Med 2015;373: 1845-1852.
crossref pmid
9. Franssen F, Swart A, van Knapen F, van der Giessen J. Helminth parasites in black rats (Rattus rattus) and brown rats (Rattus norvegicus) from different environments in the Netherlands. Infect Ecol Epidemiol 2016;6: 31413.
crossref pmid
10. Simões RO, Luque JL, Gentile R, Rosa MC, Costa-Neto S, Maldonado A. Biotic and abiotic effects on the intestinal helminth community of the brown rat Rattus norvegicus from Rio de Janeiro, Brazil. J Helminthol 2016;90: 21-27.
crossref pmid
11. Tung KC, Hsiao FC, Wang KS, Yang CH, Lai CH. Study of the endoparasitic fauna of commensal rats and shrews caught in traditional wet markets in Taichung City, Taiwan. J Microbiol Immunol Infect 2013;46: 85-88.
crossref pmid
12. d’Ovidio D, Noviello E, Pepe P, Del Prete L, Cringoli G, Rinaldi L. Survey of Hymenolepis spp. in pet rodents in Italy. Parasitol Res 2015;114: 4381-4384.
crossref pmid
13. Kataranovski M, Mirkov I, Belij S, Popov A, Petrovic Z, Gaci Z, Kataranovski D. Intestinal helminthes infection of rats (Ratus norvegicus) in the Belgrade area (Serbia): the effect of sex, age and habitat. Parasite 2011;18: 189-196.
crossref pmid pmc
14. Malsawmtluangi C, Tandon V. Helminth parasite spectrum in rodent hosts from bamboo growing areas of Mizoram, North-east India. J Parasit Dis 2009;33: 28-35.
crossref pmid
15. Wu J, Yi JR, Duan JH, Yin WX, Zhang SY, Liang L. Investigation on infection of Hymenolepis among Rattus noruegicus and Rattus flavipectus in Zhanjiang city, Guangdong province. Chin J Parasit Dis Con 2004;17: 306-307 (in Chinese).

16. Li BS, Liu YH, Liu Y, Luo WP, Tong SX, Sophia . Preliminary studies on the correlativity of Hymenolepis nana and Hymenolepis murina infection in Rural Communities, Xinjiang. Endemic Dis Bulletin 2003;18: 15-17 (in Chinese).

17. Nkouawa A, Haukisalmi V, Li T, Nakao M, Lavikainen A, Chen X, Henttonen H, Ito A. Cryptic diversity in hymenolepidid tapeworms infecting humans. Parasitol Int 2016;65: 83-86.
crossref pmid
18. Sharma S, Lyngdoh D, Roy B, Tandon V. Differential diagnosis and molecular characterization of Hymenolepis nana and Hymenolepis diminuta (Cestoda: Cyclophyllidea: Hymenolepididae) based on nuclear rDNA ITS2 gene marker. Parasitol Res 2016;115: 4293-4298.
crossref pmid pdf
19. Qu H, Sun YT, Sun YX, Liu W, Wang FG. Important investigation of zoonotic parasites in Heilongjiang Province. Agricult Technol 1999;19: 33-36 (in Chinese).

20. Bessho Y, Ohama T, Osawa S. Planarian mitochondria. I. Heterogeneity of cytochrome coxidase subunit I gene sequences in the freshwater planarian, Dugesia japonica. J Mol Evol 1992;34: 324-330.
crossref pmid
21. Blair D, van Herwerden L, Hirai H, Taguchi T, Habe S, Hirata M, Lai K, Upatham S, Agatsuma T. Relationships between Schistosoma malayensis and other Asian schistosomes deduced from DNA sequences. Mol Biochem Parasitol 1997;85: 259-263.
crossref pmid
22. Steinmann P, Cringoli G, Bruschi F, Matthys B, Lohourignon LK, Castagna B, Maurelli MP, Morgoglione ME, Utzinger J, Rinaldi L. FLOTAC for the diagnosis of Hymenolepis spp. infection: proof-of-concept and comparing diagnostic accuracy with other methods. Parasitol Res 2012;111: 749-754.
crossref pmid
23. Mirjalali H, Kia EB, Kamranrashani B, Hajjaran H, Sharifdini M. Molecular analysis of isolates of the cestode Rodentolepis nana from the great gerbil, Rhombomys opimus. J Helminthol 2016;90: 252-255.
crossref pmid
24. Macnish MG, Morgan-Ryan UM, Monis PT, Behnke JM, Thompson RC. A molecular phylogeny of nuclear and mitochondrial sequences in Hymenolepis nana (Cestoda) supports the existence of a cryptic species. Parasitology 2002;125: 567-575.
crossref pmid
25. Okamoto M, Agatsuma T, Kurosawa T, Ito A. Phylogenetic relationships of three hymenolepidid species inferred from nuclear ribosomal and mitochondrial DNA sequences. Parasitology 1997;115: 661-666.
crossref pmid
26. Mohammadzadeh T, Sadjjadi SM, Motazedian MH, Mowlavi GR. Study on the genomic diversity of Hymenolepis nana between rat and mouse isolates by RAPD-PCR. Iran J Vet Res 2007;8: 16-19.

27. Cheng T, Gao DZ, Zhu WN, Fang SF, Chen N, Zhu XQ, Liu GH, Lin RQ. Genetic variability among Hymenolepis nana isolates from different geographical regions in China revealed by sequence analysis of three mitochondrial genes. Mitochondrial DNA A DNA Mapp Seq Anal 2016;27: 4646-4650.
pmid
28. Foronda P, López-González M, Hernández M, Haukisalmi V, Feliu C. Distribution and genetic variation of hymenolepidid cestodes in murid rodents on the Canary Islands (Spain). Parasit Vectors 2011;26: 185.
crossref
29. Kang QD, Wei QY, Xie XL, Wu LP, Zhang Z, Fu YH, Li GX, Ma QH, Song ZY, Wang DC. An evaluation on survey of human parasite distribution in Heilongjiang Province. Chin J Parasitol Parasit Dis 1994;S1: 61-63 (In Chinese).

30. Shi FP, Liu BR. A case of Hymenolepis diminuta in human. J Jiamusi Med Coll 1989;12.

Table 1
Infection rates of Hymenolepis nana and H. diminuta in brown rats by microscopy and PCR
Collection site (county) No. examined No. positive for H. nana (%) No. positive for H. diminuta (%)


By microscopy COX1 ITS2 By microscopy COX1 ITS2
Granary (Xingren) 23 3 (13.0) 3 (13.0) 1 (4.3) - 6 (26.0) 2 (8.7)

Pig farm (Mingshui) 27 1 (3.7) 2 (7.4) - 4 (14.8) 5 (18.5) 3 (11.1)

Pig farm (Qinggang) 27 - - - 2 (7.4) 4 (14.8) 2 (7.4)

Sheep farm (Baoqing) 37 - 2 (5.4) 2 (5.4) - 2 (5.4) -

Total 114 4 (3.5) 7 (6.1) 3 (2.6) 6 (5.3) 17 (14.9) 7 (6.1)
Table 2
Homology analysis in nucleotides at COX1 and ITS2 loci of Hymenolepis nana and H. diminuta
Species Loci amplified Accession noa Accession nob Homology (%) Nucleotide (Position)
H. nana COX1 KY079336 AB494472 99.23 T to G/20; T to C/317; T to C/335
ITS2 HM536187 100.00

H. diminuta COX1 KY079337 AF096244 99.10 C to T/57; A to T/84; A to G/352; C to T/355
KY079338 AF096244 99.75 C to T/118
ITS2 KY079339 AB494475 99.86 A to T/691

a Accession nos. indicating the novel sequences obtained in the present study.

b Accession nos, indicating the sequences downloaded from GeneBank which have the largest homology with the sequences obtained in the present study.

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