Open access peer-reviewed chapter

Echinococcus shiquicus and Echinococcus felidis

Written By

Adel Spotin

Submitted: 03 November 2014 Reviewed: 14 May 2015 Published: 02 September 2015

DOI: 10.5772/60819

From the Edited Volume

Current Topics in Echinococcosis

Edited by Alfonso J. Rodriguez-Morales

Chapter metrics overview

2,673 Chapter Downloads

View Full Metrics

Abstract

Currently, ten genotypes (G1-G10) of Echinococcus Sensu Lato have been explicitly identified on the basis of taxonomic criteria. These include morphometric keys, host specificity, geographical distribution, phylogenetic analysis and genome mapping. However, a few emergent species of genus Echinococcus have been indigenously confirmed in some autonomous regions of Tibet plateau and Africa where there is little known about their biological aspects and potential pathogenicity in intermediate and definitive hosts. This chapter is focused on the parasite history, life cycle, phenotypic aspects, epidemiology, zoonotic potential and phylogeny relationship of two enigmatic parasites namely: Echinococcus shiquicus and Echinococcus felidis. This aims to provide a better understanding of their taxonomic status, public health problems and biological features in the mentioned regions.

Keywords

  • Echinococcus shiquicus
  • Echinococcus felidis
  • Biological Aspects
  • Phylogenetic traits

1. Introduction

Currently, ten genotypes (G1-G10) of Echinococcus Sensu Lato have been explicitly identified on the basis of taxonomic criteria. These include morphometric keys, host specificity, geographical distribution, phylogenetic analysis and genome mapping. However, a few emergent species of genus Echinococcus have been indigenously confirmed in some autonomous regions of Tibet plateau and Africa where there is little known about their biological aspects and potential pathogenicity in intermediate and definitive hosts. This chapter is focused on the parasite history, life cycle, phenotypic aspects, epidemiology, zoonotic potential and phylogeny relationship of two enigmatic parasites namely: Echinococcus shiquicus and Echinococcus felidis. This aims to provide a better understanding of their taxonomic status, public health problems and biological features in the mentioned regions.

Advertisement

2. Echinococcus shiquicus

2.1. History, morphology and biology

In ~2005, Echinococcus shiquicus was first described by Xiao, from the Tibetan fox in Shiqu county of the Qinghai–Tibet plateau, China called the ‘‘Roof of the World’’ [1]. Earlier than molecular analysis, the E. shiquicus isolated from Tibetan fox; Vulpes ferrilata was considered as a morphological strain of E. multilocularis, whilst it is metacestode from the plateau pika; Ochotona curzoniae, was then recognized as E. granulosus because of its unilocular cystic characteristics [2].

Figure 1.

The life cycle of Echinococcus shiquicus. Credit: Image courtesy of Seyyed Ali Shariatzadeh.

Afterward, based on taxonomic criteria including morphology, host specificity, molecular characters and geographical distribution was considered as a new species of Echinococcus [1].

The sylvatic cycle of E. shiquicus is supported by the Tibetan fox and the plateau pika as the definitive and intermediate hosts, respectively, which are indigenous to the highlands of Tibet (Figure 1) [1]. However, E. shiquicus using copro-PCR and sequencing strategies has been naturally reported in dogs from eastern Qinghai–Tibet plateau region, China [3].

The adult worms of E. shiquicus are observed into two types. The majority of the samples included pre-mature and gravid proglottid which testes and ovary are placed in the pre-mature segment while the genital pore is closed (Figure 2A) [1]. The second type consisted of immature, mature and gravid proglottid (Figure 2B). The number of segments in an adult worm is limited to three. E. shiquicus is readily discriminated from E. granulosus by its shorter length, length of hooks on the rostellum, branchless gravid uterus and anterior position of genital pore in the gravid proglottid. Also, the upper position of genital pore in the mature segment, smaller rostellar hooks and the fewer eggs in gravid segment of E. shiquicus (less than 100) are useful for differentiation of E. shiquicus in compared to E. multilocularis.

Figure 2.

Different adult types (A and B) of Echinococcus shiquicus in a naturally infected Tibetan fox.

The metacestode stage of E. shiquicus is characterized by presence of unilocular minicyst containing developed brood capsules with no daughter cysts. The morphometric aspects of E. shiquicus, E. multilocularis and E. granulosus are shown in Table 1.

Features E. shiquicus E. granulosus E. multilocularis
Body Length (mm) 1.3 -1.7 2.0–11.0 1.2– 4.5
Number of segments 2–3 2– 7 2–6
Length of
large hook on the rostellum (microns)
20.0– 23.0 25.0– 49.0 24.9– 34.0
Length of
small hook on the rostellum (microns)
16.0–17.0 17.0– 31.0 20.4– 31.0
Number of testicles 12–20 25– 80 16– 35

Table 1.

Comparison of the morphological aspects of Echinococcus spp.

The concomitant (dual) infections of E. shiquicus with E. multilocularis have been recently identified in O. curzoniae and Tibetan foxes [4]. The zoonotic potential of E. shiquicus is still unknown; although recently, some cases with unilocular and alveolar echinococcosis inclusive atypical ultrasound images have been characterized in Tibetans [5].

Although, no human infection of E. shiquicus has been reported yet, nevertheless the public health problems of E. shiquicus should not be neglected in control programs such as follow-up, monitoring and surveillance in an at risk population.

Therefore, additional studies are required to survey the possibility of human infections which can be employed in animal's models by serial passages using diagnostic antigens. The biological aspects of E. shiquicus including definitive host, intermediate hosts, genetic similarity and etc. are shown in Table 2.

Hydatid characters Infectivity to
humans
Genetic similarity Distribution Intermediate host Definitive host Species
Unilocular Uncertain Echinococcus
multilocularis
Tibetan
plateau
Pika Tibetan fox Echinococcus shiquicus
Unknown Uncertain Echinococcus granulosus Africa Warthog (possibly zebra, wildebeest,
bush pig, buffalo, various antelope, giraffe,
hippopotamus)
Lion Echinococcus felidis

Table 2.

A list of Echinococcus felidis and Echinococcus shiquicus features.

2.2. The evolutionary markers and molecular approaches in identifying Echinococcus spp.

The evolution in Echinococcus spp. can be considered as a combination of three major mechanisms that separately affect the composition of the genome of each species: mutation, selection and genetic drift [6].

Mutations occurred in the non-synonymous sites (called replacement sites because mutations at these sites lead to a change in the protein sequence) and the synonymous sites (called silent sites because mutations there do not lead to a change in the protein sequence) [6, 7].

It is worth noting that the nucleotide substitutions (Transition/Tranversion models) and/or indels (insertion or deletion) in the first and second positions of codons usually lead to create a new species/strain, which directly affect the frame shift of amino acids in case of any amino acid shifting or changing protein functionality while, changing in third position of codons (wobble site) is frequently leaded to creating novel haplotypes [8–11].

To date, the status of Echinococcus spp. is identified evidently by sequencing of nuclear DNA [12] and mitochondrial genome (mitogenome) accompanied by employing phylogenetic analysis on the basis of cladistics methods (Maximum Likelihood and Maximum Parsimony or Bayesian statistics and uses allele frequencies to study the nature and extent of genetic variation within and between populations) [13]. Although recently, a diagnostic pattern has been reported based on RFLP technique in differentiation of Echinococcus spp. using non-coding conserved gene [14].

It is important that the employing extra nuclear (mitochondrial) markers with low copy numbers and high variation characteristics are able to identify the unknown species/strains even haplotypes in exceptional regions where several intermediate hosts are circulating unequivocally [15].

2.3. Phylogenetic findings

Sequencing, phylogenetic and bioinformatics' analyses of mtDNA [16] and nuclear DNA [12] revealed that E. shiquicus and E. multilocularis are sister species with identical branch lengths in a specific clade and bootstrapping value of 99%.

Figure 3.

Nucleotide sequence alignments of Cox1 gene in Echinococcus spp.

The molecular characterization of Echinococcus spp. in the Tibetan plateau has demonstrated that the richness of genetic diversity indices of E. shiquicus is higher than those of E. granulosus s.s and E. multilocularis (Figure 3).

E. shiquicus, however, is placed with E. multilocularis in a common clade of ancestor with bootstrap value >70% (Figures 4 and 5).

This heterogeneity can be elucidated by description of three assumptions. First: presence of two turnover mechanisms, namely; unequal crossing over/transposition and slippage in the sequence length of parasite [17]. Second: lack of any bottleneck effects after its ancestor had been isolated on the Tibetan Plateau by colonizing alpine mammals (genetic drift or founder effect) [18]. And third: the long term geographic segregation into the plateau.

In a study, three polymerase chain reaction (PCR) assays based on the amplification of a fragment within the NADH dehydrogenase subunit 1 (ND1) mitochondrial gene have been optimized for the detection of E. shiquicus, E. granulosus and E. multilocularis in co-endemic regions of Qinghai-Tibet plateau, China [19].

Advertisement

3. Echinococcus felidis

3.1. Introduction

In Echinococcus species position, E. granulosus Sensu Lato has been categorized into E. granulosus Sensu Stricto (G1–G3), E. equinus (horse strain; genotype G4), E. ortleppi (cattle strain; genotype G5) and E. canadensis (genotypes G6–G10).

However, the taxonomic position, human infection, intermediate hosts and DNA profile of enigmatic ‘lion strain’ from Africa [20] has been unknown due to unavailability of suitable isolates.

3.2. History and biology

In 1937, Echinococcus felidis (Cestoda: Taeniidae) was first described by Ortlepp, from the lion Panthera leo, in South Africa [21]. Then, Rausch and Nelson (1963) declared that the taxonomic status of E. felidis remained to be uncertain from other Echinococcus spp. owing to existence of the host specificity and its rostellar hooks [22]. Verster (1965) re-checked the morphological features of E. felidis proglottids and proposed as a sub-specific rank of E. granulosus felidis [23]. Afterward, Rausch (1967) invalidated the sub-specific/strain status regarding E. felidis as an E. granulosus synonym because of lack of a valid evidence for it being a geographically isolated sylvatic cycle [24].

Many records of this parasite remained unidentified from a large variety of African mammals, due to the lack of diagnostic criteria, mainly genetic characterization and the misdiagnosis with the sympatric Echinococcus spp. [25] (Figure 6).

Echinococcosis is a high public health priority in the endemic areas of the world especially Africa, where more than one species of intermediate host is present and there is the possibility of interaction between cycles of transmission. Therefore the concomitant infections of E. felidis with other Echinococcus spp. may be sympatrically overlapped in under studied regions where it can be neglected.

The explicit status of E. felidis had not been determined until recent times. Huttner et al. (2008) presented its validity based on genetic classification and phylogenetic position [20].

The felids act as definitive hosts for enigmatic ‘lion strain’ however, It is still unclear which of the sympatric wild ungulates serve as intermediate hosts in life cycle of E. felidis. The different features of E. felidis are shown in Table 2. Like E. shiquicus, there is not enough data about human infection, hydatid feature and intermediate hosts. Therefore the zoonotic potential and public health concern among circulating isolates particularly those concomitant infections should be noticed absolutely.

3.3. Phylogenetic findings in E. felidis

Based on sequences of mitochondrial genes for cytochrome c oxidase subunit 1 (cox1), NADH dehydrogenase subunit 1 (nad1), cytochrome b (cob), rRNA (rrn), and nuclear genes for elongation factor 1 alpha (ef1a), ezrin-radixin-moesin (ERM)-like protein (elp) and

Figure 4.

Phylogenetic tree of Echinococcus spp. inferred from nuclear protein-coding genes.

Internal transcribed spacer (ITS), E. felidis and E. granulosus Sensu Stricto are presumed to have a common ancestor from Asian Felidae [20, 26].

Considering the assumption, ancestral lineage of Panthera leo in Asia is refereed to late Pliocene [10], which had been invaded to Africa in the early Pleistocene [27]. Phylogenetic trees of Echinococcus spp. inferred from mitogenome and nuclear protein-coding genes shown that both E. felidis and E. granulosus have placed in E. granulosus Sensu Stricto complex (genotypes G1, G2 and G3; Figures 4 and 5). In Figure 4 the E. felidis and E. granulosus are characterized with different branch lengths in a common clade and bootstrapping value of 97%.

Figure 5.

NeighborNet graph according to the Kimura-2 parameter model and concatenated sequences of Cox1 gene (mitogenome) of Echinococcus spp. Echinococcus felidis and Echinococcus shiquicus have characterized by asterisk (*) and red underline in E. granulosus and E. canadensis complexes respectively

The tree was reconstructed by the maximum likelihood method and Kimura-2 parameter model. Echinococcus felidis and Echinococcus shiquicus have characterized by asterisk (*) and red underline.

Figure 6.

The life cycle of Echinococcus felidis. Credit: Image courtesy of Seyyed Ali Shariatzadeh.

At this time, there are no valid data on the pathogenicity of E. felidis to humans and livestock although its close relationship with E. granulosus s.s proposed a zoonotic potential [28].

On the other hand, information about intermediate hosts of this parasite is still unknown, even though a hydatid cyst was identified as E. felidis from warthog in Queen Elizabeth National Park, Uganda [29].

Advertisement

4. Conclusion

In the past decade, E. shiquicus and E. felidis have been indigenously confirmed in some sympatric regions of Tibet plateau and Africa, however, there is no more known about their zoonotic potential, human infection and public health problems. The contents of this chapter can be useful in the parasite history, biology, morphometric aspects, epidemiology, zoonotic potential and phylogeny relationship of mentioned Echinococcus which is provided a better understanding of their taxonomic position, public health priority and biological aspects in the regions.

References

  1. 1. Xiao, N., Qiu, J., Nakao, M., Li, T., Yang, W., Chen, X., Schantz, P.M., Craig, P.S., Ito, A., 2005. Echinococcus shiquicus n. sp., a taeniid cestode from Tibetan fox and plateau pika in China. Int. J. Parasitol. 35, 693–701.
  2. 2. Xiao, N., Qiu, J., Nakao, M., Li, T., Yang, W., Chen, X., Schantz, P.M., Craig, P.S., Ito, A., 2006. Echinococcus shiquicus, a new species from the Qinghai-Tibet plateau region of China: discovery and epidemiological implications. Parasitol. Int. 55 (Suppl.), S233–S236.
  3. 3. Boufana, B., Qiu, J., Chen, X., Budke, C. M., Campos-Ponce, M., Craig, P. S., 2013. First report of Echinococcus shiquicus in dogs from eastern Qinghai–Tibet plateau region, China. Acta Trop. 127(1), 21–24.
  4. 4. Jiang, W., Liu, N., Zhang, G., Renqing, P., Xie, F., Li, T., Wang, Z., Wang, X., 2012. Specific detection of Echinococcus spp. from the Tibetan fox (Vulpes ferrilata) and the red fox (V. vulpes) using copro-DNA PCR analysis. Parasitol. Res. 111, 1531–1539.
  5. 5. Craig, P.S., Li, T., Qiu, J., Zhen, R., Wang, Q., Giraudoux, P., Ito, A., Heath, D., Warnock, B., Schantz, P., Yang, W., 2008. Echinococcosis and Tibetan communities. Emerg. Infect. Dis. 14, 1674–1675.
  6. 6. Wright, S., 1951. The genetic structure of populations. Ann Eugen.15, 323–354.
  7. 7. Yang, Z., Bielawski, J.P., 2000. Statistical methods for detecting molecular adaptation. Trends Ecol Evolut. 15, 496–503.
  8. 8. Strachan, T., 1999. Instability of the human genome: mutation and DNA repair.Human Molecular Genetics. 2nd edition. Chapter 9.
  9. 9. Najafzadeh, N., Sedaghat, M. M., Sultan, S. S., Spotin, A., Zamani, A., Taslimian, R.,. Parvizi, P., 2014. The existence of only one haplotype of Leishmania major in the main and potential reservoir hosts of zoonotic cutaneous leishmaniasis using different molecular markers in a focal area in Iran. Rev Soc Bras Med Trop. 47(5), 599–606.
  10. 10. Sharbatkhori, M., Spotin, A., Taherkhani, H., Roshanghalb, M., Parvizi, P., 2013. Molecular variation in Leishmania parasites from sandflies species of a zoonotic cutaneous leishmaniasis in northeast of Iran. J Vector Borne Dis. 51, 16–21.
  11. 11. Rouhani, S., Mirzaei, A., Spotin, A., Parvizi, P., 2014. Novel identification of Leishmania major in Hemiechinus auritus and molecular detection of this parasite in Meriones libycus from an important foci of zoonotic cutaneous leishmaniasis in Iran. J Infect Public Health. 7(3), 210–217.
  12. 12. Knapp, J., Bart, J.M., Glowatzki, M.L., Ito, A., Gerard, S., Maillard, S., Piarroux, R., Gottstein, B., 2007. Assessment of use of microsatellite polymorphism analysis for improving spatial distribution tracking of Echinococcus multilocularis. J. Clin. Microbiol. 45, 2943–2950.
  13. 13. Bowles, J., Blair, D., McManus, D.P., 1992. Genetic variants within the genus Echinococcus identified by mitochondrial DNA sequencing. Mol. Biochem. Parasitol. 54, 165–173.
  14. 14. Spotin, A., Gholami, S., Nasab, A.N., Fallah, E., Oskouei, M.M., Semnani, V., Shariatzadeh, S.A., Shahbazi, A., 2015. Designing and conducting in silico analysis for identifying of Echinococcus spp. with discrimination of novel haplotypes: an approach to better understanding of parasite taxonomic. Parasitol. Res. 1–7 [Epub ahead of print].
  15. 15. Spotin, A, Rouhani, S., Parvizi, P., 2014. The associations of Leishmania major and Leishmania tropica aspects by focusing their morphological and molecular features on clinical appearances in Khuzestan province, Iran. Biomed. Res. Int. 2014: 1–13.
  16. 16. Nakao, M., McManus, D.P., Schantz, P.M., Craig, P.S., Ito, A., 2007. A molecular phylogeny of the genus Echinococcus inferred from complete mitochondrial genomes. Parasitology. 134, 713–722.
  17. 17. Van Herwerden, L., Gasser, R. B., Blair, D., 2000. ITS-1 ribosomal DNA sequence variants are maintained in different species and strains of Echinococcus. Int. J. Parasitol. 30, 157–169.
  18. 18. Nakao, M., Li, T., Han, X., Ma, X., Xiao, N., Qiu, J., Wang, H., Yanagida, T., Mamuti, W., Wen, H., Moro, P.L., Giraudoux, P., Craig, P.S., Ito, A., 2010. Genetic polymorphisms of Echinococcus tapeworms in China as determined by mitochondrial and nuclear DNA sequences. Int. J. Parasitol. 40, 379–385.
  19. 19. Boufana, B., Umhang, G., Qiu, J., Chen, X., Lahmar, S., Boué, F., Craig, P. 2013. Development of Three PCR Assays for the Differentiation between Echinococcus shiquicus, E. granulosus (G1 genotype), and E. multilocularis DNA in the Co-Endemic Region of Qinghai-Tibet plateau, China. Am. J. Trop. Med. Hyg., 88(4), 795–802.
  20. 20. Huttner, M., Nakao, M., Wassermann, T., Siefert, L., Boomker, J.D., Dinkel, A., Sako, Y., Mackenstedt, U., Romig, T., Ito, A., 2008. Genetic characterization and phylogenetic position of Echinococcus felidis (Cestoda: Taeniidae) from the African lion. Int. J. Parasitol. 38, 861–868.
  21. 21. Ortlepp, R.J., 1937. South African Helminths, Part I. Onderstepoort J. Vet. Sci. Anim. Ind. 9, 311–336.
  22. 22. Rausch, R.L., Nelson, G.S., 1963. A review of the genus Echinococcus Rudolphi, 1801. Ann. Trop. Med. Parasitol. 57, 127–135.
  23. 23. Verster, A., 1965. Review of Echinococcus species in South Africa. Onderstepoort J. Vet. Res. 32, 7–118.
  24. 24. Rausch, R.L., 1967. A consideration of intraspecific categories in the genus Echinococcus Rudolphi, 1801 (Cestoda: Taeniidae). J. Parasitol. 53, 484–491.
  25. 25. Macpherson, C.N.L., Wachira, T.W.M., 1997. Cystic echinococcosis in Africa south of the Sahara. In: Andersen, F.L., Ouhelli, H., Kachani, M. (Eds.), Compendium of Cystic Echinococcosis in Africa and in Middle Eastern Countries with special Reference to Morocco. Brigham Young University, Provo, pp. 245–277.
  26. 26. Johnson, W.E., Eizirik, E., Pecon-Slattery, J., Murphy, W.J., Antunes, A., Teeling, E.,O Brien, S.J., 2006. The late Miocene radiation of modern Felidae: a genetic assessment. Science. 311, 73–77.
  27. 27. Werdelin, L., Lewis, M.E., 2005. Plio-Pleistocene Carnivora of eastern Africa: species Richness and turnover patterns. Zool. J. Linn. Soc. 144, 121–144.
  28. 28. Jenkins, E.J., Peregrine, A.S., Hill, J.E., Somers, C., Gesy, K., Barnes, B., Gottstein, B., Polley, L., 2012. Detection of European strain of Echinococcus multilocularis in North America. Emerg. Infect. Dis. 18, 1010–1012.
  29. 29. Huttner, M., Siefert, L., Mackenstedt, U., Romig, T., 2009. A survey of Echinococcus Species in wild carnivores and livestock in East Africa. Int. J. Parasitol. 39, 1269–1276.

Written By

Adel Spotin

Submitted: 03 November 2014 Reviewed: 14 May 2015 Published: 02 September 2015