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Echinococcus: the model cestode parasite

Published online by Cambridge University Press:  30 June 2021

Andrew Hemphill*
Affiliation:
Department of Infectious Diseases and Pathobiology, Vetsuisse Faculty, Institute of Parasitology, University of Bern, Länggass-Strasse 122, 3012 Bern, Switzerland
Britta Lundström-Stadelmann
Affiliation:
Department of Infectious Diseases and Pathobiology, Vetsuisse Faculty, Institute of Parasitology, University of Bern, Länggass-Strasse 122, 3012 Bern, Switzerland
*
Author for correspondence: Andrew Hemphill, E-mail: [email protected]

Abstract

Type
Editorial
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

Cestodes are important endoparasitic organisms, some of which are responsible for serious zoonotic diseases. The most severe diseases are inflicted by the larval stages (metacestodes) of Echinococcus multilocularis and E. granulosus sensu lato (s. l.), which are the causative agents of alveolar (AE) and cystic echinococcosis (CE), respectively. Another member of the Taeniidae family, Taenia solium, has also a prominent role as the causative agent of cysticercosis, with a special importance for neurocysticercosis (NC). The adult-stages of these parasites colonialize the intestine of their definitive hosts, which are foxes and dogs for E. multilocularis, canines for E. granulosus and humans for T. solium. In the intestine of the definitive host, self- or cross-fertilization of adults leads to the production of eggs which contain a zygote, eventually forming a pre-larval stage (oncosphere), which is then accidentally ingested by an intermediate host. CE and AE have been historically considered as food- and water-borne infections, with more recent evidence also pointing to the importance of hand-to-mouth transmission, and they are ranked as the most important foodborne parasites worldwide (Tamarozzi et al. Reference Tamarozzi, Deplazes and Casulli2020; Torgerson et al. Reference Torgerson, Robertson, Enemark, Foehr, van der Giessen, Kapel, Klun and Trevisan2020). For Echinococcus spp. and T. solium, several mammalian species can be infected as intermediate hosts, including humans, which act as dead-end hosts for E. granulosus and E. multilocularis. Within their intermediate hosts, the parasite larvae are usually targeted to distinct compartments or organs, such as the liver in most cases for E. multilocularis infections or liver and lungs for E. granulosus. In the case of T. solium infections, the most serious consequences occur upon invasion of the central nervous system, which less commonly also can be caused by Echinococcus spp. There, development into the larval metacestode (Echinococccus spp.) or cysticercus (T. solium) stage takes place, which causes disease due to expansion, extensive proliferation and/or inflammatory reactions on part of the host. Besides Echinococcus spp. and Taenia spp., there are a number of other, albeit less prominent, cestodes that exhibit a considerable zoonotic potential. A more recently, identified cestode causing disease in humans was identified in human cases in North America, causing systemic infection of organs and blood vessels (Deplazes et al. Reference Deplazes, Eichenberger and Grimm2019). Metacestodes exhibited molecular hallmarks that resembled, but were clearly distinct from, Vesteria mustelae. Vesteria mustelae parasitizes weasels and has not been demonstrated to be zoonotic, indicating that previously unrecognized human pathogenic cestodes species with still unknown potential animal hosts exist (Deplazes et al. Reference Deplazes, Eichenberger and Grimm2019). Other species causing disease in humans include Hymenolepis and Dibothriocephalus, but also Bertiella, Dipylidium, Raillietina, Inermicapsifer and Mesocestoides. As indicated in a recently published review, the true clinical significance of these less prominent tapeworms is not well known, as they are often more difficult to identify and there is also a rather limited awareness of their existence (Sapp and Bradbury, Reference Sapp and Bradbury2020).

For the study of NC caused by T. solium, the exploration of the cellular and molecular processes underlying disease progression is a difficult task, and in vitro models have only a limited value. However, different animal models for NC have been exploited to carry out experimental infections in a controlled environment, and these allow to study disease progression both with and without treatment interventions (reviewed in de Lange et al. Reference de Lange, Mahanty and Raimondo2019). In contrast, for E. multilocularis several in vitro laboratory models have enabled researchers to maintain and propagate metacestodes as well as germinal layer cells (including parasite stem cells) (Spiliotis and Brehm, Reference Spiliotis and Brehm2009). These models have opened the way for researchers to elucidate several aspects of the parasite biology, such as the involvement of signalling pathways in differentiation processes during larval stage formation, parasite physiology, metabolomics, proteomics and transcriptomics, and different aspects of the host–parasite relationship, including immunomodulatory mechanisms (Tsai et al. Reference Tsai, Zarowiecki, Holroyd, Garciarrubio, Sánchez-Flores, Brooks, Tracey, Bobes, Fragoso, Sciutto, Aslett, Beasley, Bennett, Cai, Camicia, Clark, Cucher, De Silva, Day, Deplazes, Estrada, Fernández, Holland, Hou, Hu, Huckvale, Hung, Kamenetzky, Keane, Kiss, Koziol, Lambert, Liu, Luo, Luo, Macchiaroli, Nichol, Paps, Parkinson, Pouchkina-Stantcheva, Riddiford, Rosenzvit, Salinas, Wasmuth, Zamanian, Zheng, Cai, Soberón, Olson, Laclette, Brehm and Berriman2013; Zheng et al. Reference Zheng, Zhang, Zhang, Zhang, Li, Lu, Zhu, Wang, Huang, Liu, Kang, Chen, Wang, Chen, Yu, Gao, Jin, Gu, Wang, Zhao, Shi, Wen, Lin, Jones, Brejova, Vinar, Zhao, McManus, Chen, Zhou and Wang2013; Nono et al., Reference Nono, Lutz and Brehm2014; Brehm and Koziol, Reference Brehm and Koziol2017; Monteiro et al. Reference Monteiro, Lorenzatto, de Lima, dos Santos, Förster, Paludo, Carvalho, Brehm and Ferreira2017; Ritler et al. Reference Ritler, Rufener, Li, Kämpfer, Müller, Bühr, Schürch and Lundström-Stadelmann2019; Zhou et al. Reference Zhou, Wang, Cui, Shi, Ma, Yu, Zhao and Zhao2019; Fratini et al. Reference Fratini, Tamarozzi, Macchia, Bertuccini, Mariconti, Birago, Iriarte, Brunetti, Cretu, Akhan, Siles-Lucas, Díaz and Casulli2020). In addition, different rodent models have been applied to investigate the pathogenesis and aspects of the host immune response. Very importantly, these in vitro and in vivo models provided the basis to establish reliable screening platforms for the assessment of either novel candidate drugs and/or different drug formulations of potential therapeutic value (Lundström-Stadelmann et al. Reference Lundström-Stadelmann, Rufener, Ritler, Zurbriggen and Hemphill2019).

These advances have placed E. multilocularis and E. granulosus on the radar as the prime models to study different aspects related to cestode biology and treatment of cestode infections. This is illustrated in a series of seven papers that have been published in Parasitology during 2018–2020. These papers deal with different aspects encountered during surgery, establishment of in vitro and in vivo infection models, and development of novel chemotherapeutical treatment options against Echinococcus ssp.

Surgical treatment of alveolar and cystic echinococcosis

The treatment of AE largely relies on surgery and/or chemotherapy depending on different factors that include metacestode size and location, number of cysts, viability status, the interaction between the expanding parasite and the adjacent host tissue, and bacterial and fungal super-infection. In the case of CE, other options include PAIR (puncture, aspiration, injection and re-aspiration) and ‘watch and wait’ (Agudelo Higuita et al. Reference Agudelo Higuita, Brunetti and McCloskey2016), and potential complications are related to cyst rupture and spillage of protoscoleces, which can lead to secondary cyst formation. For AE, complete surgical resection is the only real curative treatment, since the established chemotherapy with benzimidazoles [albendazole (ABZ)/mebendazole (MBZ)] does not act parasiticidal. In addition, surgery is always accompanied by peri- and post-operative chemotherapeutical benzimidazole treatment, not only for AE, but also for CE. The paper by Yang et al. (Reference Yang, He, Yang and Wang2019) summarizes the findings of a study of 178 patients suffering from hepatic AE, which were all treated by definitive radical surgery in the West China Hospital of the Sichuan University, Chengdu, China. Patients were grouped into four categories: A, patients with direct radical hepatic resection; B, patients with percutaneous puncture external drainage followed by radical hepatic resection 2 months later; C, patients undergoing two-step hepatic resection; D, patients undergoing liver transplantation. Following surgery, patients were followed up for 8–72 months, and data on mortality, post-operative complications and recurrence rates were compared. No post-operative mortality was seen in groups B and C, while a fraction of patients in groups A and D (2.29 and 8.62%, respectively) suffered from lethal postoperative complications. For the others, no recurrence was noted. The authors concluded that radical resection of the liver by experienced hepatic surgeons is the preferred treatment of hepatic AE. Akbulut and Sahin (Reference Akbulut and Sahin2020) published a comment on that paper and provided some additional explanations and clarifications which are based on the current WHO guidelines (Brunetti et al., Reference Brunetti, Kern and Vuitton2010). First, E. multilocularis metacestodes exhibit the hallmarks of a neoplastic, invasive lesion. Therefore, a clear surgical margin of 10 mm around the lesion can reduce the postoperative recurrence risk. Unfortunately, in many cases, radical surgery cannot be performed as these are diagnosed at the late stage of disease. ABZ therapy, and also MBZ therapies should continue for at least 2 years after surgery. Other anthelmintic drugs such as praziquantel and nitazoxanide have also been used (with no or only limited success), and the anti-fungal compound amphotericin B was applied as a salvage treatment. For post-operative surveillance, a combined radiological and serological follow-up for up to 10 years would be optimal. Inoperable cases of AE must undergo long-term/mostly life-long benzimidazole treatments. Other surgical options beside radical resection include ex vivo liver resection and auto-transplantation, and ultimately liver transplantation. However, these are major surgical procedures and are associated with high morbidity and mortality risk.

Overall, these two papers underline the need for improved and more efficacious, preferentially curative, chemotherapeutical treatment options for patients suffering from echinococcosis. To identify and perform pre-clinical studies on such novel options, experimental in vitro and in vivo models are indispensable tools.

In vitro and in vivo models for the maintenance and study of E. multilocularis metacestodes

The paper published by Laurimäe et al. (Reference Laurimäe, Kronenberg, Alvarez Rojas, Ramp, Eckert and Deplazes2020) highlighted important issues related to E. multilocularis in vitro and in vivo models, which are also relevant for drug discovery. The traditional method to preserve different Echinococcus isolates/strains has been to maintain the proliferative metacestode tissue in rodents, typically by intraperitoneal injection into the highly susceptible Meriones spp. or different laboratory mouse strains such as BALB/c or B57BL/6. Due to the tumour-like proliferation of metacestode tissue, animals are typically euthanized after 2–3 months (in most cases prior to protoscolex development), dissected and parasite tissue is transferred to another animal. A major caveat of this procedure is physiological adaptation, meaning that the biological characteristics of the metacestode might change due to adaption to the murine host. Different techniques have been developed that would allow in vitro culture of E. multilocularis metacestodes (Hemphill and Gottstein, Reference Hemphill and Gottstein1995; Jura et al., Reference Jura, Bader, Hartmann, Maschek and Frosch1996). However, the major breakthrough that allowed to maintain and propagate metacestodes at a larger scale is the culture method established by Spiliotis and Brehm (Reference Spiliotis and Brehm2009). This method enables researchers to propagate metacestode vesicles at a high rate, makes it possible to induce protoscolex development in vitro, and also allows axenic cultivation and culture of germinal layer cells, and thus the totipotent parasite stem cells. The insight that these stem cells need to be killed to achieve true parasiticidal effects is important when it comes to drug development. While application of these techniques led to a steady increase in our knowledge on the parasite biology, its metabolic requirements and its interaction with the host, adaptation to in vitro culture conditions is again likely to provide biased results. In terms of treatment options, there is a clear risk that drug susceptibility properties of rodent-adapted isolates or culture-adapted parasites could be rather different from low-passage-number-isolates obtained from, e.g. human tissue, which would reflect the ‘true’ parasites.

In their paper, Laurimäe et al. provide a potential solution to this problem. They show how cryopreservation of isolates, namely of metacestode-infected tissue blocks and/or protoscoleces, could be valuable alternative to long-term in vitro/in vivo maintenance. Surprisingly, this paper has revealed that protocols for cryopreservation of E. multilocularis had been established and validated already in 1985 (Eckert and Ramp, Reference Eckert and Ramp1985; Eckert, Reference Eckert1988). By analysing samples that were cryopreserved with this ‘forgotten’ protocol from 1984 to 1986, the authors showed that some of the metacestodes and protoscoleces were still viable after 35 years of storage in liquid nitrogen. Metacestodes (35%) underwent growth and proliferation in vitro, and protoscoleces (76%) were motile and thus viable in vitro. The in vivo infection rate in a rodent model was at 58%, of which 36% showed abortive lesions. Thus, with the described cryopreservation technique the parasite was able to survive, though at a limited rate. Genetic analysis confirmed that the isolates belonged to European, Asian and North-American clades. It is not clear whether metacestode proliferation after cryopreservation is due to surviving micro-vesicles or due to the stem cells from the germinal layer. Cryopreservation is thus a suitable method for long-term storage of Echincoccocus isolates, and this has the potential to (i) reduce the number of experimental animals that would otherwise be needed to propagate the parasite in serial passages, and (ii) to carry out drug-treatment studies without the bias of adaptive processes during in vitro culture or in vivo maintenance.

Improving treatments by improving the solubility of benzimidazoles

While clinical studies have shown that benzimidazole-based chemotherapy of CE can actually act curative, depending on several factors as outlined above, the situation is different for AE, and benzimidazoles will halt parasite growth but do not act parasiticidal. Nevertheless, it is important to point out that the benzimidazole-based therapy developed by Professor Dr Johannes Eckert and colleagues over 40 years ago (Schantz et al., Reference Schantz, Van den Bossche and Eckert1982) has been a major advance, as it has significantly increased the 10-year survival rate for AE patients that cannot undergo radical surgery from around 20 to 80–85%. Nevertheless, adverse reactions to benzimidazole therapy such as severe hepatotoxicity have been reported frequently, often leading to treatment discontinuation. To avoid such adverse effects, regular monitoring of liver enzymes, drug serum levels and, if necessary, adjustment of the dosage are required. As this is only possible in countries with an advanced health service infrastructure, and most AE and CE cases are found in resource-poor settings, better drugs are needed. Despite these shortcomings, no new drugs, or only few new formulations of already existing lead drugs, have been specifically patented in the last 40 years (Patentscope database, 2020).

The poor bioavailability of ABZ and MBZ is due to inadequate solubility and thus absorbance in the intestine. Thus, high dosages and repeated and/or long-term treatments are required to reach adequate systemic distribution, which expose patients to adverse side-effects and decrease their quality of life. Strategies to improve bioavailability have been pursued, and newly developed formulations of benzimidazoles were developed, such as ABZ complexes with phospholipid-based liposomes, or ABZ emulsions that exhibit increased absorption without increasing the toxicity (reviewed in Hemphill et al., Reference Hemphill, Stadelmann, Rufener, Spiliotis, Boubaker, Müller, Müller, Gorgas and Gottstein2014, Reference Hemphill, Rufener, Ritler, Dick, Lundström-Stadelmann, Swinney and Pollastri2019). Another and highly valuable strategy has been introduced by the paper by Vural et al. (Reference Vural, Yardimci, Kocak, Yasar, Kurt, Harem, Carradori, Sciamanna, Siles-Lucas, Fabiani, Hemphill, Lundström-Stadelmann, Cirilli and Casulli2020), which reports on the use of novel benzimidazole salt formulations and their use in experimentally induced CE in mice. These formulations were developed within the framework of the HERACLES European funded project (Casulli et al., Reference Casulli, SilesLucas, Cretu, Vutova, Akhan, Vural, CortésRuiz, Brunetti and Tamarozzi2020). Salt formulations of ABZ and ABZ-sulfoxide (ricobendazole, RBZ) have been patented for the European and US markets, and include sodium salts of ABZ (ABZ-Na), RBZ (RBZ-Na) and salts of the RBZ enantiomers. These formulations exhibit dramatically increased solubility of the compounds. Vural et al. comparatively evaluated oral application by gavage of ABZ, RBZ and RBZ enantiomers and respective salt formulations in BALB/c mice intraperitoneally infected with E. granulosus protoscoleces and monitored changes in the pharmacokinetics of RBZ enantiomers and the parasite mass upon treatments. They demonstrated a significant reduction of parasite load in mice treated with most of the salt formulations compared to conventional ABZ treatment. This reduction coincided with improved bioavailability as determined by PK studies, and aberrant structural integrity of both laminated and germinal layer of the parasite. They also found consistently lower drug concentrations in the cyst fluid compared to plasma samples, illustrating the problems to get the drug to the desired site of action, namely the interior of the parasite. Overall, these results are encouraging, since benzimidazole salts can be synthesized in a simple, cheap and rapid manner, they have an improved and more rapid anthelmintic activity than the conventional benzimidazoles, and are prone to cause less side-effects (Vural et al. Reference Vural, Yardimci, Kocak, Yasar, Kurt, Harem, Carradori, Sciamanna, Siles-Lucas, Fabiani, Hemphill, Lundström-Stadelmann, Cirilli and Casulli2020).

Another way to increase solubility of benzimidazoles is to introduce structural modifications, by adding hydrophilic moieties to the benzimidazole scaffold. Recently, Xu et al. (Reference Xu, Duan, Zhang, Xu, Chen, Hu, Gui, Huang, Wang, Dang and Zhao2019) introduced an epoxy group to MBZ by a reaction with epichlorohydrin and obtained two isoforms (M-C1 and M-C2), both of which exhibited much higher solubility compared to non-modified MBZ. In vitro exposure of E. multilocularis protoscoleces to 1 μ m M-C2 (1–30 μ m) resulted in protoscolex mortality similar to MBZ. In addition, in vitro treatments of E. multilocularis metacestodes with M-C2 resulted in a high degree of damage. The other derivative, M-C1, did not affect neither protoscoleces nor metacestodes. However, both derivatives showed a markedly reduced cytotoxicity in rat hepatoma cell cultures compared to MTZ. Thus, these modifications on the benzimidazole scaffold improved MBZ solubility, resulting in one compound with higher efficacy, and an isoform with lower anti-parasitic activity. Further studies on in vivo pharmacokinetics, pharmacodynamics and toxicity should be carried out to forward such compounds to a suitable in vivo model.

Natural products for the treatment of alveolar and cystic echinococcosis

Powerful pharmacological activities, accessibility, relatively low costs and generally low toxicities are the hallmarks of medicinal plants, whose pharmaceutical and anti-parasitic properties are often attributed to essential oils. For instance, essential oils with documented activities against E. granulosus protoscoleces and metacestodes have been derived from Mentha piperita and M. pulegium. The main compound in M. pulegium essential oil is piperitone oxide, with suspected protoscolicidal and metacestodicidal effects. Other natural products with significant anti-protoscolex activity are derived from endophytic Pestalotiopsis sp., from the circassian walnut Juglans regia, Myrtus communis L. essential oil and Nectaroscordum tripedale L. leaf extract. However, in all these studies, the corresponding active substances have not been determined (Hemphill et al., Reference Hemphill, Rufener, Ritler, Dick, Lundström-Stadelmann, Swinney and Pollastri2019; Lundström-Stadelmann et al., Reference Lundström-Stadelmann, Rufener, Ritler, Zurbriggen and Hemphill2019).

Of all the natural herb products tested, thymol and carvacrol, two isomers that differ only by the positioning of a hydroxyl group, represent promising options. Thymol and carvacrol are the main components of essential oils of Thymus vulgaris and Origanum vulgare.

In the study by Hizem et al. (Reference Hizem, Lundström-Stadelmann, M'rad, Souiai, Ben Jannet, Flamini, Ascrizzi, Ghedira, Babba and Hemphill2019), the essential oil of Thymus capitatus, seven defined fractions (F1–F7) obtained from silica gel chromatography and several pure essential oil components were evaluated with respect to in vitro activities against E. multilocularis metacestodes and in vitro cultured germinal layer cells. Measurements of metacestode viability and transmission electron microscopy demonstrated that exposure to essential oil, F2 and F4 impaired metacestode viability. F2 and F4 exhibited higher toxicity against metacestodes than against mammalian cells, whereas essential oil was as toxic to mammalian cells as to the parasite. However, none of these fractions exhibited notable activity against isolated E. multilocularis germinal layer cells. Hizem et al. also analysed the essential oil and different fractions by gas chromatography and mass spectrometry and showed that carvacrol was the major component of the essential oil (82.4%), as well as of fractions F3, F4 and F5 (>90%). Other major components of essential oil were β-caryophyllene, limonene, thymol and eugenol. However, exposure of metacestodes to all these individual components, including carvacrol, and a combination of these components, was ineffective. Thus, while the fractions F2 and F4 of T. capitatus essential oil contain potent anti-echinococcal compounds, the activities of these two fractions are most likely based on synergistic effects between several major and minor constituents, and not on an individual compound. Nevertheless, these compounds could be exploited for the development of novel treatments once these synergisms are elucidated.

Drug repurposing and nano-encapsulation

Besides exploiting natural compounds, drug repurposing, meaning the use of already existing drugs, is regarded a valid strategy to accelerate the pipeline for drug licensing. Drug repurposing has the potential to decrease the time that is required to reach the market and to reduce costs. In vitro, a variety of anti-cancer, anti-fungal and anti-protozoal drugs were efficacious against metacestodes of E. multilocularis and E. granulosus (Hemphill et al., Reference Hemphill, Rufener, Ritler, Dick, Lundström-Stadelmann, Swinney and Pollastri2019; Lundström-Stadelmann et al., Reference Lundström-Stadelmann, Rufener, Ritler, Zurbriggen and Hemphill2019). A classic example of drug repurposing was reported by Fabbri et al. (Reference Fabbri, Pensel, Albani, Arce, Mártire and Elissondo2019), by introducing the use of dichlorophen (DCP), a halogenated phenolic compound used as bactericide and fungicide in cosmetic product formulations. This compound has been repurposed earlier for a variety of infections by intestinal stages of nematodes and tapeworms, including Ascaris lumbricoides, Taenia saginata and Hymenolepis nana. DCP has a very low solubility in water and is poorly absorbed after oral administration. Thus, to be able to apply this compound for treatment of a systemic infection, solubility must be improved to increase absorption. Nano-encapsulation of drugs is a well-known strategy, and Fabbri et al. evaluated the in vitro and in vivo efficacy of DCP and DCP-loaded silica nanoparticles (DCP-NP) against E. multilocularis metacestodes. In vitro, NP-DCP (0.1, 0.5 and 1 μg/mL) impaired the survival of protoscoleces in a time- and dose-dependent manner and to a much higher degree than free NP or ABZ, and microscopy demonstrated distinct morphological and structural alterations which indicated parasite death. In vitro treatment of E. multilocularis metacestodes with 0.5 and 1 μg/mL of NP-DCP strongly altered the germinal layer of parasites and lead to rapid vesicle death. In vivo studies in a rodent model demonstrated that the NP-DCP applied at 4 mg/kg had similar efficacy as ABZ applied at 25 mg/kg and was more efficacious than non-encapsulated DCP. Therefore, the repurposing of DCP combined with silica nanoparticles could be an alternative for the treatment of echinococcosis.

Where to go from here…

The examples presented here are just a very minor part of a much larger number of preclinical studies that have been carried out to inform on and/or improve the current treatment options for echinococcosis. The published literature on the subject, when using the keywords ‘echinococcosis’ and ‘therapy’, amounts up to >9200 entries in PubMed, and in the last 20 years, 200–280 papers on these topics have been published annually. These publications include case reports, immunological, molecular and biochemical studies, and also reports on compounds that would be potentially interesting as novel treatment options. However, for many compounds or compound formulations, no or very limited in vivo studies were published. This could be due to very limited project financing, the lack of specificity and toxicity of the compounds or, and this is unfortunate, the authors wanted to refrain from publishing ‘negative’ results. The latter is commonly observed, and creates a disturbing lack of knowledge, which hinders advancements in the field. Another striking observation is that most studies which claim to have investigated compounds against AE or CE have applied subjective methods for in vitro testing against Echinococcus protoscoleces by light microscopy. However, metacestodes, and not protoscoleces, are the disease-causing stages of AE and CE. In vitro culture methods for metacestodes and objective measurements of drug-impact are actually available, and researchers in the field should implement these methods more often.

In addition, several substances, even though they looked promising in mouse trials, were not pursued further. This could be due to side-effects and toxicity issues (often also not reported in the literature). Other compounds were not followed up most likely because of financial constraints, which is a commonly encountered problem when it comes to developing novel treatments for diseases with no, or only little, market return. With few exceptions, pre-clinical studies do not take into account the regulatory process. Thus, there is a lack of clear strategy encompassing preclinical and clinical studies aiming at licensing new treatments for the market. Overall, none of the approaches carried out to date have identified alternatives with improved properties compared to the benzimidazoles used to date. Further screening efforts should be undertaken to identify better compounds with increased efficacy and specificity, and improved safety, and novel drug targets should be identified and validated, with the clear aim to overcome the regulatory hurdles leading to clinical application.

Echinococcus multilocularis and E. granulosus are highly adapted to a parasitic lifestyle, and crucial genes and entire pathways for the de novo-synthesis of pyrimidines, purines and amino acids are absent in the genome, and genes for fatty acid and cholesterol de novo synthesis are largely missing. Transcripts coding for respective proteins/enzymes involved in uptake and transport of these essential components are upregulated in the metacestode stage, as has been recently shown for fatty acid binding proteins (Pórfido et al., Reference Pórfido, Herz, Kiss, Kamenetzky, Brehm, Rosenzvit, Córsico and Franchini2020). These auxotrophies should be targeted and exploited for the development of novel therapeutic options.

References

Agudelo Higuita, NI, Brunetti, E and McCloskey, C (2016) Cystic echinococcosis. Journal of Clinical Microbiology 54, 518523.CrossRefGoogle ScholarPubMed
Akbulut, S and Sahin, TT (2020) Comment on surgical approaches for definitive treatment of hepatic alveolar echinococcosis: results of a survey in 178 patients. Parasitology 147, 14081410.CrossRefGoogle ScholarPubMed
Brehm, K and Koziol, U (2017) Echinococcus-host interactions at cellular and molecular levels. Advances in Parasitology 95, 147212.CrossRefGoogle ScholarPubMed
Brunetti, E, Kern, P and Vuitton, DA; Writing Panel for the WHO-IWGE (2010) Expert consensus for the diagnosis and treatment of cystic and alveolar echinococcosis in humans. Acta Tropica 114, 116.CrossRefGoogle ScholarPubMed
Casulli, A, SilesLucas, M, Cretu, CM, Vutova, K, Akhan, O, Vural, G, CortésRuiz, A, Brunetti, E and Tamarozzi, F (2020) Achievements of the HERACLES project on cystic echinococcosis. Trends in Parasitology 36, 14.CrossRefGoogle ScholarPubMed
de Lange, A, Mahanty, S and Raimondo, JV (2019) Model systems for investigating disease processes in neurocysticercosis. Parasitology 146, 553562.CrossRefGoogle ScholarPubMed
Deplazes, P, Eichenberger, RM and Grimm, F (2019) Wildlife transmitted Taenia and Versteria cysticercosis and coenurosis in humans and other primates. International Journal for Parasitology-Parasites and Wildlife 9, 342358.CrossRefGoogle ScholarPubMed
Eckert, J (1988) Cryopreservation of parasites. Experientia 44, 873877.CrossRefGoogle ScholarPubMed
Eckert, J and Ramp, T (1985) Cryopreservation of Echinococcus multilocularis metacestodes and subsequent proliferation in rodents (Meriones). Zeitschrift für Parasitenkunde 71, 777787.CrossRefGoogle ScholarPubMed
Fabbri, J, Pensel, PE, Albani, CM, Arce, VB, Mártire, DO and Elissondo, MC (2019) Drug repurposing for the treatment of alveolar echinococcosis: in vitro and in vivo effects of silica nanoparticles modified with dichlorophen. Parasitology 146, 16201630.CrossRefGoogle ScholarPubMed
Fratini, F, Tamarozzi, F, Macchia, G, Bertuccini, L, Mariconti, M, Birago, C, Iriarte, A, Brunetti, E, Cretu, CM, Akhan, O, Siles-Lucas, M, Díaz, A and Casulli, A (2020) Proteomic analysis of plasma exosomes from cystic echinococcosis patients provides in vivo support for distinct immune response profiles in active vs inactive infection and suggests potential biomarkers. PLoS Neglected Tropical Diseases 14, e0008586.CrossRefGoogle ScholarPubMed
Hemphill, A and Gottstein, B (1995) Immunology and morphology studies on the proliferation of in vitro cultivated Echinococcus multilocularis metacestodes. Parasitology Research 81, 605614.CrossRefGoogle ScholarPubMed
Hemphill, A, Stadelmann, B, Rufener, R, Spiliotis, M, Boubaker, G, Müller, J, Müller, N, Gorgas, D and Gottstein, B (2014) Treatment of echinococcosis: albendazole and mebendazole – what else? Parasite 21, 70.CrossRefGoogle ScholarPubMed
Hemphill, A, Rufener, R, Ritler, D, Dick, L and Lundström-Stadelmann, B (2019) Drug discovery and development for the treatment of echinococcosis, caused by the tapeworms Echinococcus granulosus and Echinococcus multilocularis. In Swinney, DC, Pollastri, M (eds), Neglected Tropical Diseases: Drug Discovery and Development. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, pp. 251286.Google Scholar
Hizem, A, Lundström-Stadelmann, B, M'rad, S, Souiai, S, Ben Jannet, H, Flamini, G, Ascrizzi, R, Ghedira, K, Babba, H and Hemphill, A (2019) Activity of Thymus capitatus essential oil components against in vitro cultured Echinococcus multilocularis metacestodes and germinal layer cells. Parasitology 146, 956967.CrossRefGoogle ScholarPubMed
Jura, H, Bader, A, Hartmann, M, Maschek, H and Frosch, M (1996) Hepatic tissue culture model for study of host-parasite interactions in alveolar echinococcosis. Infection and Immunity 64, 34843490.CrossRefGoogle ScholarPubMed
Laurimäe, T, Kronenberg, PA, Alvarez Rojas, CA, Ramp, TW, Eckert, J and Deplazes, P (2020) Long-term (35 years) cryopreservation of Echinococcus multilocularis metacestodes. Parasitology 147, 10481054.CrossRefGoogle ScholarPubMed
Lundström-Stadelmann, B, Rufener, R, Ritler, D, Zurbriggen, R and Hemphill, A (2019) The importance of being parasiticidal… an update on drug development for the treatment of alveolar echinococcosis. Food and Waterborne Parasitology 15, e00040.CrossRefGoogle ScholarPubMed
Monteiro, KM, Lorenzatto, KR, de Lima, JC, dos Santos, GB, Förster, S, Paludo, GP, Carvalho, PC, Brehm, K and Ferreira, HB (2017) Comparative proteomics of hydatid fluids from two Echinococcus multilocularis isolates. Journal of Proteomics 162, 4051.CrossRefGoogle ScholarPubMed
Nono, JK, Lutz, MB and Brehm, K (2014) EmTIP, a T-cell immunomodulatory protein secreted by the tapeworm Echinococcus multilocularis is important for early metacestode development. PLoS Neglected Tropical Diseases 8, e2632.CrossRefGoogle ScholarPubMed
Patentscope database (2020) Available at https://www.wipo.int/patentscope/en/ (Accessed 15 June 2020).Google Scholar
Pórfido, JL, Herz, M, Kiss, F, Kamenetzky, L, Brehm, K, Rosenzvit, MC, Córsico, B and Franchini, GR (2020) Fatty acid-binding proteins in Echinococcus spp.: the family has grown. Parasitology Research 119, 14011408.CrossRefGoogle ScholarPubMed
Ritler, D, Rufener, R, Li, JV, Kämpfer, U, Müller, J, Bühr, C, Schürch, S and Lundström-Stadelmann, B (2019) In vitro metabolomic footprint of the Echinococcus multilocularis metacestode. Scientific Reports 9, 19438.CrossRefGoogle ScholarPubMed
Sapp, SGH and Bradbury, RS (2020) The forgotten exotic tapeworms: a review of uncommon zoonotic Cyclophyllidea. Parasitology 147, 533558.CrossRefGoogle ScholarPubMed
Schantz, PM, Van den Bossche, H and Eckert, J (1982) Chemotherapy for larval echinococcosis in animals and humans: report of a workshop. Zeitschrift für Parasitenkunde 67, 526.CrossRefGoogle ScholarPubMed
Spiliotis, M and Brehm, K (2009) Axenic in vitro cultivation of Echinococcus multilocularis metacestode vesicles and the generation of primary cell cultures. Methods in Molecular Biology 470, 245262.CrossRefGoogle ScholarPubMed
Tamarozzi, F, Deplazes, P and Casulli, A (2020) Reinventing the wheel of Echinococcus granulosus sensu lato transmission to humans. Trends in Parasitology 36, 427434.CrossRefGoogle ScholarPubMed
Torgerson, PR, Robertson, LJ, Enemark, HL, Foehr, J, van der Giessen, JWB, Kapel, CMO, Klun, I and Trevisan, C (2020) Source attribution of human echinococcosis: a systematic review and meta-analysis. PLoS Neglected Tropical Diseases 14, e0008382.CrossRefGoogle ScholarPubMed
Tsai, IJ, Zarowiecki, M, Holroyd, N, Garciarrubio, A, Sánchez-Flores, A, Brooks, KL, Tracey, A, Bobes, RJ, Fragoso, G, Sciutto, E, Aslett, M, Beasley, H, Bennett, HM, Cai, X, Camicia, F, Clark, R, Cucher, M, De Silva, N, Day, TA, Deplazes, P, Estrada, K, Fernández, C, Holland, PWH, Hou, J, Hu, S, Huckvale, T, Hung, SS, Kamenetzky, L, Keane, JA, Kiss, F, Koziol, U, Lambert, O, Liu, K, Luo, X, Luo, Y, Macchiaroli, N, Nichol, S, Paps, J, Parkinson, J, Pouchkina-Stantcheva, N, Riddiford, N, Rosenzvit, M, Salinas, G, Wasmuth, JD, Zamanian, M, Zheng, Y; Taenia solium Genome Consortium, Cai, J, Soberón, X, Olson, PD, Laclette, JP, Brehm, K and Berriman, M (2013) The genomes of four tapeworm species reveal adaptations to parasitism. Nature 496, 5763.CrossRefGoogle ScholarPubMed
Vural, G, Yardimci, M, Kocak, M, Yasar, , Kurt, A, Harem, IS, Carradori, S, Sciamanna, I, Siles-Lucas, M, Fabiani, M, Hemphill, A, Lundström-Stadelmann, B, Cirilli, R and Casulli, A (2020) Efficacy of novel albendazole salt formulations against secondary cystic echinococcosis in experimentally infected mice. Parasitology 147, 1425–1143.CrossRefGoogle ScholarPubMed
Xu, S, Duan, L, Zhang, H, Xu, B, Chen, J, Hu, W, Gui, W, Huang, F, Wang, X, Dang, Z and Zhao, Y (2019) In vitro efficacies of solubility-improved mebendazole derivatives against Echinococcus multilocularis. Parasitology 146, 12561262.CrossRefGoogle ScholarPubMed
Yang, C, He, J, Yang, X and Wang, W (2019) Surgical approaches for definitive treatment of hepatic alveolar echinococcosis: results of a survey in 178 patients. Parasitology 146, 14141420.CrossRefGoogle ScholarPubMed
Zheng, H, Zhang, W, Zhang, L, Zhang, Z, Li, J, Lu, G, Zhu, Y, Wang, Y, Huang, Y, Liu, J, Kang, H, Chen, J, Wang, L, Chen, A, Yu, S, Gao, Z, Jin, L, Gu, W, Wang, Z, Zhao, L, Shi, B, Wen, H, Lin, R, Jones, MK, Brejova, B, Vinar, T, Zhao, G, McManus, DP, Chen, Z, Zhou, Y and Wang, S (2013) The genome of the hydatid tapeworm Echinococcus granulosus. Nature Genetics 45, 11681175.CrossRefGoogle ScholarPubMed
Zhou, X, Wang, W, Cui, F, Shi, C, Ma, Y, Yu, Y, Zhao, W and Zhao, J (2019) Extracellular vesicles derived from Echinococcus granulosus hydatid cyst fluid from patients: isolation, characterization and evaluation of immunomodulatory functions on T cells. International Journal for Parasitology 49, 10291037.CrossRefGoogle ScholarPubMed