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VACCINES FOR GASTROINTESTINAL PARASITES, A PILLAR OF PREVENTIVE MEDICINE IN VETERINARY PRACTICE: SYSTEMATIC REVIEW
VACUNAS PARA PARÁSITOS GASTROINTESTINALES, UN PILAR DE LA MEDICINA PREVENTIVA EN LA PRÁCTICA VETERINARIA: REVISIÓN SISTEMÁTICA
Revista de Investigación Agraria y Ambiental, vol. 13, no. 1, pp. 221-251, 2022
Universidad Nacional Abierta y a Distancia

ÁREA PECUARIA

Revista de Investigación Agraria y Ambiental
Universidad Nacional Abierta y a Distancia, Colombia
ISSN: 2145-6097
ISSN-e: 2145-6453
Periodicity: Semestral
vol. 13, no. 1, 2022

Received: 24 February 2021

Accepted: 02 June 2021

Published: 21 December 2021

Funding

Funding source: MCTI/CNPQ/FNDCT Program

Contract number: Contract no. 5737862008; Transversal Action Regional Research Networks in Ecosystems, Biodiversity and Biotechnology no 79/2013 (RENORBIO)

Award recipient: VACCINES FOR GASTROINTESTINAL PARASITES, A PILLAR OF PREVENTIVE MEDICINE IN VETERINARY PRACTICE: SYSTEMATIC REVIEW

https://hemeroteca.unad.edu.co/index.php/riaa/about

This work is licensed under Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International.

CÓMO CITAR: Vargas, L., Prieto, L., Baquero, M., Corredor, W., Alcantara-Neves, N. and Jaramillo-Hernández, D. (2022). Vaccines for gastrointestinal parasites, a pillar of preventive medicine in veterinary practice: Systematic review. Revista de Investigación Agraria y Ambiental, 13(1), 221 – 251. https://doi.org/10.22490/21456453.4544

Abstract: Contextualization: The antiparasitic resistance caused by the indiscriminate use of anthelmintic drugs for the control of gastrointestinal parasites in production animals and pets, has become one of the biggest problems in animal health. For this reason, the use of vaccines could benefit animal health and welfare by controlling emerging zoonotic diseases and foodborne pathogens of animal origin, thus improving public health.

Knowledge gap: It is relevant for professionals in veterinary science to know the clinical trials of experimental vaccines for controlling certain gastrointestinal parasites. This way, they can be at the forefront of the next available technological products and so, be able to control this menace to the animal health and public health.

Purpose: To do a systematic review of clinical trials for experimental vaccines in production animals and pets for diseases caused by gastrointestinal parasites of relevance in animal production and/or public health. Furthermore, it presents the current gastrointestinal antiparasitic vaccines commercialized in different countries and their prophylactic efficacy.

Methodology: PRISMA protocols were followed for this systematic review. Articles were obtained from scientific databases with the following keywords: vaccines, clinical trials, commercial vaccines, parasites control, gastrointestinal nematodes, gastrointestinal cestodes, gastrointestinal protozoa, Ascaris suum, Ancylostoma caninum, Cooperia oncophora, Echinococcus granulosus, Eimeria spp., Giardia lamblia, Haemonchus contortus, Osteortagia osteortagi, Taenia solium and Teladorsagia circumcincta. Only clinical trials of gastrointestinal antiparasitic vaccines in birds, pets, pigs and ruminants were included in this analysis, as well as commercial vaccines currently available for these same parasites.

Results and conclusions: Even though there are important clinical trial studies of vaccines in these animal species (n=101) reported between 1964 to 2020, only five parasites can be prevented/controlled with commercial vaccines used in veterinary medicine: Haemonchus contortus and Echinococcus granulosus in ruminants, Taenia solium in pigs, Eimeria spp. in birds and Giardia lamblia in dogs (e.g., Cysvax™, Barbervax®, Providean® Hidatil EG95, CocciVac® and GiardiaVax™). It is expected that, with the development of bioinformatics and methodologies such as reverse vaccinology, this immunoprophylactic and immunotherapeutic range will be extended as to control these parasitic agents of great importance in human and animal health.

Keywords: clinical trial, immunoprophylaxis, gastrointestinal parasites, vaccination.

Resumen: Contextualización: La resistencia a los antiparasitarios provocada por el uso indiscriminado de antihelmínticos, para el control de parásitos gastrointestinales en animales de producción y mascotas, se ha convertido en uno de los mayores problemas en salud animal y pública. Por esta razón, el uso de vacunas podría beneficiar la salud y el bienestar de los animales al controlar las enfermedades zoonóticas y los patógenos de origen animal transmitidos por los alimentos.

Vacío del conocimiento: Es relevante para los profesionales en ciencias veterinarias conocer los estudios clínicos de vacunas experimentales para el control de ciertos parásitos gastrointestinales y de esta forma, estar a la vanguardia de próximos productos tecnológicos disponibles.

Propósito: Revisar sistemáticamente resultados de ensayos clínicos de vacunas experimentales en diferentes especies animales de producción y compañía, para parásitos gastrointestinales de relevancia en la producción animal y/o salud pública. Además, presentar el estado del arte de las vacunas antiparasitarias gastrointestinales comercializadas en diferentes países y su eficacia profiláctica respectiva.

Metodología: En esta revisión sistemática siguió la metodología del protocolo PRISMA. Se obtuvieron artículos de bases de datos científicas con las siguientes palabras clave: vacunas, ensayos clínicos, vacunas comerciales, control de parásitos, nematodos gastrointestinales, cestodos gastrointestinales, protozoos gastrointestinales, Ascaris suum, Ancylostoma caninum, Cooperia oncophora, Echinococcus granulosus, Eimeria spp., Giardia lamblia, Haemonchus contortus, Osteortagia osteortagi, Taenia solium y Teladorsagia circumcincta. En este análisis solo se incluyeron ensayos clínicos de vacunas antiparasitarias gastrointestinales en aves, mascotas, cerdos y rumiantes, así como vacunas comerciales actualmente disponibles para estos mismos parásitos.

Resultados y conclusiones: Aunque existen importantes estudios de ensayos clínicos de vacunas en estas especies animales (n=101) reportados entre 1964 y 2020, solo cinco parásitos pueden prevenirse/controlarse con vacunas comerciales utilizadas en medicina veterinaria: Haemonchus contortus y Echinococcus granulosus en rumiantes, Taenia solium en cerdos, Eimeria spp. en aves y Giardia lamblia en perros (por ejemplo, Cysvax™, Barbervax®, Providean® Hidatil EG95, CocciVac® y GiardiaVax™). Se espera que, con el desarrollo de la bioinformática y metodologías como la vacunología inversa, este abanico inmunoprofiláctico e inmunoterapéutico se amplíe en el control de estos agentes parasitarios de gran importancia en la salud humana y animal.

Palabras clave: Ensayo clínico, inmunoprofilaxis, parásitos gastrointestinales, vacunación.

GRAPHIC ABSTRACT




authors

1. INTRODUCTION

Is urgent to develop vaccines against parasites for domestic animals because of: 1) resistance of parasites to conventional pharmacological treatments; 2) lack of effective anti-parasitic drugs and 3) the presence of chemical residues in products for human consumption (Emery et al., 1993; Woods et al., 2011).

Diseases associated with gastrointestinal parasites are responsible for severe negative economic impacts in animal production, mainly for productive and reproductive losses (Sharma et al., 2015). Parasitic infestations affect animal production in terms of health and welfare, for this reason, control measures should be implemented to reduce or mitigate this impact. The use of vaccines could benefit animal health and welfare by controlling emerging zoonotic diseases and foodborne pathogens of animal origin, thus improving public health (Corwin, 1997; Innes et al., 2011).

It is relevant for professionals in veterinary science to know the clinical trials of experimental vaccines for the control of certain gastrointestinal parasites and, in this way, to be at the forefront of the next available technological products to control this thread to the animal health and public health. On the other hand, the usual veterinary medical practice has important gaps in the commercial offer of antiparasitic vaccines for the control of gastrointestinal parasites in production animals and pets.

Experimental vaccines offer an alternative to prevent animal intestinal parasites by implementing recombinant proteins to efficiently promote immuno-protective responses. These vaccines have been classified as 1) hidden antigens (i.e., those not recognized by the host’s immune system), that are generally found in the parasite's intestine and 2) natural antigens, which are expressed during the infection process and identified by the host (Jenkins, 2001; Newton et al., 2003).

This manuscript aims to review results of clinical trials for experimental vaccines (in different production animals and pets) to prevent certain diseases caused by gastrointestinal parasites that affect animal production and /or public health. Furthermore, this research presents the state of the art of gastrointestinal antiparasitic vaccines commercialized in different countries and their prophylactic efficacy.

2. METHODOLOGY

This systematic review followed the PRISMA protocols (Moher et al., 2009). In general terms, a bibliographic search that identified possible articles for their inclusion, based on search keywords and pre-established inclusion criteria, was developed. This process is presented through the figure 1, PRISMA flow chart.


Figure 1
PRISMA flow diagram
authors

Search strategy for study identification

The search was based on four scientific platforms: PubMed (http://www.ncbi.nlm.nih.gov/pubmed/), Science Direct http://www.sciencedirect.com/), Scientific Electronic Library Online (SciELO: https://scielo.org/en) and Scholar Google (Scholar Google: https://scholar.google.com/). The keywords used for identifying the potential articles were: vaccines, clinical trials, commercial vaccines, parasites control, gastrointestinal nematodes, gastrointestinal cestodes, gastrointestinal protozoa, Ascaris suum, Ancylostoma caninum, Cooperia oncophora, Echinococcus granulosus, Eimeria spp., Giardia lamblia, Haemonchus contortus, Osteortagia osteortagi, Taenia solium and Teladorsagia circumcincta.

Eligibility criteria

We used the following inclusion criteria: 1. Only specific articles about these parasites that are harmful for production animals or pets, as well as their impact on public health: nematodes (Haemonchus contortus, Teladorsagia circumcincta, Osteortagia osteortagi, Cooperia oncophora, Ancylostoma caninum and Ascaris suum); cestodes (Taenia solium and Echinococcus granulosus); protozoa (Giardia lamblia and Eimeria spp.). 2. Clinical trials of gastrointestinal antiparasitic vaccines for the mentioned parasites in birds, pets, pigs, and ruminants; 3. Commercial vaccines currently available for these same parasites[1].

Data screening

The authors, divided in two working groups, read the titles, and in many cases, the abstracts of the articles retrieved from the databases consulted, according to keywords, and saved those that reported experimental studies of gastrointestinal antiparasitic vaccines in selected animal species (animal species for which the respective vaccine has been developed).

After the comparison of information between the two working groups, the articles chosen were read, then were included in the timeline reports of clinical trials (temporal analysis of the trials), and the data obtained by those in terms of levels of protection, for the parasitosis studied, were analyzed. It is important to clarify that, only two protozoa (Giardia lamblia and Eimeria spp.) were included in this study, given their importance for children’s health and their drastic effects on poultry production (Bartelt & Platts-Mills, 2016; Gilbert et al., 2020). On the other hand, technical-commercial information is linked and extracted from the web pages of the pharmaceutical companies that produce the commercial antiparasitic vaccines discussed in this systematic review.

The other gastrointestinal parasites are mostly cestodes and nematodes. The last ones are the most studied because efficient mechanisms of prophylactic to control them, supported by vaccines, have been researched (Stutzer et al., 2018; Anvari et al., 2020; Britton et al., 2020; Ehsan et al., 2020; Sander et al., 2020). Regarding this, even though Toxocara spp. is a nematode with important effects on world public health in developed and developing countries, there are no clinical trials of vaccines for its control in canines (Jaramillo-Hernández et al., 2020).

3. RESULTS AND DISCUSSION

According to the search parameters initially proposed, a total of 1162 articles were found in the databases used in this study. Of those, 504 were repeated and were immediately separated. Subsequently, the remaining 667 scientific studies were reviewed to establish compliance with the inclusion and exclusion criteria pre-established. Only 164 articles, presumably, fulfilled some of the requirements.

After analyzing the results, it was established that 63 of these articles were studies about preclinical vaccine trials (e.g., using animal models of parasitic disease) or were studies in other parasites different from the interest of this study. So, in the end, a total of 101 articles about clinical phases of vaccine experimentation in poultry, pigs, ruminants, and pets (canines and felines) were included within the temporal analysis of experimentation and their antiparasitic protection. The period of the results reported is 1964 to 2020 (Figure 1).

The authors have presented these results by animal species or group of animal species (e.g., large and small ruminants), given the species-specific implications of the gastrointestinal parasites treated in this study. The results are organized under the subtitle “Advances in the development of vaccines for the control of gastrointestinal parasites in (…)”. Likewise, the figure2 shows a time series of crucial experimental clinical studies that have determined the advances in prophylaxis and immunotherapy for the gastrointestinal parasite control in veterinary medicine. In the same way, under the subtitle "Gastrointestinal deworming vaccines currently commercialized in veterinary medicine", the existing commercial vaccines for the control of these gastrointestinal parasites were presented.


Figure 2
Timelines of clinical studies for the control of gastrointestinal parasites with their respective vaccines. This figure shows the animal species of interest; the year in which the study was executed; type of vaccine (antigen plus adjuvant) used; and the parasite to be controlled or eradicated and the country

Figure 2A: Timeline of the main clinical studies in large and small ruminant’s main timeline.

Authors




Figure 2B: Timeline of the main clinical studies in dogs.

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Figure 2C: Timeline of the main clinical studies in birds.

Authors




Figure 2D: Timeline of the main clinical studies in pigs.

Authors

Advances in the development of vaccines for the control of gastrointestinal parasites in domestic ruminants

Large and small grazing ruminants are continuously exposed to nematode infections. On the other hand, nematodes develop resistance to medicines, due to continuous anthelmintic treatments; this limits livestock production and represents a constant threat to animal welfare (Knox, 2000; Knox et al., 2003). The most important gastrointestinal parasites in ruminants are Haemonchus contortus (H. contortus) and Teladorsagia circumcincta (T. circumcincta) in sheep; Osteortagia osteortagi (O. ostertagi) and Cooperia oncophora (C. oncophora) in cattle. Due to the high cost of treatments and the potential anthelmintic resistance, a significant effort has been carried out in the discovery of vaccine candidates for parasite control (Dalton et al., 2001; Matthews et al., 2016). Table 1 summarizes a series of clinical trials in different experimental or production stages for gastrointestinal parasite control in ruminants.

Table 1
Clinical trials of experimental vaccines for the gastrointestinal parasites control in large and small ruminants

Authors nASP: Native secreted protein associated with ASP1 activation, QuilA®: Adjuvant saponin, Al(OH)3: Aluminum hydroxide, DS: Dextran sulfate, H-gal-GP: Digestive protease glycoprotein complex, H11: Hc isolated integral intestinal membrane protein, CEF: Contortin-enriched fraction, rHc23: Recombinant somatic Hc protein, P46+P52: Hc apical intestinal surface protein, nOPA: Native purified antigen of Osteortagia osteortagi polyprotein, ES-thiol: Cysteine proteinase enriched fraction, EPG: Eggs for gram feces; IM: Intramuscular, SC: Subcutaneous, PBS: phosphate buffered saline, dd-ASP: double domain ASP protein, ESP: larval excretory-secretary products of Oesophagostomum radiatum, IP: Intraperitoneal, L4: Larval stage 4 of Oesophagostomum radiatum, WHG: H. placei whole gut homogenate, EPG: eggs per gram of feces, CFA: Complete Freund's adjuvant, IFA: Incomplete Freund's Adjuvant. (↓): low dose, (↑): high dose, (-): not data available.

Several hidden intestinal antigens have been found in animals to confer protection against H. contortus. The hidden intestinal antigen digestive protease glycoprotein complex (H-gal-GP) was effective in protecting sheep against H. contortus, by decreasing parasitic loads in 70 %, with a decrease in fecal egg count (FEC) of 90 %, in several clinical trials (Smith et al., 1994; Smith & Smith, 1996; Knox & Smith, 2001). Another H. contortus antigen, that has played an important role in clinical studies, is in the hidden integral intestinal membrane. This protein was isolated from H. contortus (H11 antigen). This antigen has proved to bind specific antibodies that disable the enzymatic activity of the antigen, showing a 90 % reduction in FEC and a 75 % drop in the presence of adult H. contortus in the abomasum of immunized sheep (Newton & Munn, 1999).

Based on these results and with new technologies available to obtain antigens, (Vercruysse et al., 2018), it seems that vaccines composed by several antigens of the same nematode species promote a more intense and long-lasting protection against the specific parasite, avoiding a potential adaptation of these parasites to the administered vaccine (Claerebout & Geldhof, 2020).

In the last decade, efforts have been made to develop vaccines for T. circumcincta, an important parasite that affects small ruminants, causing gastroenteritis, and a reduction in weight gain (Nisbet et al., 2013; Matthews et al., 2016). An immunoprophylactic study against this nematode was performed in sheep in the last third of gestation and in grazing lambs (in-situ), where they were inoculated with a combination of recombinant proteins (Tci-ASP-1; Tci-MIF-1; Tci-TGH-2; Tci-APY-1; Tci-SAA-1; Tci-CF1; Tci-ES20; Tci-MEP-1), resulting in a 45 % decrease in the FEC (Nisbet et al., 2016).

The parasite of abomasum, O. ostertagi, and the small intestinal parasite, C. oncophora, are the nematodes that affect prevalently grazing cattle in the tropics. The vaccines studied against these parasites has showed the following results: Calves that were vaccinated with an O. ostertagi excretory-secretory antigen fraction, enriched with cysteine proteinase (ES-thiol) activity, and the adjuvant Quil-A®, indicated that a protective immune response against O. ostertagi was induced, which was reflected by a reduction in FEC from 56 to 60 % (Geldhof et al., 2004; Meyvis et al., 2007). The administration of an ASP-based vaccine against O. ostertagi (a double-domain ASP protein-dd-ASP, purified from excretory/secretory material of C. oncophora larvae) showed successful results and has been considered a vaccine candidate (Borloo et al., 2013).

Echinococcus granulosus (E. granulosus), a canine intestinal cestode, is the causative agent of human hydatidosis, which also affects several intermediate hosts (such as sheep, cattle, camelids, and horses). This zoonotic disease causes significant economic losses and public health concerns in many countries (Lightowlers et al., 1999; Dalimi et al., 2002). To advance in the control of this parasitic agent, a vaccine that contains a recombinant antigen belonging to the oncosphere of the E. granulosus, called EG95, has been developed (Larrieu et al., 2015; Larrieu et al., 2019). With this antigen, a protection of 96-98 % with respect to the parasitic load was obtained (Lightowlers et al., 1996).

A study was executed in which cattle were immunized with EG95, and with Quil-A® as adjuvant, finding a protection of 90 % of the immunized animals for 12 months (Heath et al., 2012). These results suggest that the vaccine from the EG95 antigen could have a wide applicability as a tool to control hydatidosis (Lightowlers et al., 1999). However, it cannot be overlooked that the vaccine should be used in combination with other control measures, such as health education, control of slaughter, and canine deworming; for more favorable results (Anvari et al., 2020).

Advances in the development of vaccines for the control of gastrointestinal parasites in pets (dogs and cats)

Some of the parasitic diseases of pets (dogs and cats) are highly zoonotic. For this reason, a significant effort for developing clinical trials, to find a solution that prevents high rates of animal-human contagion has been done (Hotez et al., 1996). Table 2 presents several clinical immunoassays for the control of gastrointestinal parasites in pets, especially against the hookworm Ancylostoma caninum (A. caninum), one of the main causative agents of anemia and malnutrition in dogs and in humans in the less developed countries of the tropics (Ghosh et al., 1996).

In 1973, a vaccine prepared from larvae (L3) of A. caninum, irradiated with Roentgen rays, was commercialized, resulting in 90 % of protection (associated to the reduction of the parasitic load). The distribution of this vaccine was interrupted two years later, due to limitations that included price, supply, and stability of protection (Miller, 1964; Boag et al., 2003). After that, a clinical trial with dogs immunized with Ac-ASP-2 (catalytically active cysteine protease [Ac] and proteins secreted from Ancylostoma larvae [ASP]) showed a significant reduction in the FEC and in the load of adult hookworm parasites in the intestine (Fujiwara et al., 2006).

Table 2
Clinical trials of experimental vaccines for the control of gastrointestinal parasites in companion animals

Authors Ac-16: Immunodominant antigen of A. caninum, ASO3®: Oil in water emulsion, EgTrp+EgA3: Recombinant adult A. caninum worm proteins, Ac-cp-2: Catalytically active cysteine protease, ASO2A®: Oleaceous emulsion of L3 irradiated with X (irradiated larvae of A. caninum), Ac-APR1: Aspartate protease of A. caninum, EPG: Eggs for gram feces; IM: Intramuscular, SC: Subcutaneous, EgM4, EgM9 and EgM123: Recombinant purified soluble fusion proteins of E. granulosus. CFA: Complete Freund's adjuvant; IFA: Incomplete Freund's Adjuvant, GST: Glutathione S-transferase, PO: Per os, PSCs: Soluble proteins from E. granulosus protoscolls, RP: Recombinant protein, (-): not data available.

Cystic echinococcosis caused by the cestode E. granulosus, also called hydatidosis, represents a concerning problem in public health and livestock, mainly in developing countries (Budke et al., 2006; Petavy et al., 2008). During its adult stage, this parasite locates in the small intestine of dogs, where it grows and can migrate to other organs such as liver and lungs (Grosso et al., 2012). In a classical vaccination study, a new approach for the immunization of dogs against E. granulosus was performed using secretory antigens derived from adult tapeworms grown in-vitro, which induced a significant decrease in the FEC of E. granulosus in immunized canines (Herd et al., 1975).

Advances in the development of vaccines for the control of gastrointestinal parasites in birds

The poultry industry has evolved significantly around the world, and the first-generation of experimental vaccines have been developed against diseases caused by protozoa, such as Eimeria spp. coccidiosis diseases (Vercruysse et al., 2004). These diseases affect intestinal epithelial cells, causing considerable weight reductions due to reduced food consumption and malabsorption. In addition, the continuous administration of coccidiostats generates adaptation of the parasites, making it a constant problem in the poultry industry (Jenkins, 2001; McDonald & Shirley, 2009). In Table 3, a series of clinical immunoassays for the control of gastrointestinal parasites (specifically for Eimeria spp.) in birds are summarized.

Table 3
Clinical trials of experimental vaccines for gastrointestinal parasites control in birds

Authors PcDNA-TA4-IL-2: DNA fusion vaccine co-expressed in E. tenella, PcDNA: DNA fusion vaccine, Gam56: Recombinant plasmid from E. maxima, EtMIC2: Recombinant microneme gene from E. tenella, pMP13: Preserved antigen of E. tenella, pVAX-LDH-IFN-γ: Recombinant antigen plasmid of E. acervuline, Raw gametocyte extract, IM: Intramuscular, SC: Subcutaneous, APGA: gametocyte antigens purified by affinity, RHMR1: rhomboid-like gene, CFA: Complete Freund's adjuvant, IFA: Complete Freund's adjuvant, PBS: phosphate-buffered saline, TE: buffer solution commonly used in molecular biology, Mex: raw extract of merozoite, OoNex: raw extract of non-sporulated oocysts, OoSex: crude extract of sporulated oocysts.

During the 1950s, the first vaccines against E. tenella were marketed using live sporulated oocysts (Soutter et al., 2020). Due to the economic relevance of avian coccidiosis, a series of commercial vaccines from different companies have been commercialized (Williams, 2002). In the last decades, a special focus has been made to manipulate recombinant DNA antigens from different stages of growth of the Eimeria spp., based on the fact that metabolic and reproductive processes are essential for its permanence in their hosts change during the life cycle of the parasite (Jenkins, 1998; Vermeulen, 1998).Likewise, the identification of different antigens with a high potential for its use in these vaccines is increasingly important for the target market (Blake et al., 2017; Soutter et al., 2020).

Advances in the development of vaccines for the control of gastrointestinal parasites in pigs

A major advance has been made by the pig industry over the past five decades, supported by genetic improvement. The continuous treatments for the control of gastrointestinal parasites remains conventional, and thus developing anti-parasite resistance and worsening public health problems. Therefore, several research groups have made important efforts to develop vaccines for the control of the main parasites of pigs with public health implications (Table 4).

An example of these advances is the control of Taenia solium (T. solium), which is a common cestode in pig breeding areas and is the main cause of human cysticercosis, an important neurological disease of global public health, with the pig as the intermediate host. This zoonotic pathology is associated with human population areas of scarce economic resources where pigs roam freely, consolidating the transmission of the parasite from pigs to humans. Most attempts to control the parasite transmission have been ineffective and unsustainable (Verastegui et al., 2002; Gauci et al., 2012) with some exceptions of success in specific geographic areas, which have linked comprehensive community actions based on vaccination schemes and conventional antiparasitic management (Garcia et al., 2016).

Table 4
Clinical trials of experimental vaccines for the gastrointestinal parasites control in pigs.

Authors TSOL18. TSOL45. TSOL16: Antigens from Taenia solium oncosphere, 45WB/X-GST. 16K-GST. 18K-GST: Recombinant proteins from T. ovis, S3Pvac: Anti-cysticercus triple-peptide synthetic vaccine, GST: Glutathione S-transferase, IM: Intramuscular, SC: Subcutaneous, AsHb: Ascaris suum purified hemoglobin, Quil-A®: Adjuvant saponin, PBS: phosphate-buffered saline, MPB: maltose-binding protein, CFA: Complete Freund's adjuvant, IFA: Incomplete Freund's adjuvant.

Researchs to development effective vaccines against this disease have been taking place. Thus, several works were generated about the promising vaccine candidate: TSOL18 antigen. A research, using this recombinant antigen, detected high levels of antibodies in immunized pigs, possibly associated to the protection against T. solium, which evidenced a 94 % - 100 % reduction in the loads of meta-cestoids (Cai et al., 2007). Furthermore, an investigation found that the recombinant proteins TSOL18 and TSOL45-1A induced more than 97 % of protection (in independent vaccine trials) against an experimental infection with T. solium eggs in pigs (Kyngdon et al., 2006). In summary, these three antigens (TSOL16, TSOL18 and TSOL45) induce high levels of protection into the immunized pigs; however, it has been demonstrated that TSOL18 antigen has been the most effective in field conditions (in situ) to stop the parasitic agent transmission (Garcia et al., 2016).

A synthetic S3Pvac vaccine, consisting of three peptides (GK1, KETc1 and KETc12), to prevent the transmission of T. solium was shown to be successful (De Aluja et al., 2005). This S3Pvac vaccine caused a 50 % reduction of the parasitic load and, in the case of cysticercus, a reduction of 98 % in immunized pigs (Sciutto et al., 2008). It has been demonstrated that immunization with S3Pvac is effective for preventing porcine cysticercosis; however, its effectiveness is still limited to reduce the prevalence of the cestode, besides its high manufacturing costs (Sciutto et al., 2013).

Another gastrointestinal parasite of great concern for pig production systems is Ascaris suum (A. suum), which is usually located in the small intestine of its host and migrates to different organs before its destination, causing significant tissue damage (Masure et al., 2013). Because of this migratory capacity, it is responsible for high rates of animal morbidity and considerable economic losses in pig productions; besides is a very relevant agent in zoonotic geohelminth infection (Tsuji et al., 2003). Several clinical studies of vaccine experimentation have been carried out to study immunoprophylaxis as a control strategy of this parasite in pigs. The inoculation of 10000 irradiated A. suum eggs resulted in a reduction of 88 % of A. suum larvae. The parasite was extracted post-mortem from the inoculated pigs (Urban & Tromba, 1982).

Gastrointestinal deworming vaccines currently commercialized in veterinary medicine

Over the years, vaccines containing different antigens and adjuvants have been developed, which help to reduce the damage generated by the presence of gastrointestinal parasites in animal production systems, and to animal and human health (Meeusen et al., 2007). This has provoked an extensive work by researchers, to generate effective vaccines that fulfill the needs of producers opportunely, and be economically viable (Redding & Weiner, 2009). Currently research on helminth vaccines has produced successful results, and has been characterized for using innovative technologies, but their commercialization is limited, leading to a reduction in the production (Hein & Harrison, 2005).

Since 2014, the first vaccine for gastrointestinal nematode control in ruminants is in the market. It is an antigenic subunit vaccine, based on hidden native intestinal membrane antigens obtained from adult H. contortus (Jacob et al., 2013). The vaccine compounds are the glycoproteins complex of aspartyl and metallo-proteases (H-gal-GP), and a family of leucine aminopeptidases (H11); associated to an adjuvant of saponin nature. The adjuvant commercial name is Quil-A®. This vaccine is commercialized for the control of haemonchosis in sheep (with some successful research studies in goats, alpacas, among other ruminants); its release was carried out in Australia, where the vaccine was named as Barbervax® (Wormvax, Australia Pty Ltd) (Preston et al., 2015; Matthews et al., 2016). Barbervax® is available in South Africa, where it is known as Wirevax®, and in the United Kingdom it is sold only under veterinarian’s prescriptions ( http://barbervax.com.au/). By 2018, its respective commercial registration was obtained in New Zealand and Europe.

The vaccine for controlling hydatidosis (Echinococcus granulosus) in its intermediate hosts (sheep, goats, cattle, pigs, and camelids) was the first commercial vaccine for the control of gastrointestinal cestodes (Claerebout & Geldhof, 2020). It is based in a recombinant antigen and is in the market since 2006 as Providean® Hydatil EG95 (Tecnovax, Buenos Aires, Argentina). This vaccine is based on the EG95 mature oncosphere antigen (cloned from the respective gene in a plasmid vector) expressed in E. coli K12BB4-pGex-3Ex, and then associated to an oil adjuvant: Montanide ISA 70® (Matthews et al., 2016). The benefit of this vaccine is that by controlling the infection in its intermediate hosts, its definitive host (dogs) hardly come in contact with the hydatid cysts generated by E. granulosus, interrupting its life cycle. Humans are accidental host of this parasite, and the mechanism of action of this vaccine highly diminishes the probability of contamination, exerting a beneficial effect on public health in an indirect way (Tecnovax, n.d.) (Jacob et al., 2013).

In 1999, Fort Dodge Laboratories (USA) launched a vaccine called GiardiaVax™, generated from chemically inactivated trophozoites of the protozoan G. lamblia (syn. G. duodenalis or G. intestinalis). This protozoon is the main causative agent of diarrhea in global children population, because its cysts are expelled to the environment through the feces of pets (and wild species of dogs and cats) and can reach humans through the oral route (Meeusen et al., 2007; Payne & Artzer, 2009; Molina, 2017). The vaccine contributed to the reduction and impact of cyst expulsion from the protozoan G. lamblia in canine feces, and prevented giardiasis (Meeusen et al., 2007). Ten years after its commercial release, Fort Dodge Laboratories stopped the production of GiardiaVax™ because of its low efficacy (Molina, 2017). Paradoxically, this same vaccine is commercialized still in some countries of the American continent, such as in the United States, Brazil, and Argentina, by other laboratory: Zoetis (Australia PTY LTD) for its use in dogs (Zoetis, 2013).

In 1951, the first commercial vaccine against avian coccidiosis was recognized and, until today, several series of vaccines have been commercialized for controlling this disease in different species of production birds (commercial laying hens, broilers, breeders, turkeys, among others) (Li et al., 2012). Thus, the first commercial vaccine for the control of Eimeria spp. (cause of avian coccidiosis) was the live vaccine named CocciVac®-D (Schering Plough Animal Health, USA) formulated with a series of low doses of oocysts from eight different Eimeria species (E. tenella, E. maxima, E. mivati, E. acervulina, E. brunetti, E. hagani, E. necatrix and E. praecox) to be administered in birds.

This same commercial line of vaccines (Merck Animal Health, n.d.), one year later was called CocciVac®-D2 (MSD, Kenilworth, NJ, USA). Is similar in its antigenic content to the previous one, but have been modified by reducing the oocyst doses of the eight Eimeria spp. that have not been transformed to modulate their pathogenicity (Peek and Landman, 2011). Furthermore, in the same vaccine production path, years later appeared CocciVac®-B (MSD, Kenilworth, NJ, USA), which is formulated for broilers, composed by four Eimeria species (E. acervulina, E. maxima, E. mivati and E. tenella) (Reid, 1990); and Coccivac®-B52 (Intervet Inc, through Merk animal health), which prevents infection by E. mivati and E. tenella, in addition to reducing injuries caused by E. acervulina and E. maxima in broilers (Merck Animal Health, n.d).

In 1985, Vetech Laboratories Inc. in Canada started to commercialize a vaccine for the control of Eimeria spp. called Immucox® (https://www.immucox.com/Range), developed in Ceva Animal Health (Cambridge, ON). It has been evolving year by year and, until today, it has developed three commercial vaccines under the precept of live sporulated oocysts (via oral administration) at low doses for this kind of birds: 1) for broilers: Immucox®3 (E. acervulina, E. maxima and E. tenella); 2) for broilers and laying hens: Immucox®5 (E. acervulina, E. maxima, E. tenella, E. necatrix and E. brunetti) and 3) for turkeys: ImmucoxT® (E. adenoids and E. meleagrimitis).

In addition, in 1989, the live attenuated vaccine Paracox® was launched by Schering Plough Animal Health in the United Kingdom. Later, in association with Intervet UK Ltd-MSD animal health (MSD Animal Health, n.d), generated two new commercial vaccines under the same technological precept: 1) Paracox®8, which is formulated with different low doses of oocysts from seven different Eimeria species (E. acervulina, E. brunetti, E. maxima, E. mitis, E. necatrix, E. praecox and E. tenella), it is indicated for broilers, laying hens and reproducers. 2) Paracox®5, which is formulated with four different Eimeria spp. (E. acervulina, E. maxima, E. mitis and E. tenella). These vaccines are called "8" and "5" respectively, even having only 7 and 4 Eimeria spp., since the attenuated field strain of E. maxima has two types ("attenuated line” (CP) and "mixed field strain precocious” (MFP)).

In 1992, the avian industry worldwide had a new possibility to control avian coccidiosis, based on the same trend of developing vaccines for the gastrointestinal pathogen Eimeria spp. Thus, BioPharm of the Czech Republic (https://www.bri.cz/en) released a new line of attenuated live vaccines called Livacox®, which offers two vaccines based on attenuated sporulated oocytes: Livacox®T (E. acervulina, E. máxima and E. tenella) and Livacox®Q (E. acervulina, E. máxima, E. necatrxi and E. tenella). The vaccines are indicated for broilers and reproducers laying hens, respectively.

Following the vaccines’ purpose of controlling avian coccidiosis (but using innovation and technology for its synthesis) it was promulgated in 2002 (by ABIC Biological Laboratories Teva Ltd in Israel (www.abic-vet.com)) the CoxAbic® vaccine (Novartis, AH). This vaccine has three subunits of antigenic proteins inactivated: 230kDa, 82 kDa, 56 kDa (also called gam230, gam82 and gam56, respectively), known as Affinity Purified Gametocyte Antigen (APGA). The proteins were isolated from the sexual-stage gametocytes of the protozoan E. maxima (these protein fractions are located around the wall-forming bodies -WFBs- of the macrogametocytes) (Li et al., 2012).

In the pig industry is important to stand out the efforts focused on controlling T. solium, a cestode of great zoonotic impact associated with cysticercosis disease in humans (Lightowlers & Donadeu, 2017). In 2016, the vaccine known as Cysvax™ was developed and launched by Indian Immunological Limited with the collaboration of various economic and technical sources, including the Global Alliance for Livestock Veterinary Medicines -GALVmed- (https://www.galvmed.org/). It is the first and only vaccine against cysticercosis based on TSOL18, which is a recombinant antigen from the oncosphere of the parasite, expressed in Pichia pastoris, and an oily adjuvant (Sciutto et al., 2013). This vaccine provides 100 % effectiveness and contributes to a significant decrease in the parasitic load of this cestode in pigs (Sepúlveda et al., 2020).

Finally, not just a positive effect on animal health, welfare and production, has been generated by veterinary vaccines; also on human health, confirming that the continuous exchange of knowledge between health researchers of these two matters, considering environmental interactions (One Health principle), is essential to address the always-present threat of problematic emerging diseases (Meeusen et al., 2007). Figure 3 shows the main commercial vaccines for controlling gastrointestinal parasites examined in this review, as well as their global distribution.


Figure 3
Vaccines marketed for the control of parasites in animals, according to their country of distribution. (A): countries where Providean® Hidatil EG95 is marketed, (A1): countries where Barbervax® is marketed, (A2): countries where Cysvax™ is marketed, (A3): countries where GiardiaVax™ is marketed and (A4): countries where Coccivax®, Immucox®, Livacox® and Paracox® are marketed.
Authors

4. CONCLUSIONS

The control of parasitic diseases played by vaccines is transcendental, particularly in animal production for human consumption. Like all other remedies, they must be endorsed by the competent entities (Heldens et al., 2008). However, the high costs of certain vaccines reduce the possibilities of commercialization, as ultimately users seek saving money, rather than quality (Schetters, 1995). Despite progress in experimental vaccine research, very few vaccines are promising to finally become commercialized (Schetters, 1995). In the future, changes in legislation are expected to provide subsidies for the manufacturing and marketing of commercial deworming vaccines (Schetters & Gravendyck, 2006), and it is expected to have available a range of immunoprophylactic and immunotherapeutic biologics importance for the control or even eradication of gastrointestinal parasites.

Vaccination is an effective alternative to prevent many diseases that affect animals species of veterinary interest. This has increased the levels of confidence in public health globally (Unnikrishnan et al., 2012) and has provided welfare to various animal species. Even so, and despite the scientific advances in the world, gastrointestinal parasitic infections persist; therefore, vaccination is recognized as one of the most viable and effective option for controlling these diseases. However, the development of preventive vaccines against these parasites has proven to be enormously difficult for scientific and economic reasons (Versteeg et al., 2019).

Acknowledgments

MCTI/CNPQ/FNDCT Program Contract no. 5737862008; Transversal Action Regional Research Networks in Ecosystems, Biodiversity and Biotechnology no 79/2013 (RENORBIO).

LITERATURA CITADA

Anvari, D., Rezaei, F., Ashouri, A., Rezaei, S., Majidiani, H., Pagheh, A. S., Rezaei, F., Shariatzadeh, S. A., Fotovati, A., Siyadatpanah, A., Gholami, S. & Ahmadpour, E. (2020). Current situation and future prospects of Echinococcus granulosus vaccine candidates: A systematic review. Transboundary and emerging diseases, 68(3), 1080-1096. https://doi.org/10.1111/tbed.13772

Assana, E., Kyngdon, C. T., Gauci, C. G., Geerts, S., Dorny, P., De Deken, R., Anderson, G. A., Zoli, A. P. & Lightowlers, M. W. (2010). Elimination of Taenia solium transmission to pigs in a field trial of the TSOL18 vaccine in Cameroon. International journal for Parasitology, 40(5), 515–519. https://doi.org/10.1016/j.ijpara.2010.01.006

Bartelt, L. A. & Platts-Mills, J. A. (2016). Giardia: a pathogen or commensal for children in high-prevalence settings? Current opinion in infectious diseases, 29(5), 502–507. https://doi.org/10.1097/QCO.0000000000000293

Blake, D. P., Pastor-Fernández, I., Nolan M. J. & Tomley, F. M. (2017). Recombinant anticoccidial vaccines - a cup half full? Infection, Genetics and Evolution, 55, 358–365. https://doi.org/10.1016/j.meegid.2017.10.009

Boag, P. R., Parsons, J. C., Presidente, P. J. A., Spithill, T. W. & Sexton, J. L. (2003). Characterisation of humoral immune responses in dogs vaccinated with irradiated Ancylostoma caninum. Veterinary immunology and immunopathology, 92(1-2), 87–94. https://doi.org/10.1016/s0165-2427(03)00006-0

Borloo, J., De Graef, J., Peelaers, I., Nguyen, D. L., Mitreva, M., Devreese, B., Hokke, C. H., Vercruysse, J., Claerebout, E. & Geldhof, P. (2013). In-depth proteomic and glycomic analysis of the adult-stage Cooperia oncophora excretome/secretome. Journal of proteome research, 12(9), 3900–3911. https://doi.org/10.1021/pr400114y

Britton, C., Emery, D. L., McNeilly, T. N., Nisbet, A. J. & Stear, M. J. (2020). The potential for vaccines against scour worms of small ruminants. International journal for Parasitology, 50(8), 533–553. https://doi.org/10.1016/j.ijpara.2020.04.003

Budke, C. M., Deplazes, P. & Torgerson, P. R. (2006). Global socioeconomic impact of cystic echinococcosis. Emerging infectious diseases, 12(2), 296–303. https://doi.org/10.3201/eid1202.050499

Cai, X., Yuan, G., Zheng, Y., Luo, X., Zhang, S., Ding, J., Jing, Z. & Lu, C. (2007). Effective production and purification of the glycosylated TSOL18 antigen, which is protective against pig cysticercosis. Infection and immunity, 76(2), 767–770. https://doi.org/10.1128/IAI.00444-07

Claerebout, E. & Geldhof, P. (2020). Helminth Vaccines in Ruminants: From Development to Application. Veterinary clinics of North America: Food animal practice, 36(1), 159–171. https://doi.org/10.1016/j.cvfa.2019.10.001

Corwin R. M. (1997). Economics of gastrointestinal parasitism of cattle. Veterinary parasitology, 72(3-4), 451–460. https://doi.org/10.1016/s0304-4017(97)00110-6

Dalimi, A., Motamedi, G., Hosseini, M., Mohammadian, B., Malaki, H., Ghamari, Z. & Ghaffari-Far, F. (2002). Echinococcosis/hydatidosis in western Iran. Veterinary parasitology, 105(2), 161–171. https://doi.org/10.1016/s0304-4017(02)00005-5

De Aluja, A. S., Villalobos, N. M., Nava, G., Toledo, A., Martínez, J. J., Plancarte, A., Rodarte, L. F., Fragoso, G. & Sciutto, E. (2005). Therapeutic capacity of the synthetic peptide-based vaccine against Taenia solium cysticercosis in pigs. Vaccine, 23(31), 4062–4069. https://doi.org/10.1016/j.vaccine.2004.11.076

Díaz, M. A., Villalobos, N., De Aluja, A., Rosas, G., Goméz-Conde, E., Hernández, P., Larralde, C., Sciutto, E., & Fragoso, G. (2003). Th1 and Th2 indices of the immune response in pigs vaccinated against Taenia solium cysticercosis suggest various host immune strategies against the parasite. Veterinary immunology and immunopathology, 93(3-4), 81–90. https://doi.org/10.1016/s0165-2427(03)00071-0

Ding, X., Lillehoj, H. S., Dalloul, R. A., Min, W., Sato, T., Yasuda, A. & Lillehoj, E. P. (2005). In ovo vaccination with the Eimeria tenella EtMIC2 gene induces protective immunity against coccidiosis. Vaccine, 23(28), 3733–3740. https://doi.org/10.1016/j.vaccine.2005.01.144

East, I. J., Berrie, D. A., & Fitzgerald, C. J. (1988). Oesophagostomum radiatum: successful vaccination of calves with an extract of in vitro cultured larvae. International journal for parasitology, 18(1), 125–127. https://doi.org/10.1016/0020-7519(88)90047-1

Ehsan M., Hu, R.., Liang, Q.., Hou, J.., Song, X., Yan, R. Zhu, X. & Li, X. (2020). Advances in the development of anti-Haemonchus contortus vaccines: Challenges, opportunities, and perspectives. Vaccines, 8(3), 555. https://doi.org/10.3390/vaccines8030555

Emery, D. L., McClure, S. J., & Wagland, B. M. (1993). Production of vaccines against gastrointestinal nematodes of livestock. Immunology and cell biology, 71(5), 463–472. https://doi.org/10.1038/icb.1993.52

Fujiwara, R. T., Loukas, A., Mendez, S., Williamson, A. L., Bueno, L. L., Wang, Y., Samuel, A., Zhan, B., Bottazzi, M. E., Hotez, P. J. & Bethony, J. M. (2006). Vaccination with irradiated Ancylostoma caninum third stage larvae induces a Th2 protective response in dogs. Vaccine, 24(4), 501–509. https://doi.org/10.1016/j.vaccine.2005.07.091

Fujiwara, R. T., Zhan, B., Mendez, S., Loukas, A., Bueno, L. L., Wang, Y., Plieskatt, J., Oksov, Y., Lustigman, S., Bottazzi, M. E., Hotez, P. & Bethony, J. M. (2007). Reduction of worm fecundity and canine host blood loss mediates protection against hookworm infection elicited by vaccination with recombinant Ac-16. Clinical and vaccine immunology, 14(3), 281–287. DOI: https://doi.org/10.1128/CVI.00404-06

Garcia, H. H., González, A. E., Tsang, V. C. W., O'Neal, S. E., Llanos-Zavalaga, F., Gonzalvez, G., Romero, J., Rodriguez, S., Moyano, L. M., Ayvar, V., Diaz, A., Hightower, A., Craig, P. S., Lightowlers, M. W., Gauci, C. G., Leontsini, E., Gilman, R. H. (2016). Elimination of Taenia solium Transmission in Northern Peru. The New England journal of medicine, 374(24), 2335–2344. https://doi.org/10.1056/NEJMoa1515520

Gasbarre, L. C. & Douvres, F. W. (1987). Protection from parasite-induced weight loss by the vaccination of calves with excretory-secretory products of larval Oesophagostomum radiatum. Veterinary parasitology, 26(1-2), 95–105. https://doi.org/10.1016/0304-4017(87)90080-x

Gauci, C. G., Jayashi, C. M., González, A. E., Lackenby, J. & Lightowlers, M. W. (2012). Protection of pigs against Taenia solium cysticercosis by immunization with novel recombinant antigens. Vaccine, 30(26), 3824–3828. https://doi.org/10.1016/j.vaccine.2012.04.019

Geldhof, P., Claerebout, E., Knox, D., Vercauteren, I., Looszova, A. & Vercruysse, J. (2002). Vaccination of calves against Ostertagia ostertagi with cysteine proteinase enriched protein fractions. Parasite immunology, 24(5), 263–270. https://doi.org/10.1046/j.1365-3024.2002.00461.x

Geldhof, P., Vercauteren, I., Vercruysse, J., Knox, D. P., Van Den Broeck, W. & Claerebout, E. (2004). Validation of the protective Ostertagia ostertagi ES-thiol antigens with different adjuvantia. Parasite immunology, 26(1), 37–43. https://doi.org/10.1111/j.0141-9838.2004.00681.x

Ghosh, K., Hawdon, J. & Hotez, P. (1996). Vaccination with alum-precipitated recombinant Ancylostoma-secreted protein 1 protects mice against challenge infections with infective hookworm (Ancylostoma caninum) larvae. The Journal of infectious diseases, 174(6), 1380–1383. https://doi.org/10.1093/infdis/174.6.1380

Gilbert, W., Bellet, C., Blake, D. P., Tomley, F. M. & Rushton, J. (2020). Revisiting the Economic Impacts of Eimeria and Its Control in European Intensive Broiler Systems with a Recursive Modeling Approach. Frontiers in Veterinary Science, 7, 757. https://doi.org/10.3389/fvets.2020.558182

González, A. E., Gauci, C. G., Barber, D., Gilman, R. H., Tsang, V. C. W., Garcia, H. H., Verastegui, M. & Lightowlers, M. W. (2005). Vaccination of pigs to control human neurocysticercosis. The American journal of tropical medicine and hygiene, 72(6), 837–839. https://doi.org/10.4269/ajtmh.2005.72.837

González-Sánchez, M. E., Cuquerella, M. & Alunda, J. M. (2018). Vaccination of lambs against Haemonchus contortus with the recombinant rHc23. Effect of adjuvant and antigen dose. PloS one, 13(3), 1-12. https://doi.org/10.1371/journal.pone.0193118

Grosso, G., Gruttadauria, S., Biondi, A., Marventano, S. & Mistretta, A. (2012). Worldwide epidemiology of liver hydatidosis including the Mediterranean area. World journal of gastroenterology, 18(13), 1425–1437. https://doi.org/10.3748/wjg.v18.i13.1425

Heath, D. D., Robinson, C., Shakes, T., Huang, Y., Gulnur, T., Shi, B., Zhang, Z., Anderson, G. A., & Lightowlers, M. W. (2012). Vaccination of bovines against Echinococcus granulosus (cystic echinococcosis). Vaccine, 30(20), 3076–3081. https://doi.org/10.1016/j.vaccine.2012.02.073

Hein, W. R. & Harrison, G. B. L. (2005). Vaccines against veterinary helminths. Veterinary parasitology, 132(3-4), 217–222. https://doi.org/10.1016/j.vetpar.2005.07.006

Heldens, J. G. M., Patel, J. R., Chanter, N., Thij, G. J. T., Gravendijck, M., Schijns, V. E. J. C., Langen, A. & Schetters, T. P. M. (2008). Veterinary vaccine development from an industrial perspective. Veterinary journal, 178(1), 7–20. https://doi.org/10.1016/j.tvjl.2007.11.009

Herd, R. P., Chappel, R. J. & Biddell, D. (1975). Immunization of dogs against Echinococcus granulosus using worm secretory antigens. International journal for parasitology, 5(4), 395–399. https://doi.org/10.1016/0020-7519(75)90004-1

Hotez, P. J., Hawdon, J. M., Cappello, M., Jones, B. F., Ghosh, K., Volvovitz, F. & Xiao, S. (1996). Molecular approaches to vaccinating against hookworm disease. Pediatric research, 40(4), 515–521. https://doi.org/10.1203/00006450-199610000-00001

Innes, E. A., Bartley, P. M., Rocchi, M., Benavidas-Silvan, J., Burrells, A., Hotchkiss, E., Chianini, F., Canton, G. & Katzer, F. (2011). Developing vaccines to control protozoan parasites in ruminants: Dead or alive? Veterinary parasitology, 180(1-2), 155–163. https://doi.org/10.1016/j.vetpar.2011.05.036

Jacob, S. S., Cherian, S., Sumithra, T. G., Raina, O. K. & Sankar, M. (2013). Edible vaccines against veterinary parasitic diseases—current status and future prospects. Vaccine, 31(15), 1879–1885. https://doi.org/10.1016/j.vaccine.2013.02.022

Jaramillo-Hernández, D. A., Salazar-Garcés, L. F., Baquero-Parra, M. M., Da Silva-Pinheiro, C. . & Alcantara-Neves N. M. (2020). Toxocariasis and Toxocara vaccine: a review. Orinoquia 24(2), 79-95. https://doi.org/10.22579/20112629.631

Jenkins M. C. (1998). Progress on developing a recombinant coccidiosis vaccine. International journal for Parasitology, 28(7), 1111–1119. https://doi.org/10.1016/s0020-7519(98)00041-1

Jenkins, M. C. (2001). Advances and prospects for subunit vaccines against protozoa of veterinary importance. Veterinary Parasitology, 101(3-4),291-310. https://doi.org/10.1016/s0304-4017(01)00557-x

Knox, D. P. (2000). Development of vaccines against gastrointestinal nematodes. Parasitology, 120(7), 43–61. https://doi.org/10.1017/s0031182099005764

Knox, D. P. & Smith, W. D. (2001). Vaccination against gastrointestinal nematode parasites of ruminants using gut-expressed antigens. Veterinary parasitology, 100(1-2), 21–32. https://doi.org/10.1016/s0304-4017(01)00480-0

Knox, D. P., Redmond, D. L., Newlands, G. F., Skuce, P. J., Pettit, D. & Smith, W. D. (2003). The nature and prospects for gut membrane proteins as vaccine candidates for Haemonchus contortus and other ruminant trichostrongyloids. International journal for Parasitology, 33(11), 1129–1137. https://doi.org/10.1016/s0020-7519(03)00167-x

Kyngdon, C. T., Gauci, C. G., Gonzalez, A. E., Flisser, A., Zoli, A., Read, A. J., Martínez-Ocaña, J., Strugnell, R. A. & Lightowlers, M. W. (2006). Antibody responses and epitope specificities to the Taenia solium cysticercosis vaccines TSOL18 and TSOL45-1A. Parasite immunology, 28(5), 191–199. https://doi.org/10.1111/j.1365-3024.2006.00820.x

Larrieu, E., Mujica, G., Araya, D., Labanchi, J. L., Arezo, M., Herrero, E., Santillán, G., Vizcaychipi, K., Uchiumi, L., Salvitti, J. C., Grizmado, C., Calabro, A., Talmon, G., Sepulveda, L., Galvan, J. M., Cabrera, M., Seleiman, M., Crowley, P., Cespedes, G … Lightowlers, M. W. (2019). Pilot field trial of the EG95 vaccine against ovine cystic echinococcosis in Rio Negro, Argentina: 8 years of work. Acta tropica, 191, 1–7. https://doi.org/10.1016/j.actatropica.2018.12.025

Larrieu, E., Mujica, G., Gauci, C. G., Vizcaychipi, K., Seleiman, M., Herrero, E., Labanchi, J. L., Araya, D., Sepúlveda, L., Grizmado, C., Calabro, A., Talmon, G., Poggio, T. V., Crowley, P., Cespedes, G., Santillán, G., García Cachau, M., Lamberti, R., Gino, L … Lightowlers, M. W. (2015). Pilot Field Trial of the EG95 Vaccine Against Ovine Cystic Echinococcosis in Rio Negro, Argentina: Second Study of Impact. PLOS: Neglected Tropical Diseases, 9(10), 1-10. DOI: https://doi.org/10.1371/journal.pntd.0004134

Li, J., Zheng, J., Gong, P. & Zhang, X. (2012). Efficacy of Eimeria tenella rhomboid-like protein as a subunit vaccine in protective immunity against homologous challenge. Parasitology research, 110(3), 1139–1145. https://doi.org/10.1007/s00436-011-2603-1

Lightowlers, M. W., Jensen, O., Fernández, E., Iriarte, J. A., Woollard, D. J., Gauci, C. G., Jenkins, D. J. & Heath, D. D. (1999). Vaccination trials in Australia and Argentina confirm the effectiveness of the EG95 hydatid vaccine in sheep. International journal for Parasitology, 29(4), 531–534. https://doi.org/10.1016/s0020-7519(99)00003-x

Lightowlers, M. W., Lawrence, S. B., Gauci, C. G., Young, J., Ralston, M. J., Maas, D. & Heath, D. D. (1996). Vaccination against hydatidosis using a defined recombinant antigen. Parasite immunology, 18(9), 457–462. https://doi.org/10.1111/j.1365-3024.1996.tb01029.x

Lightowlers, M. W. & Donadeu, M. (2017). Designing a Minimal Intervention Strategy to Control Taenia solium. Trends in Parasitology, 33(6), 426-434. https://doi.org/10.1016/j.pt.2017.01.011

Loukas, A., Bethony, J. M., Williamson, A. L., Goud, G. N., Mendez, S., Zhan, B., Hawdon, J. M., Bottazzi, M. E., Brindley, P. J. & Hotez, P. J. (2004). Vaccination of dogs with a recombinant cysteine protease from the intestine of canine hookworms diminishes the fecundity and growth of worms. The Journal of infectious diseases, 189(10), 1952–1961. https://doi.org/10.1086/386346

Masure, D., Vlaminck, J., Wang, T., Chiers, K., Van den Broeck, W., Vercruysse, J. & Geldhof, P. (2013). A role for eosinophils in the intestinal immunity against infective Ascaris suum larvae. PLOS: Neglected Tropical Diseases, 7(3), 1-7. https://doi.org/10.1371/journal.pntd.0002138

Matthews, J. B., Geldhof, P., Tzelos, T. & Claerebout, E. (2016). Progress in the development of subunit vaccines for gastrointestinal nematodes of ruminants. Parasite immunology, 38(12), 744–753. https://doi.org/10.1111/pim.12391

McDonald, V. & Shirley, M. W. (2009). Past and future: vaccination against Eimeria. Parasitology, 136(12), 1477–1489. https://doi.org/10.1017/S0031182009006349

Meeusen, E. N. T., Walker, J., Peters, A., Pastoret, P. & Jungersen, G. (2007). Current status of veterinary vaccines. Clinical microbiology reviews, 20(3), 489–510. https://doi.org/10.1128/CMR.00005-07

Merck Animal Health. (n.d). 0255 PB MAH-PPC Coccivac B52 2-20.indd (merck-animal-health-usa.com)

Merck Animal Health. (n. d.). Intestinal health. https://www.merck-animal-health.com/species/poultry/intestinal-health/

Meyvis, Y., Geldhof, P., Gevaert, K., Timmerman, E., Vercruysse, J. & Claerebout, E. (2007). Vaccination against Ostertagia ostertagi with subfractions of the protective ES-thiol fraction. Veterinary parasitology, 149(3-4), 239–245. https://doi.org/10.1016/j.vetpar.2007.08.014

Miller, T. A. (1964). Effect of x-irradiation upon the infective larvae of ancylostoma caninum and the immunogenic effect in dogs of a single infection with 40 kr-irradiated larvae. The Journal of parasitology, 50(6), 735–742. https://doi.org/10.2307/3276194

Molina, V. M. (2017). Pharmacological treatment of giardiasis. In Rodriguez, A. J. (Ed.), Current Topics in Giardiasis (pp. 133–145). IntechOpen. https://doi.org/10.5772/intechopen.71803

Moher, D., Liberati, A., Tetzlaff, J., Altman, D. G. & The PRISMA Group (2009). Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. PLOS medicine, 6(7), 1-6. https://doi.org/10.1371/journal.pmed.1000097

MSD Animal Health. (n.d.). Poultry. https://www.msd-animal-health-hub.co.uk/Products/Paracox

Munn, E. A., Greenwood, C. A., & Coadwell, W. J. (1987). Vaccination of young lambs by means of a protein fraction extracted from adult Haemonchus contortus. Parasitology, 94(2), 385–397. https://doi.org/10.1017/s0031182000054032

Newton, S. E. & Meeusen, E. N. T. (2003). Progress and new technologies for developing vaccines against gastrointestinal nematode parasites of sheep. Parasite immunology, 25(5), 283–296. https://doi.org/10.1046/j.1365-3024.2003.00631.x

Newton, S. E. & Munn, E. A. (1999). The development of vaccines against gastrointestinal nematode parasites, particularly Haemonchus contortus. Parasitology today, 15(3), 116–122. https://doi.org/10.1016/s0169-4758(99)01399-x

Nisbet, A. J., McNeilly, T. N., Greer, A. W., Bartley, Y., Oliver, E. M., Smith, S., Palarea-Albaladejo, J. & Matthews, J. B. (2016). Protection of ewes against Teladorsagia circumcincta infection in the periparturient period by vaccination with recombinant antigens. Veterinary parasitology, 228, 130–136. https://doi.org/10.1016/j.vetpar.2016.09.002

Nisbet, A. J., McNeilly, T. N., Wildblood, L. A., Morrison, A. A., Bartley, D. J., Bartley, Y., Longhi, C., McKendrick, I. J., Palarea-Albaladejo, J. & Matthews, J. B. (2013). Successful immunization against a parasitic nematode by vaccination with recombinant proteins. Vaccine, 31(37), 4017–4023. https://doi.org/10.1016/j.vaccine.2013.05.026

Payne, P. A. & Artzer, M. (2009). The biology and control of Giardia spp and Tritrichomonas foetus. Veterinary clinics of North America: Small animal practice, 39(6), 993–1007. https://doi.org/10.1016/j.cvsm.2009.06.007

Peek, H. W. & Landman, W. J. M. (2011). Coccidiosis in poultry: anticoccidial products, vaccines and other prevention strategies. Veterinary quarterly, 31(3), 143–161. https://doi.org/10.1080/01652176.2011.605247

Petavy, A. F., Hormaeche, C., Lahmar, S., Ouhelli, H., Chabalgoity, A., Marchal, T., Azzouz, S., Schreiber, F., Alvite, G., Sarciron, M. E., Maskell, D., Esteves, A. & Bosquet, G. (2008). An oral recombinant vaccine in dogs against Echinococcus granulosus, the causative agent of human hydatid disease: a pilot study. PLOS: neglected tropical diseases, 2(1), 1-7. https://doi.org/10.1371/journal.pntd.0000125

Plancarte, A., Flisser, A., Gauci, C. G. & Lightowlers, M. W. (1999). Vaccination against Taenia solium cysticercosis in pigs using native and recombinant oncosphere antigens. International journal for parasitology, 29(4), 643–647. https://doi.org/10.1016/s0020-7519(99)00021-1

Preston, S., Jabbar, A., Nowell, C., Joachim, A., Ruttkowski, B., Baell, J., Cardno, T., Korhonen, P. K., Piedrafita, D., Ansell, B. R. E., Jex, A. R., Hofmann, A. & Gasser, R. B. (2015). Low cost whole-organism screening of compounds for anthelmintic activity. International journal for parasitology, 45(5), 333–343. https://doi.org/10.1016/j.ijpara.2015.01.007

Redding, L. & Weiner, D. B. (2009). DNA vaccines in veterinary use. Expert review of vaccines, 8(9), 1251–1276. https://doi.org/10.1586/erv.09.77

Reid, W. M. (1990). History of avian medicine in the United States. X. Control of coccidiosis. Avian diseases, 34(3), 509–525. https://doi.org/10.2307/1591239

Sander, V. A., Sánchez López, E. F., Mendoza, L., Ramos, V. A., Corigliano, M. G. & Clemente, M. (2020). Use of Veterinary Vaccines for Livestock as a Strategy to Control Foodborne Parasitic Diseases. Frontiers in cellular and infection microbiology, 10 (288), 1-20. https://doi.org/10.3389/fcimb.2020.00288

Schetters, T. (1995). Vaccine development from a commercial point of view. Veterinary parasitology, 57(1-3), 267–275. https://doi.org/10.1016/0304-4017(94)03125-g

Schetters, T. P. M. & Gravendyck, M. (2006). Regulations and procedures in parasite vaccine development. Parasitology, 133, 189–195. https://doi.org/10.1017/S0031182006001879

Sciutto, E., Fragoso, G., De Aluja, A. S., Hernández, M., Rosas, G. & Larralde, C. (2008). Vaccines against cysticercosis. Current topics in medicinal chemistry, 8(5), 415–423. https://doi.org/10.2174/156802608783790839

Sciutto, E., Fragoso, G., Hernández, M., Rosas, G., Martínez, J. J., Fleury, A., Cervantes, J., Aluja, A. & Larralde, C. (2013). Development of the S3Pvac vaccine against murine Taenia crassiceps cysticercosis: a historical review. The Journal of parasitology, 99(4), 693–702. https://doi.org/10.1645/GE-3101.1

Sepúlveda-Crespo, D., Reguera, R. M., Rojo-Vázquez, F., Balaña-Fouce, R., & Martínez-Valladares, M. (2020). Drug discovery technologies: Caenorhabditis elegans as a model for anthelmintic therapeutics. Medicinal research reviews, 40(5), 1715–1753. https://doi.org/10.1002/med.21668

Sharma, N., Singh, V. & Shyma, K. P. (2015). Role of parasitic vaccines in integrated control of parasitic diseases in livestock. Veterinary world, 8(5), 590–598. https://doi.org/10.14202/vetworld.2015.590-598

Siefker, C. & Rickard, L. G. (2000). Vaccination of calves with Haemonchus placei intestinal homogenate. Veterinary parasitology, 88(3-4), 249–260. https://doi.org/10.1016/s0304-4017(99)00208-3

Smith, S. K. & Smith, W. D. (1996). Immunisation of sheep with an integral membrane glycoprotein complex of Haemonchus contortus and with its major polypeptide components. Research in veterinary science, 60(1), 1–6. https://doi.org/10.1016/s0034-5288(96)90121-6

Smith, S. K., Pettit, D., Newlands, G. F., Redmond, D. L., Skuce, P. J., Knox, D. P. & Smith, W. D. (1999). Further immunization and biochemical studies with a protective antigen complex from the microvillar membrane of the intestine of Haemonchus contortus. Parasite immunology, 21(4), 187–199. https://doi.org/10.1046/j.1365-3024.1999.00217.x

Smith, W. D. & Smith, S. K. (1993). Evaluation of aspects of the protection afforded to sheep immunised with a gut membrane protein of Haemonchus contortus. Research in veterinary science, 55(1), 1–9. https://doi.org/10.1016/0034-5288(93)90025-b

Smith, W. D., Smith, S. K. & Murray, J. M. (1994). Protection studies with integral membrane fractions of Haemonchus contortus. Parasite immunology, 16(5), 231–241. https://doi.org/10.1111/j.1365-3024.1994.tb00345.x

Smith, W. D., Smith, S. K., Pettit, D., Newlands, G. F. & Skuce, P. J. (2000). Relative protective properties of three membrane glycoprotein fractions from Haemonchus contortus. Parasite immunology, 22(2), 63–71. https://doi.org/10.1046/j.1365-3024.2000.00277.x

Song, H., Yan, R., Xu, L., Song, X., Shah, M. A., Zhu, H., & Li, X. (2010). Efficacy of DNA vaccines carrying Eimeria acervulina lactate dehydrogenase antigen gene against coccidiosis. Experimental parasitology, 126(2), 224–231. https://doi.org/10.1016/j.exppara.2010.05.015

Song, K. D., Lillehoj, H. S., Choi, K. D., Yun, C. H., Parcells, M. S., Huynh, J. T. & Han, J. Y. (2000). A DNA vaccine encoding a conserved Eimeria protein induces protective immunity against live Eimeria acervulina challenge. Vaccine, 19(2-3), 243–252. https://doi.org/10.1016/s0264-410x(00)00169-9

Song, X., Xu, L., Yan, R., Huang, X., Shah, M. A., & Li, X. (2009). The optimal immunization procedure of DNA vaccine pcDNA-TA4-IL-2 of Eimeria tenella and its cross-immunity to Eimeria necatrix and Eimeria acervulina. Veterinary parasitology, 159(1), 30–36. https://doi.org/10.1016/j.vetpar.2008.10.015

Soutter, F., Werling, D., Tomley, F. M. & Blake, D. P. (2020). Poultry Coccidiosis: Design and Interpretation of Vaccine Studies. Frontiers in veterinary science, 7, 101.: https://doi.org/10.3389/fvets.2020.00101

Stutzer, C., Richards, A., Ferreira, M., Baron, S. & Maritz-Olivier, C. (2018). Metazoan parasite vaccines: present status and future prospects. Frontiers in cellular and infection microbiology 8, 67. https://doi.org/10.3389/fcimb.2018.00067

Tecnovax. (n.d.) PROVIDEAN HIDATIL EG95. Retrieved from http://www.tecnovax.com.ar/productos/providean-hidatil-eg95/

Tsuji, N., Suzuki, K., Kasuga-Aoki, H., Isobe, T., Arakawa, T. & Matsumoto, Y. (2003). Mice intranasally immunized with a recombinant 16-kilodalton antigen from roundworm Ascaris parasites are protected against larval migration of Ascaris suum. Infection and immunity, 71(9), 5314–5323. https://doi.org/10.1128/iai.71.9.5314-5323.2003

Unnikrishnan, M., Rappuoli, R. & Serruto, D. (2012). Recombinant bacterial vaccines. Current opinion in immunology, 24(3), 337–342. https://doi.org/10.1016/j.coi.2012.03.013

Urban, J. F.& Tromba, F. G. (1982). Development of immune responsiveness to Ascaris suum antigens in pigs vaccinated with ultraviolet-attenuated eggs. Veterinary immunology and immunopathology, 3(4), 399–409. https://doi.org/10.1016/0165-2427(82)90022-8

Verastegui, M., Gilman, R. H., Gonzales, A., Garcia, H. H., Gavidia, C., Falcon, N., Bernal, T., Arana, Y., Tsang, V. C. & Cysticercosis Working Group In Peru (2002). Taenia solium oncosphere antigens induce immunity in pigs against experimental cysticercosis. Veterinary parasitology, 108(1), 49–62. https://doi.org/10.1016/s0304-4017(02)00182-6

Vercauteren, I., Geldhof, P., Vercruysse, J., Peelaers, I., Van den Broeck, W., Gevaert, K., & Claerebout, E. (2004). Vaccination with an Ostertagia ostertagi polyprotein allergen protects calves against homologous challenge infection. Infection and immunity, 72(5), 2995–3001. https://doi.org/10.1128/iai.72.5.2995-3001.2004

Vercruysse, J., Charlier, J., Van Dijk, J., Morgan, E. R., Geary, T., Von Samson-Himmelstjerna, G. & Claerebout, E. (2018). Control of helminth ruminant infections by 2030. Parasitology, 145(13), 1655–1664. https://doi.org/10.1017/S003118201700227X

Vercruysse, J., Knox, D. P., Schetters, T. P. & Willadsen, P. (2004). Veterinary parasitic vaccines: pitfalls and future directions. Trends in parasitology, 20(10), 488–492. https://doi.org/10.1016/j.pt.2004.07.009

Vermeulen, A. N. (1998). Progress in recombinant vaccine development against coccidiosis. A review and prospects into the next millennium. International journal for parasitology, 28(7), 1121–1130. https://doi.org/10.1016/s0020-7519(98)00080-0

Versteeg, L., Almutairi, M. M., Hotez, P. J. & Pollet, J. (2019). Enlisting the mRNA Vaccine Platform to Combat Parasitic Infections. Vaccines, 7(4), 122. https://doi.org/10.3390/vaccines7040122

Vlaminck, J., Borloo, J., Vercruysse, J., Geldhof, P. & Claerebout, E. (2015). Vaccination of calves against Cooperia oncophora with a double-domain activation-associated secreted protein reduces parasite egg output and pasture contamination. International journal for parasitology, 45(4), 209–213. https://doi.org/10.1016/j.ijpara.2014.11.001

Vlaminck, J., Martinez-Valladares, M., Dewilde, S., Moens, L., Tilleman, K., Deforce, D., Urban, J., Claerebout, E., Vercruysse, J. & Geldhof, P. (2011). Immunizing pigs with Ascaris suum haemoglobin increases the inflammatory response in the liver but fails to induce a protective immunity. Parasite immunology, 33(4), 250–254. https://doi.org/10.1111/j.1365-3024.2010.01274.x

Wallach, M., Smith, N. C., Petracca, M., Miller, C. M., Eckert, J. & Braun, R. (1995). Eimeria maxima gametocyte antigens: potential use in a subunit maternal vaccine against coccidiosis in chickens. Vaccine, 13(4), 347–354. https://doi.org/10.1016/0264-410x(95)98255-9

Williams, R. B. (2002). Fifty years of anticoccidial vaccines for poultry (1952-2002). Avian diseases, 46(4), 775–802. https://doi.org/10.1637/0005-2086(2002)046[0775:FYOAVF]2.0.CO

Woods, D. J., Vaillancourt, V. A., Wendt, J. A. & Meeus, P. F. (2011). Discovery and development of veterinary antiparasitic drugs: past, present and future. Future medicinal chemistry, 3(7), 887–896. https://doi.org/10.4155/fmc.11.39

Xu, J., Zhang, Y. & Tao, J. (2013). Efficacy of a DNA vaccine carrying Eimeria maxima Gam56 antigen gene against coccidiosis in chickens. The Korean journal of parasitology, 51(2), 147–154. https://doi.org/10.3347/kjp.2013.51.2.147

Xu, Q., Song, X., Xu, L., Yan, R., Shah, M. A. A. & Li, X. (2008). Vaccination of chickens with a chimeric DNA vaccine encoding Eimeria tenella TA4 and chicken IL-2 induces protective immunity against coccidiosis. Veterinary parasitology, 156(3-4), 319–323. https://doi.org/10.1016/j.vetpar.2008.05.025

Zoetis (n.d.) Giardia Vax. https://ar.zoetis.com/products/caninos/giardia-vax.aspx

Notes

[1] All works which had not the data mentioned in the inclusion criteria were excluded (e.g., preclinical trials preclinical of vaccine candidates for these same parasites and others).

Additional information

CÓMO CITAR: Vargas, L., Prieto, L., Baquero, M., Corredor, W., Alcantara-Neves, N. and Jaramillo-Hernández, D. (2022). Vaccines for gastrointestinal parasites, a pillar of preventive medicine in veterinary practice: Systematic review. Revista de Investigación Agraria y Ambiental, 13(1), 221 – 251. https://doi.org/10.22490/21456453.4544

AUTHORS’ CONTRIBUTION: Lina M. Vargas: Data search, introduction, methodology, writing. Laura D. Prieto: Data search, introduction, methodology, writing. Monica Mónica M. Baquero: Logistics, review. Wilson Corredor: review, translation. Neuza M. Alcantara-Neves: review. Dumar A. Jaramillo-Hernández: Data search, introduction, methodology, writing, editing, supervision, review, translation.

CONFLICTO DE INTERESES: Los autores declaran no tener ningún conflicto de intereses.

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