Abstract
The biological control of gastrointestinal (GI) parasites using predatory fungi has been recently proposed as an accurate and sustainable approach in birds. The current study aimed to assess for the first time the efficacy of using the native ovicidal fungus Mucor circinelloides (FMV-FR1) in reducing coccidia parasitism in peacocks. For this purpose, an in vivo trial was designed in the resident peacock collection (n = 58 birds) of the São Jorge Castle, at Lisbon, Portugal. These animals presented an initial severe infection by coccidia of the genus Eimeria (20106 ± 8034 oocysts per gram of feces, OPG), and thus received commercial feed enriched with a M. circinelloides suspension (1.01 × 108 spores/kg feed), thrice-weekly. Fresh feces were collected every 15 days to calculate the coccidia shedding, using the Mini-FLOTAC technique. The same bird flock served simultaneously as control (t0 days) and test groups (t15–t90 days). The average Eimeria sp. shedding in peacocks decreased up to 92% following fungal administrations, with significant reduction efficacies of 78% (p = 0.004) and 92% (p = 0.012) after 45 and 60 days, respectively. Results from this study suggest that the administration of M. circinelloides spores to birds is an accurate solution to reduce their coccidia parasitism.
Similar content being viewed by others
Introduction
Galliformes kept under free-range conditions in farms, zoos and private collections are highly prone to gastrointestinal (GI) parasitism caused by coccidia of the genera Eimeria and Isospora, and by nematodes such as Capillaria spp., Ascaridia galli, Heterakis spp., Trichostrongylus tenuis and Strongyloides spp.1,2,3,4,5,6 .
Coccidia, in particular, are responsible for severe health concerns in domestic and exotic birds, being of clinical (characterized by swelling of the intestinal wall and hemorrhages, leading to diarrhea and/or hemorrhagic feces, and even to death) or subclinical importance (associated with limited enteritis and loss of fluids, leading to poor absorption of nutrients), with poultry coccidia being the most studied3,7, resulting in average economic losses for the poultry industry of nearly 12 € billion annually worldwide8,9. Moreover, a total of nine Eimeria species have already been described in peacocks, namely Eimeria arabica, E. kharjensis, E. mandali, E. mayurai, E. mutica, E. pavonina, E. pavonis, E. patnaiki and E. riyadhae6,10,11, and despite not being so well studied, it is known that E. mutica and E. kharjensis develop their pathogenic activity on peacock’s ileum12.
Prevention and treatment of avian GI parasitic infections is still frequently performed exclusively with antiparasitic drugs, whose incorrect use often leads to low treatment efficacies, drug resistance, accumulation of drug residues on carcasses and contamination of soil and ground-waters13,14,15,16,17 .
Over the last 30 years, efforts have been made by the scientific community to develop new complementary approaches for the integrated control of GI parasitic infections in animals, namely the use of predatory fungi, also referred in the literature as “nematophagous”, “helmintophagous” or “parasiticide fungi”18. These saprophytic filamentous fungi are mostly found in agricultural soil and animal feces19,20,21,22,23,24 , and their main functional characteristic relies on the ability to capture and destroy environmental forms of GI parasites (larvae, eggs, and oocysts), by means of mechanical and enzymatic activities, and thus breaking the parasites’ life cycles on their exogenous stages. The most known predatory fungal taxa are Duddingtonia flagrans (Dudd.) R.C. Cooke (1969), Arthrobotrys oligospora Fresen., (1850), and Monacrosporium thaumasium (Drechsler) de Hoog & Oorschot (1985), which are able to destroy nematodes’ infective larvae (L3) (larvicidal fungi), whereas Pochonia chlamydosporia (Goddard) Zare & W. Gams (2001) and Mucor circinelloides Tiegh (1875) present ovicidal activity towards helminth eggs and coccidian oocysts (ovicidal/coccidicidal fungi)18,25,26.
Despite the majority of studies have addressed the use of these fungi to control ruminants27,28,29 and horses30,31,32 GI parasites, research on this topic has been recently extended to other animal species, namely dogs, birds, and captive wild animals24,33,34,35,36,37 . Regarding bird parasite control, it has been revealed that P. chlamydosporia, D. flagrans, Arthrobotrys spp. and M. thaumasium are promising candidates for the biological control of helminth infections, namely in chickens, laying hens and ostriches, and also confirmed chlamydospores’ tolerance to the avian GI biochemical environment38,39,40,41,42. Recently, Lozano et al.24 described for the first time the isolation of seven native Mucor spp. isolates (M. circinelloides and M. lusitanicus) from chicken and peacock fecal samples, and confirmed their coccidiostatic and coccidicidal activity towards Eimeria sp. oocysts, with the isolate M. circinelloides FR1 achieving the highest efficacy on destroying coccidia oocysts. However, field trials using predatory fungi to control GI parasitic infections in birds are still lacking.
The current research aimed to evaluate in vivo the efficacy of M. circinelloides (FMV-FR1) in reducing coccidia infections in an ornamental peacock collection.
Results
Initial coprological results revealed that this peacock collection was severely infected with Eimeria sp. at the beginning of the trial (20107 ± 8034 oocysts per gram of feces, OPG). Following fungal administrations, it was possible to observe an overall decrease in oocysts’ shedding, with OPG reduction efficacies ranging between 59 to 92%, and with the decreased values at timepoints t45 and t60 being significant (p = 0.004 and p = 0.012, respectively) (Fig. 1). Furthermore, it was also observed that the average OPG did not reach the initial level during the entire assay.
Weather data tracked for the Lisbon municipality, in which the peacock collection was located, revealed an average temperature and rainfall of 16.4 °C (11.5–21.3 °C, min–max.) and 5.96 mm (0–26.4 mm, min–max), respectively, during the study period (Fig. 2). Also, a rainfall increase was observed in weeks 9 and 10, characterized by flood episodes in Lisbon downtown. Both temperature and rainfall did not significantly correlate with the coccidia shedding values (p = 0.12 and p = 0.48 for the correlations “Eimeria OPG—temperature”, and “Eimeria OPG—rainfall”, respectively).
Finally, no side effects were recorded after feeding peacocks with M. circinelloides spores, namely no changes on normal bird behavior, feed consumption, and feather appearance.
Discussion
Predatory fungi are a promising solution for the integrated parasite management of animals kept in captivity in farms, zoos, and private collections, serving as a complement to the conventional antiparasitic drug treatments25,36,43. However, studies on this topic traditionally focus on horses and ruminants, and to our knowledge no large-scale field trials were previously performed aiming to assess the efficacy of predatory fungi in the reduction of avian GI parasitism.
Parasitological results from this study allowed to conclude that the parasiticide activity developed by M. circinelloides against Eimeria spp. oocysts reduced the environmental contamination by this parasite, with significant OPG reduction efficacies up to 92%, after 60 days of fungal feeding. These results demonstrated that the predacious activity developed by this type of fungi is a gradual process, as observed in other in vivo trials performed with M. circinelloides in dogs26,36, sheep29, baboons36 and wapitis35, which reported significant reductions in helminth egg shedding after a minimum of one month of routine fungal administrations.
The presence of parasitic forms (eggs, oocysts, and larvae) triggers predatory fungi hyphae germination and colonization of the fecal and surrounding soil’s microenvironments, with the final attachment to the oocyst/egg capsule prompting the first stage of ovicidal/coccidicidal activity18,25,34. This can be considered one of the most critical stages of the whole ovicidal process, together with the penetration of the parasite’s capsule, since fungi need to compete against other fecal and soil commensal microorganisms, attach on the parasite capsule and penetrate it through mechanical (appressorium and haustorium) and enzymatic activity (e.g., proteases, chitinases, collagenases and lipases)25,44,45,46,47 .
This trial was conducted mostly during the Autumn season, in which moderate average temperatures and rainfall were recorded in the Lisbon Municipality. Despite these weather variables being favorable for coccidia oocysts to reach the infective stage, which can even be accomplished at temperatures lower than 20 °C, and especially during Spring and Autumn seasons48,49, no significant correlations were obtained between weather and coccidia shedding. Thus, the possibility that meteorological conditions could contribute to differences observed in the parasitism results was discarded. Moreover, data collected regarding peacock samples suggest that this M. circinelloides isolate tolerated and maintained its predatory activity at overall temperatures and rainfall between 11.5–21.3 °C and 0–26.4 mm, respectively, being in accordance with previous in vitro and in vivo research using the strain M. circinelloides CECT 20824 for the biological control of strongyles, ascarids and trematodes34,35,50. It has also been demonstrated that D. flagrans, P. chlamydosporia and Monacrosporium sinense Xing Z. Liu & K.Q. Zhang (1994) maintain their germination capacity on different culture media even at temperatures lower than 20 °C51,52.
Despite the general OPG decreasing trend observed during the trial, following fungal spores’ administrations, a slight increase was recorded on the last two weeks, which coincided with the intense rainfall period recorded for the Lisbon district, as previously mentioned. Between t67–90 days of trial, and due to climate conditions, peacocks were not let free ranging in the monument’s outdoor area, and thus were sheltered in close contact with each other, leading to a higher exposition to feces contaminated with coccidia oocysts, and consequently stimulating re-infections. Avian Eimeria spp. have a very short life cycle, with a prepatent period of minimum four days3,8, and thus increasing bird stocking density can trigger re-infections and increase coccidia shedding53. These results also point out to the need for a constant monitorization of parasite shedding and clinical signs, during a parasite biocontrol program using predatory fungi, since treatments with antiparasitic drugs might be necessary to complement the action of these fungi.
This was also the first biological control trial to use the coprological technique Mini-FLOTAC for assessing the dynamics of coccidia shedding following the administration of predatory fungi to animals. Since 2014, there has been an increment in studies reporting the use of Mini-FLOTAC in routine diagnosis of GI parasitic infections in several animal species, being unanimously considered a good alternative to the traditional McMaster technique54,55 . Recent studies with Mini-FLOTAC in birds have revealed its usefulness for the diagnosis of coccidia and helminth infections, achieving sensitivities of up to 100%56,57,58,59,60. Since typical in vivo studies with predatory fungi always aim to compare control and test groups and obtain the respective oocyst/egg shedding or L3 reduction efficacies, the use of more sensitive coprological techniques like MF is of major importance, allowing to detect the real differences between groups and determine more statistically robust treatment efficacies.
Finally, one of the major concerns regarding the use of predatory fungi to control GI parasites is whether this kind of fungi can be harmful to birds, and during this trial no side effects were recorded following the administration of M. circinelloides spores to peacocks. These outcomes are in accordance with extensive research performed with this fungal species in horses, ruminants, and dogs26,29,61,62, in which authors confirmed the lack of pathogenicity of M. circinelloides spores to these animal species.
Results from this research offer the opportunity to develop further studies in the topic of parasite biocontrol. It would be interesting if further in vivo trials could include: (i) a wider period of research (e.g., 6–12 months of spores’ administrations and fecal collections), to evaluate the long-term efficacy of M. circinelloides in maintaining the coccidia fecal shedding at basal levels in birds, as extensively demonstrated for strongyles affecting domestic and exotic herbivores27,30,35,63; (ii) the separation of birds in test and control groups, and if possible according to their age (e.g., juveniles and adults), since younger birds are typically more prone to be infected by coccidia than adults49,64, and thus parasiticide fungi efficacy might differ between age groups; (iii) the collection of blood samples for haematological analysis to conclude more about the safety of this fungus, as previously performed in horses and ruminants fed with M. circinelloides and D. flagrans spores29,62,65; (iv) a previous characterization of the different Eimeria species residing in the GI tract of the respective birds, to check if the parasiticide efficacy of M. circinelloides would differ between Eimeria species.
To our best knowledge, this is the first report of an in vivo trial performed in exotic birds kept under real ornamental conditions, using a native ovicidal fungus previously isolated from birds, and aiming to evaluate its efficacy in reducing coccidia parasitism. This study revealed that feeding M. circinelloides to peacocks did not result in any side effects for birds, while achieving significant reduction efficacies of 78–92% in their coccidia parasitism. Overall results allow to propose M. circinelloides as a good fungal candidate for an accurate, safe, and sustainable parasite control program in birds.
Methods
Peacock collection
This trial was performed on the resident peacock collection (Pavo cristatus) of São Jorge Castle, a national monument located in Lisbon downtown, Portugal (38°42′50.241″ N 9°8′2.182″ W). The flock was composed by 58 birds (44 adults and 14 chicks), kept freely in an outdoor area of 4700 m2. According to previous research performed at the LPPD-CIISA-FMV, infections by Eimeria sp., Capillaria sp. and Strongyloides pavonis were identified in this peacock collection59.
These birds were normally fed twice per day with a formulation composed by corn, wheat, barley, sorghum, soyabean meal, sunflower seeds, calcium carbonate, monocalcium phosphate, soyabean oil, sodium chloride, molasses, and lard (nutritional composition: 15.8% Crude Protein, 4.25% Crude Fibre, 5% Ash, 3.45% Crude Fat, 0.8% Calcium, 0.43% Phosphorus, 0.09% Sodium, 0.75% Lysine and 0.32% Methionine), given ad libitum at two different locations.
In this bird collection, the assistant Veterinarians annually perform a single oral administration of Toltrazuril (25 mg/kg) to the juveniles (March–April), and the entire group receives febantel (15 mg/kg), pyrantel pamoate (5 mg/kg) and praziquantel (5 mg/kg), as a pre-mixture. However, no antiparasitic drug treatment was performed at least 6 months prior and during the trial.
Preparation of the fungal suspension
A native Mucor circinelloides (FMV-FR1) ovicidal isolate, belonging to the predatory fungi collection of the Laboratory of Parasitology and Parasitic Diseases of the Faculty of Veterinary Medicine—University of Lisbon (LPPD-CIISA-FMV), whose parasiticide activity towards avian coccidia was previously confirmed24, was used in the current study. This isolate was stored in Wheat-Flour Agar (2%) medium, at room temperature, in a dark and dry environment, and cultured according to Arias et al.66. Briefly, a wheat broth was prepared, using 10 g of wheat grains per 1 L of distilled water. After autoclaving, 50 mL of broth were transferred to 20 plastic bottles, previously washed, and sterilized with UV-light. Wheat Agar cubes of 2.25 × 2.25 × 2.25 cm, containing mycelia from M. circinelloides, were cut and added to the broth in each bottle, which were then left at room temperature with a slope of 45° for one month. Finally, fungal suspensions of 106 spores’ fold/mL were established, using a Neubauer chamber to count Mucor conidia and chlamydospores, and kept in a dry environment until its further use.
Fungal administrations
For this assay, bird feed doses containing M. circinelloides spores were previously prepared in the laboratory, following the protocol proposed by Voinot et al.29. For each dose, 600 g of peacock feed were mixed with 60 mL of the fungal suspension with 106 spores/mL. The mixture was dried at 27 °C, for 30 min, using an incubator, and then packaged individually in sealed plastic bags, with peacocks receiving 1.01 × 108 spores/kg of feed (Fig. 3).
The assay lasted between October—December 2022 and was based on the procedures described by Palomero et al.35 and Voinot et al.29. During this timeframe, a total of 33 fungal oral administrations were performed, thrice weekly. Since it was not possible to set two separate groups (test and control), the same flock served simultaneously as control (t0 days) and test group (t15–t90 days).
Parasitological analysis
A total of 20 fresh fecal samples were collected from the environment, immediately after excretion, every 15 days, with exception for t0 days (n = 17 samples) and t30 days (n = 16 samples), and then individually packed in plastic bags and stored in a refrigerator (4 °C) at the LPPD-CIISA-FMV, for maximum one week.
All samples were processed using the coprological technique Mini-FLOTAC, to identify coccidia oocysts and helminth eggs, and calculate their fecal shedding (oocysts or eggs per gram of feces, OPG or EPG). For this purpose, the Mini-FLOTAC protocol followed the guidelines proposed by the manufacturer and referred in the literature for exotic animals54,59,60. Briefly, 2 g of feces were mixed with 38 mL of saturated sucrose solution (specific gravity 1.2), using the Fill-FLOTAC device; the resulting fecal suspension was transferred to the counting chamber, and left resting on the lab bench for 10 min, to allow parasitic forms to float and attach to the counting grids; then, the top disk was rotated clock-wise, and all coccidia oocysts and helminth eggs were identified and counted in an optical microscope (100x), using an analytic sensitivity of 10 OPG/EPG.
At the beginning of the trial, peacocks revealed very low burdens of Capillaria sp. (1.2 ± 0.81 EPG), which was the only helminth identified, and therefore only coccidia shedding was considered for further analysis.
The average coccidia OPG was calculated for each sampling timepoint, and treatment efficacy was determined based on the coccidia fecal oocyst count reduction (FOCR), using the following formula30,31,35:
Side effects
Peacocks were regularly examined for any side effects resulting from fungal administrations, namely feed rejection, modifications on normal bird behavior, feathers appearance, skin lesions, and diarrhea or blood on droppings.
Climate conditions
Weather data recorded in the Lisbon Municipality, for the 12 weeks of the trial, namely average temperature (°C) and rainfall (mm), were retrieved from the regional platform “CLIMA.AML: Rede de Monitorização e Alerta Meteorológico Metropolitano” (URL: https://www.clima.aml.pt).
Statistical analysis
Calculations for mean values and standard errors were performed using the software IBM® SPSS® Statistics, version 27 for Windows (IBM Corporation, Armonk, NY, EUA), which was also used for all further statistical analysis. It was observed that the coccidia OPG data failed the Shapiro–Wilk normality test (n < 50 samples for every timepoint; p < 0.001). Thus, the coccidia OPG recorded in each test time point was compared with control using the Mann–Whitney test. Also, a correlation analysis was performed to assess a possible statistical association between coccidia OPG and the weather variables “average temperature” and “rainfall”, using the Spearman’s Test. A significance level of p < 0.05 was used for all statistical tests.
Ethical approval
This study was approved by the Ethical Committee for Research and Teaching of the Faculty of Veterinary Medicine—University of Lisbon (CEIE 019/2022) and also received the written consent of the bird collection owner. Fungal administrations and fecal samplings were performed without any direct manipulation of the animals, and the study followed the normal daily procedures of the peacock collection.
All methods were carried out in accordance with relevant guidelines and regulations, as well as authors complied with the ARRIVE guidelines.
Data availability
The datasets generated during the current study can be made available by requesting it from the Corresponding Author.
References
Ilić, T. et al. Prevalence of endoparasitic infections of birds in zoo gardens in Serbia. Acta. Parasitol. 63, 134–146 (2018).
Lolli, S., Grilli, G., Ferrari, L., Ferrari, P. & Ferrante, V. Effect of range use on endo- and ectoparasite infestation in italian organic egg production. Ital. J. Anim. Sci. 18, 690–695 (2019).
Lozano, J. et al. Gastrointestinal parasites of free-range chickens—a worldwide issue. Bulletin of university of agricultural sciences and veterinary medicine Cluj-Napoca. Vet Med 76, 110 (2019).
Carrera-Játiva, P. D., Morgan, E. R., Barrows, M., Jiménez-Uzcátegui, G. & Tituaña, J. R. Free-ranging avifauna as a source of generalist parasites for captive birds in zoological settings: An overview of parasite records and potential for cross-transmission. J Adv Vet Anim Res 7(3), 482. https://doi.org/10.5455/javar.2020.g445 (2020).
Andreopoulou, M., Chaligiannis, I., Sotiraki, S., Daugschies, A. & Bangoura, B. Prevalence and molecular detection of Eimeria species in different types of poultry in Greece and associated risk factors. Parasitol. Res. 121, 2051–2063 (2022).
Zhang, K. et al. First detection of coccidia species in blue peafowl (Pavo cristatus) in China via both microscopic and molecular methods. Vet. Parasitol. Reg. Stud. Rep. 36, 10087 (2022).
Mesa-Pineda, C., Navarro-Ruíz, J. L., López-Osorio, S., Chaparro-Gutiérrez, J. J. & Gómez-Osorio, L. M. Chicken coccidiosis: From the parasite lifecycle to control of the disease. Front. Vet. Sci. https://doi.org/10.3389/fvets.2021.787653 (2021).
McDougald, L. & Fitz-Coy, S. Parasitic Diseases—Coccidiosis. in Diseases of Poultry (ed. Saif, Y.) 1068–1085 (Blackwell Publishing Professional, Ames, Iowa, 2008).
Blake, D. P. et al. Re-calculating the cost of coccidiosis in chickens. Vet. Res. 51, 1–4 (2020).
Titilincu, A. et al. Prevalence of endoparasites in peacocks (Pavo cristatus). Sci. Parasitol. 1–2, 101–105 (2009).
Jaiswal, A. K., Sudan, V., Shanker, D. & Kumar, P. Endoparasitic infections in Indian peacocks (Pavo cristatus) of veterinary college campus Mathura. J. Parasit. Dis. 37, 26–28 (2013).
Alyousif, M. S. & Al-Shawa, Y. R. Two new coccidia (Apicomplexa:Eimeriidae) from the green peacock (Pavo muticus) from Saudi Arabia. Parasitol. Int. 47, 301–306 (1998).
Abbas, R. Z., Iqbal, Z., Blake, D., Khan, M. N. & Saleemi, M. K. Anticoccidial drug resistance in fowl coccidia: The state of play revisited. World’s Poult. Sci. J. https://doi.org/10.1017/S004393391100033X (2011).
Mund, M. D., Khan, U. H., Tahir, U., Mustafa, B. E. & Fayyaz, A. Antimicrobial drug residues in poultry products and implications on public health: A review. Int. J. Food Prop. 20(7), 1433–1446. https://doi.org/10.1080/10942912.2016.1212874 (2017).
Mooney, D. et al. An analysis of the spatio-temporal occurrence of anthelmintic veterinary drug residues in groundwater. Sci. Total Environ. 769, 144804 (2021).
Selzer, P. M. & Epe, C. Antiparasitics in animal health: Quo vadis?. Trends Parasitol. https://doi.org/10.1016/j.pt.2020.09.004 (2021).
Martins, R. R. et al. Coccidiostats and poultry: A comprehensive review and current legislation. Foods 11(18), 2738 (2022).
Braga, F. R. & Araújo, J. V. Nematophagous fungi for biological control of gastrointestinal nematodes in domestic animals. Appl. Microbiol. Biotechnol. https://doi.org/10.1007/s00253-013-5366-z (2014).
Falbo, M. K. et al. Isolation and characterization of the nematophagous fungus Arthrobotrys conoides. Parasitol. Res. 112, 177–185 (2013).
Liu, W. et al. Isolation, identification, and characterization of the nematophagous fungus Monacrosporium salinum from China. J. Basic Microbiol. 55, 992–1001 (2015).
Hernández, J. A. et al. Isolation of ovicidal fungi from fecal samples of captive animals maintained in a zoological park. J. Fungi 3, 29 (2017).
Ojeda-Robertos, N. F. et al. In vitro predatory activity of nematophagous fungi isolated from water buffalo feces and from soil in the Mexican southeastern. Rev. Brasileira de Parasit. Vet. 28, 314–319 (2019).
Arroyo-Balán, F. et al. High predatory capacity of a novel arthrobotrys oligospora variety on the ovine gastrointestinal nematode haemonchus contortus (Rhabditomorpha: Trichostrongylidae). Pathogens 10, 815 (2021).
Lozano, J. et al. Isolation of saprophytic filamentous fungi from avian fecal samples and assessment of its predatory activity on coccidian oocysts. Sci. Rep. 13, 8965 (2023).
Madeira de Carvalho, L., Bernardo, F. & Paz-Silva, A. The role of fungi in the control of animal parasites—classification, mode of action and practical applications. in Fungi: Types, Environmental Impact and Role in Disease (eds. Paz-Silva, A. & Vázquez, M.) (Nova Science Publishers, Hauppauge, NY, USA, 2012).
Viña, C. et al. A new comestible formulation of Parasiticide Fungi to reduce the risk of soil-transmitted helminth infections in a Canine Shelter. Pathogens 11, 1391 (2022).
Healey, K. et al. Field evaluation of Duddingtonia flagrans IAH 1297 for the reduction of worm burden in grazing animals: Pasture larval studies in horses, cattle and goats. Vet. Parasitol. 258, 124–132 (2018).
Branco Oliveira, L. et al. Bioverm® in the control of nematodes in beef cattle raised in the central-west region of Brazil. Pathogens 10, 548 (2021).
Voinot, M. et al. Control of strongyles in first-season grazing ewe lambs by integrating deworming and thrice-weekly administration of parasiticidal fungal spores. Pathogens 10, 1338 (2021).
Madeira de Carvalho, L. et al. Controlo integrado da Estrongilidose equina com anti-helmínticos associados ao fungo Duddingtonia flagrans. Aspectos da sua utilização em Portugal. Acta Parasitol. Portuguesa 18, 63–90 (2011).
Arias, M. et al. A preliminary study of the biological control of strongyles affecting equids in a zoological park. J. Equine. Vet. Sci. 33, 1115–1120 (2013).
Canhão-Dias, M., Paz-Silva, A. & de Carvalho, L. M. The efficacy of predatory fungi on the control of gastrointestinal parasites in domestic and wild animals—A systematic review. Vet. Parasitol. 1(283), 109173. https://doi.org/10.1016/j.vetpar.2020.109173 (2020).
Araujo, J. M. et al. Survival of Pochonia chlamydosporia in the gastrointestinal tract of experimentally treated dogs. Res. Vet. Sci. 93, 803–806 (2012).
Cazapal-Monteiro, C. F. et al. Analysis of the effect of soil saprophytic fungi on the eggs of Baylisascaris procyonis. Parasitol Res 114, 2443–2450 (2015).
Palomero, A. M. et al. Formulating fungal spores to prevent infection by trichostrongylids in a zoological park: Practical approaches to a persisting problem. Biol. Control 152, 104466 (2021).
Paz-Silva, A. et al. Gelatin treats containing filamentous fungi to promote sustainable control of helminths among pets and zoo animals. Biol. Control 179, 105184 (2023).
Salmo, R. et al. Saprophytic Filamentous fungi against helminths affecting captive wild animals. Encyclopedia 4, 91–100 (2024).
Braga, F. et al. First report of interaction of nematophagous fungi on Libyostrongylus douglassii (Nematoda: Trichostrongylidae). Rev. Bras. Parasitol. Vet. 22, 147–151 (2013).
Silva, M., Silveira, W., Braga, F. & Araújo, J. Nematicide activity of microfungi (Orbiliales, Orbiliaceae) after transit through gastrointenstinal tract of “Gallus gallus domesticus”. Rev. Brasileira de Saúde e Produção Anim. 18, 1–9 (2017).
Thapa, S. et al. Effect of the nematophagous fungus Pochonia chlamydosporia on soil content of ascarid eggs and infection levels in exposed hens. Parasit. Vectors 11, 319 (2018).
Valadão, M. C. et al. Germination capacity of the Pochonia chlamydosporia fungus after its passage through the gastrointestinal tract of domestic chickens (Gallus gallus domesticus). Exp. Parasitol. 216, 107936 (2020).
Lozano, J., Almeida, C., Oliveira, M., Paz-Silva, A. & Madeira Carvalho, L. Biocontrol of avian gastrointestinal parasites using predatory fungi: Current status, challenges, and opportunities. Parasitologia 2, 37 (2022).
Araújo, J. V., Braga, F. R., Mendoza-de-Gives, P., Paz-Silva, A. & Vilela, V. L. R. Recent advances in the control of helminths of domestic animals by helminthophagous fungi. Parasitologia https://doi.org/10.3390/parasitologia1030018 (2021).
Yang, J., Liang, L., Li, J. & Zhang, K. Q. Nematicidal enzymes from microorganisms and their applications. Appl. Microbiol. Biotechnol. https://doi.org/10.1007/s00253-013-5045-0 (2013).
Braga, F. R. et al. Nematocidal activity of extracellular enzymes produced by the nematophagous fungus Duddingtonia flagrans on cyathostomin infective larvae. Vet. Parasitol. 212, 214–218 (2015).
Herrera-Estrella, A., Casas-Flores, S. & Kubicek, C. P. Nematophagous Fungi. in Environmental and Microbial Relationships (eds. Druzhinina, I. & Kubicek, C.) vol. 4, 247–267 (Springer, 2016). https://doi.org/10.1007/978-3-319-29532-9_13
de Freitas Soares, F. E., Ferreira, J. M., Genier, H. L. A., Al-Ani, L. K. T. & Aguilar-Marcelino, L. Biological control 2.0: Use of nematophagous fungi enzymes for nematode control. J. Nat. Pestic. Res. 4, 100025 (2023).
Ahad, S., Tanveer, S. & Malik, T. A. Seasonal impact on the prevalence of coccidian infection in broiler chicks across poultry farms in the Kashmir valley. J. Parasit. Dis. 39, 736–740 (2015).
Shamim, A. et al. Occurrence and identification of Emeria species in broiler rearing under traditional system. J. Anim. Sci. Technol. 57, 1–4 (2015).
Cortiñas, F. J. et al. Potential use of Mucor circinelloides for the biological control of certain helminths affecting livestock reared in a care farm. Biocontrol Sci. Technol. 25, 1443–1452 (2015).
Oliveira, I. C. et al. Evaluation of nematophagous fungal mycelial growth and interactions with bovine gastrointestinal parasitic nematodes. Ger. J. Vet. Res. 2, 39–45 (2022).
Wang, B. et al. Effect of temperature, pH, physical and chemical factors on germination rate of the chlamydospores of the nematophagous fungus Duddingtonia flagrans. FEMS Microbiol. Lett. 366, 212 (2019).
Attree, E. et al. Controlling the causative agents of coccidiosis in domestic chickens: An eye on the past and considerations for the future. CABI Agric. Biosci. https://doi.org/10.1186/s43170-021-00056-5 (2021).
Cringoli, G. et al. The Mini-FLOTAC technique for the diagnosis of helminth and protozoan infections in humans and animals. Nat. Protoc. 12, 1723–1732 (2017).
Maurelli, M. P. et al. A Qualitative market analysis applied to Mini-FLOTAC and fill-FLOTAC for diagnosis of helminth infections in ruminants. Front. Vet. Sci. 7. https://doi.org/10.3389/fvets.2020.580649 (2020).
Bortoluzzi, C., Paras, K. L., Applegate, T. J. & Verocai, G. G. Comparison between McMaster and Mini-FLOTAC methods for the enumeration of Eimeria maxima oocysts in poultry excreta. Vet. Parasitol. 254, 21–25 (2018).
Coker, S. M. et al. Comparing the Mini-FLOTAC and centrifugal faecal flotation for the detection of coccidia (Eimeria spp.) in kiwi (Apteryx mantelli). Parasitol Res 119, 4287–4290 (2020).
Daş, G., Klauser, S., Stehr, M., Tuchscherer, A. & Metges, C. C. Accuracy and precision of McMaster and Mini-FLOTAC egg counting techniques using egg-spiked faeces of chickens and two different flotation fluids. Vet. Parasitol. 283, 109158 (2020).
Lozano, J. et al. Implementation of Mini-FLOTAC in routine diagnosis of coccidia and helminth infections in domestic and exotic birds. Vet. Sci. 8, 160 (2021).
Lozano, J. et al. Diagnosis of coccidiosis by Eimeria spp. in free-range chickens using Mini-FLOTAC and McMaster techniques—preliminary results. Sci. Parasitol. 22, 13–18 (2021).
Hernández, J. Á. et al. Feeding horses with industrially manufactured pellets with fungal spores to promote nematode integrated control. Vet. Parasitol. 229, 37–44 (2016).
Voinot, M. et al. Safety of daily administration of pellets containing parasiticidal fungal spores over a long period of time in heifers. Biocontrol. Sci. Technol. 32, 1249–1259 (2022).
Vilela, V. et al. Coadministration of nematophagous fungi for biological control over gastrointestinal helminths in sheep in the semiarid region of northeastern Brazil. Vet. Parasitol. 221, 139–143 (2016).
Kaboudi, K., Umar, S. & Munir, M. T. Prevalence of coccidiosis in free-range chicken in Sidi Thabet Tunisia. Scientifica 2016, 1 (2016).
Vilela, V. L. R. et al. Biological control of goat gastrointestinal helminthiasis by Duddingtonia flagrans in a semi-arid region of the northeastern Brazil. Vet. Parasitol. 188, 127–133 (2012).
Arias, M. et al. Mixed production of filamentous fungal spores for preventing soil-transmitted helminth zoonoses: A preliminary analysis. Biomed. Res. Int. 2013, 1 (2013).
Acknowledgements
This work was supported by the CIISA/FMV Project UIDB/00276/2020 and LA/P/0059/2020—AL4AnimalS (both funded by FCT), and by the Projects PID2020-120208RB-I00 (MCINN, Spain; FEDER) and ED431B 2021/07 (funded by Consellería de Cultura, Educación e Universidades, Xunta de Galicia). Additionally, João Lozano holds the PhD Research Fellowship 2020.09037.BD (funded by FCT). The authors would like to acknowledge the Laboratory of Parasitology and Parasitic Diseases (CIISA-FMV, Lisbon, Portugal), Laboratory of Microbiology and Immunology (CIISA-FMV, Lisbon, Portugal), and the COPAR research group (Faculty of Veterinary, USC, Lugo, Spain), and their leaders, Professors Doctors Isabel Fonseca, Luís Tavares, and Adolfo Paz-Silva, for all the support provided during this research. We are also grateful to Dr. Maria Antónia Amaral, Director of São Jorge Castle (Lisbon), for allowing us to perform this research at her facilities, and for all the crucial collaboration and assistance provided by her team during this in vivo trial.
Author information
Authors and Affiliations
Contributions
JL designed the study, provided resources, performed the experiment, curated the data, analysed the results, and wrote the original draft of the manuscript. CA provided resources and collaborated on the experiment. EV provided resources and collaborated on the experiment. DS provided resources, collaborated on the experiment, and co-supervised the study. AMP provided resources and revised the manuscript. CCM provided resources and revised the manuscript. MSA provided resources and revised the manuscript. MO provided resources, collaborated in the experiment, revised the manuscript, and co-supervised the study. LMC provided resources, collaborated in the experiment, revised the manuscript, and co-supervised the study. APS provided resources, collaborated in the experiment, revised the manuscript, and supervised the study. All authors have read this manuscript and agreed to submit.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Lozano, J., Almeida, C., Vicente, E. et al. Assessing the efficacy of the ovicidal fungus Mucor circinelloides in reducing coccidia parasitism in peacocks. Sci Rep 14, 11352 (2024). https://doi.org/10.1038/s41598-024-61816-7
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-024-61816-7
Keywords
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.