Identification of keratinophilic fungi in the coat microbiota of anteaters retained in captivity in two Brazilian Zoos

Anteaters comprise three different species: Myrmecophaga tridactyla (flag anteater), Tamandua tetradactyla (mini anteater) and Cyclopes didactylus (anteater), some considered vulnerable to extinction. These species are distributed over a large part of the Brazilian territory, especially in the cerrado biome. In order to preserve these species, some research work on the health status of these animals has been carried out, both in captive and free-living animals. The objective of this study was to investigate keratinophilic filamentous fungi, including dermatophytes, in the coat of 27 adult anteaters retained in captivity. Among the animals studied, 14 were giant anteater (Myrmecophaga tridactyla) and 13 were small anteater (Tamandua tetradactyla). These specimens were retained at the São Paulo Zoological Park Foundation and Quinzinho de Barros Municipal Zoological Park. Samples were obtained by means of rubbing sterilized squares of carpet on the coat of each animal. Each carpet was seeded in Petri dishes containing MycobioticTM agar medium (DifcoTM) and incubated at 25oC until colony growth was observed. Dermatophytes were not isolated; however, the following genera of filamentous fungi were identified: Cladosporium spp. (51.8%), Scopulariopsis sp (29.6%), Aspergillus spp. (22.2%), Acremonium spp. and Chrysosporium spp. (11.1%) and Mucor spp. (7.4%), among these we highlight the keratinophilics: Scopulariopsis sp, Acremonium spp. and Chrysosporium spp. There are few studies on the prevalence of dermatophytes and other keratinophilics in wild animals and none on anteaters. It was possible to confirm the presence of non-dermatophytic keratinophilics in the normal microbiota of anteaters, similarly to what was observed in other mammals.


Introduction
Biodiversity is essential for the survival of humanity and its intrinsic and extrinsic value has been widely recognized by means of governments and civil society in several international agreements (Peres et al, 2011). It is believed that in Brazil there are approximately 1.8 million known species among plants and animals, of which 210 thousand are invertebrate and vertebrate animals distributed in 541 species of mammals, 1696 species of birds and more than 5000 species including reptiles, amphibians and fishes. This number is much higher according to estimates by means of Lewinsohn and Prado (2005). The Brazilian fauna is one of the largest and most important in the world, corresponding to 13% of the world's biota divided into biomes: Amazon Forest, Atlantic Forest, Caatinga, Cerrado, Pantanal and Campos Sulinos (Benites & Mamede, 2008) and its loss is one of the worst current global crises, with species and habitats decreasing at an alarming rate as ilustrated since 2008 by means of the Red List of Endangered Species of some national and international preservation institutions (Vié et al, 2009).
The intense environmental degradation has fragmented forests where more than a half of the cerrado area has been transformed into pastures or grain plantations (Rambaldi & Oliveira, 2005;Klink & Machado, 2005). According to the Biodiversitas Foundation: "One of the biggest challenges for governments is the definition of strategic plans for the conservation of biodiversity" (Fundação Biodiversitas, 2010), since human activity can lead to environmental degradation and compromise the survival of species (Fundação Zoo-botânica, 2000). Professionals from numerous areas of the science, governmental and non-governmental organizations, including veterinarians, biologists and environmentalists have dedicated a large effort to the conservation of endangered species and this effort is translated through increasing studies and researches in the area of the national flora and fauna. Some institutions such as the International Union for the Conservation of Nature (IUCN) have created lists (IUCN "Red List") based on worldwide research and databases to define endangered species and it works for the conservation of these species around the world (IUCN, 2021).
IUCN is a union of partners composed exclusively of governmental and civil society organizations in which it provides public, private and non-governmental organizations with the knowledge and tools that enable human progress, economic development and nature conservation to occur together (IUCN, 2021). The update of the "Red List" carried out in September 2017 placed the giant anteater on a scale of least concern (IUCN, 2021); the small anteater and the silky anteater did not enter the list, revealing that the efforts made have had a positive result (Project Tamanduá, 2015). In Brazil, organizations such as the Instituto Brasileiro do Meio Ambiente e Recursos Naturais Renovaveis (IBAMA) and the Instituto de Pesquisa e Conservação do Tamanduá no Brasil (Projeto Tamanduá) carry out different works for the conservation and development of these and other endangered species. IBAMA is a government institution linked to the Ministério do Meio Ambiente (MMA) created in 1989 with the aim of exercising the power of federal environmental police with an important role in environmental licensing, environmental quality control, authorization for the utilization of natural resources and inspection, monitoring and environmental control (IBAMA, 2017) in which it works together with non-governmental organizations such as the Projeto Tamanduá, which aims to preserve animals that have been thus little studied in this case, the Anteaters, Armadillos and Sloths (Xenarthra); developing research in the wild, working in partnership with national and international screening centers and zoos, developing a database and biological samples, acting strongly in public policy actions with the Brazilian government (Projeto Tamanduá, 2015).
Three species of anteaters are currently known, natives of the Brazilian cerrado and belonging to the order Xenarthra, of the Myrmecophagidae family, Myrmecophaga trydactyla (giant anteater), Tamanduá trydactyla (small anteater) e o Cyclopes didactylus (silky anteater) from the family Cyclopedidae (Cubas et al, 2014). These animals are solitary mammals with twilight habits, their body color is dark gray mixed with white, the fore limbs are whitish and the hind limbs are black (Vieira, 1949& Braga, 2010. They can reach more than two meters in length and weigh more than 39 kg (Wetzel, 1985;Eisenberg, 1989;Drummond, 1994;Braga, 2010). They have nails that measure up to 6.5 cm, important structures for their diet according to Carvalho (1996) and Braga (2010), as they assist to open anthills and termite mounds and moreover as a defense (Rossoni et al, 1981, Braga, 2010Nowak, 2018); in addition to having a series of morphological adaptations such as the absence of teeth and well-developed salivary glands, as well as the tongue, which can extend up to 61 cm outside the mouth (Rossoni et al, 1981;Chebez, 1994;Emmons, 1997, Braga, 2010, Nowak, 2018, Teta et al, 2018. Its diet is exclusive to insects, mainly from the orders Hymenoptera (ants) and Isoptera (termites) (Montegomery, 1985;Shaw et al, 1985;Medri et al, 2003& Zimbres, 2010. As Rosa (2007) states: "The giant anteater has energy limitations due to its energy-poor diet, thus it has some characteristics to compensate for these limitations, such as low metabolism and low temperature and thermal conductance".
Temperature and dietary restriction have been depicted as stressors for rabbits, influencing the immune response (Franci et al., 1996;Acco, 1999). Among the main stressors for wild and domestic animal species are physical containment and transport, which are therefore utilized as models of stressors in research (Morton et al., 1995& Acco, 1999. These and other innovations such as confinement, change the temperament and behavior of animals, contributing to the incidence of stress on the species (Bispo & Pereira, 1994;Carramenha, 2012) in addition to threats to the survival of these species through predatory hunting, roadkill, the loss of its habitat due to gradual deforestation due to agricultural expansion, fires and animal trafficking, a definitely common practice in underdeveloped countries (IUCN, 2021;IBAMA, 2016;Projeto Tamanduá, 2015). It is known that animals in captivity may demonstrate considerable differences in their microbiota because, according to Acco (1999), the stress of confinement can influence animal behavior and possibly the immune response of animals in captivity. As it is a Research, Society and Development, v. 11, n. 2, e11311225497, 2022 (CC BY 4.0) | ISSN 2525-3409 | DOI: http://dx.doi.org/10.33448/rsd-v11i2.25497 specimen of wild habits, it could suffer from a probable infection due to contact with fomites contaminated with the presence of opportunistic fungi in the environment (even if the enclosure undergoes disinfection processes) developing eventual skin diseases.
Fungi are microorganisms belonging to the Fungi Kingdom, classified into Chytridiomycetes, Zygomycetes, Ascomycetes and Basidiomycetes, composed of eukaryotic cells that present DNA surrounded by means of a nuclear membrane; they can be unicellular (yeasts) or pluricellular (mushrooms), classified as saprobes (dependent on dead organic matter) or biotrophic (dependent on living organic matter), widely dispersed in the environment and additionally present in the microbiota of humans and animals (Paula et al. , 2007). According to Paula et al (2007), most of these fungi develop at a pH close to 6.0 and a temperature between 25ºC and 30ºC; are easily sown in culture media where their growth and form varies according to the type of fungus: molds (hyphae-forming filamentous fungi), yeasts (spherical non-filamentous fungi) and dimorphic ones (they have both forms of growth -usually pathogenic fungi) . Fungi reproduce asexually and sexually, are of extreme ecological importance since they are found in tree trunks, plants, soil and other organic materials, widely utilized in the pharmaceutical and food industries and some with pathogenic characteristics, which is why biologists have classified the fungi in the seventies creating the Kingdom Fungi, which is divided into three groups: slime fungi, inferior flagellate fungi and terrestrial fungi that include: mushrooms, yeasts and molds (Lacaz, et al, 2002). There are few studies on the prevalence of dermatophytes in wild animals and none on anteaters in this way, the present study consists of researching the presence of dermatophytes and other potentially pathogenic keratinophilic fungi in captive anteater coat in order to assist and expand the conservation of the considered species vulnerable to extinction (IUCN, 2021).
Based on the scarcity of studies on the health aspect of wild animals, as well as some important predictive microbiological parameters for disease prevention, monitoring and even therapeutic interventions, the aim of this study was to investigate the possible presence of dermatophytes and other filamentous fungi with keratinophilic nature as resident and/or transient members in the surface microbiota of the integument of two of the three species of anteaters maintained as a biomaterial reserve in conservation institutions in Brazil.

Samples
In the present study, 27 animals were utilized, including giant anteaters and anteaters, all from the Fundação Parque Zoológico de São Paulo (FPZSP), located in the city of São Paulo; Quinzinho de Barros Municipal Zoological Park (PZMQB), located in Sorocaba-SP; and a specimen from the Pantanal Mato-grossense which, at the time this research was carried out, was contained and submitted for evaluation in field activity by means of the Working Group for the Conservation of Anteater in Brazil (GTCT). Of these, 14 individuals were giant anteaters (Myrmecophaga tridactyla) and 13 are small anteaters (Tamandua tetradactyla), all specimens in their adult phase, with the predominant situation being captivity.

Sample collection and processing
After physical restraint of the animals, coat samples were obtained by means of rubbing previously sterilized squares of carpet over the back of each animal. They were sent aseptically and under refrigeration to the Laboratory of Molecular and Cell Biology (UNIP), where they were seeded, by means of printing, in Petri dishes containing Mycobiotic™ agar (Difco™) and incubated at 25ºC. Each plate was inspected every two days for four weeks or until growth of filamentous fungal colonies was noted (Mariat & Adam-Campos, 1967, Bentubo et al, 2006Bentubo et al, 2021).

Identification of fungi
The filamentous fungi obtained in the cultivation of samples collected from the skin of the specimens studied were identified by means of their macro and microscopic morphological characteristics. To verify the macroscopic characteristics, giant colonies were produced in Petri dishes containing the same medium utilized for the priming isolation. To obtain preparations that allowed the analysis of the microscopic morphology of the isolates, a classical method based on the microculture slide technique was utilized (Riddel, 1950). Taxonomic manuals were utilized as a reference for comparing the visible structures in the macro and microscopy of the isolates (Kurtzman & Fell, 1998;De Hoog et al, 2004).

Results and Discussion
Research works related to the health aspects of wildlife animals are still quite limited. The scientific community's concern with the environment and the required conserve endemic fauna has stimulated pioneering initiatives across the country. This is the case of the Working Group for the Conservation of Anteaters in Brazil (Projeto Tamanduá The technique of the square of carpet rubbed over the back, originally depicted by means of Mariat & Adam-Campos (1967) to obtain samples for the isolation of filamentous fungi. Its use for this purpose has already been experimented and proven in previous researches (Bentubo et al, 2006) including for yeasts and in this same animal species (Bentubo et al, 2021) ( Figure 1). By means of analyzing the macroscopic morphology of the isolates obtained in culture, it was possible to establish a correspondence with the probable genus of the filamentous fungus, as depicted in the taxonomic manuals utilized in this analysis. Riddel's (1950) technique of cultivation on slides, which was utilized for micro morphological visualization of the isolates, confirmed the suspicions regarding the identification of the isolates (Kurtzman & Fell, 1998;De Hoog et al, 2004). Research, Society and Development, v. 11, n. 2, e11311225497, 2022 (CC BY 4.0) | ISSN 2525-3409 | DOI: http://dx.doi.org/10.33448/rsd-v11i2.25497 6 ( Figure 2A). Dermatophytic fungi were not isolated from any of the animals studied; however, it was possible to isolate other keratinophilic genera from the coat of the studied anteaters. We highlight Scopulariopsis sp, Acremonium spp. and Chrysosporium spp. ( Figure 2B). Initially, the morphological findings observed for the identification of these isolated genera will be discussed. The isolate prevalent in this research, of the Cladosporium genus, is considered one of the most common filamentous fungi in the environment. These molds have a great capacity to colonize different substrates and are easy to grow in definitely limited environmental conditions (Gambale et al, 1993), for this reason they were additionally found in such a high frequency in the anteaters investigated in this research. They are considered among the fungi with the highest concentration in the atmosphere, mainly in tropical and sub-tropical climate regions (Zoppas et al, 2011). Menezes et al (2017) depicted the fungi of this genus as endowed with great adaptive capacity, capacity for contamination and colonization of different environments, as it was possible to verify in this study, where this genus was isolated from the integument of several species of anteater studied. As observed by means of other authors, in this research, the macro morphological evaluation of Cladosporium spp. demonstrated a naturally brownish coloration due to the presence of melanin pigment in its cell wall (Zaits et al, 2010& Sidrim & Rocha, 2003. Another genus of isolated fungi, Scopulariopsis sp, whose most common habitat is the soil, demonstrated a slow growth rate. Its macro morphological description was compatible with its sandy texture, velvety center and color that varied from white to beige. Both the macro and microscopic characteristics observed in the present research were compatible with those depicted in the literature (Sidrim & Rocha, 2003;López-Jodra & Torres-Rodrigues, 1999). The genus Aspergillus, the third most common filamentous fungus found in the normal anteater coat microbiota, is ubiquitous and can be isolated from definitely common places such as air, soil, water, food, plants, and a wide variety of inanimate surfaces (Ward et al, 2006). The isolates obtained in this research demonstrated a predominance of yellowish green coloration; however the literature considers that the genus can present colonies of green, yellow, brown and white coloration (Klich, 2002;Varga et al, 2004).
In this research, there was a prevalence of the genera Cladosporium spp. and Scopulariopsis sp. In a study carried out by means of Albano (2009), the genera Aspergillus and Scopulariopsis were found to be highly prevalent in the coat of felids, canids, marsupials, edentates, primates and rodents. Although the characteristics of the isolates obtained in this study are

A B
Research, Society andDevelopment, v. 11, n. 2, e11311225497, 2022 (CC BY 4.0) | ISSN 2525-3409 | DOI: http://dx.doi.org/10.33448/rsd-v11i2.25497 compatible with those found by means of Albano (2009), in no anteater there was any clinical manifestation of infection and the isolates only appeared to be part of the normal microbiota of the specimens studied. However, there are already references to the pathogenic power of these fungi. Menezes et al (2017) reported in their research that the genus Cladosporium spp. it can cause from epithelial lesions, such as keratitis, with organ involvement, to the development of brain abscesses (Oliveira et al, 2001). Infections can progress to sepsis with consequent death in humans. In animals, it causes epithelial mycoses and fungal sinusitis in immunocompromised patients, the main causes being C. bantiana, C. carrioni and C. devriesii (Bensch et al, 2012).
Scopulariopsis spp. pathogenic agents for animals and men are recognized (Filipello Marchisio et al, 2000;Nenoff et al, 2014), having already been observed acting as an etiological agent in dermatomycosis processes in domestic animals (Petanović et al, 2010). Ogawa et al (2008) reported a case of generalized infection by means of Scopulariopsis brevicaulis in a calf. The Aspergillus genus is known for its ability to produce toxic metabolites, well known in pathological processes called mycotoxicosis. These poisonings can affect animals and man. The best known mycotoxicosis is aflatoxicosis, a disease produced by means of aflatoxin, which is capable of developing respiratory conditions in the patient that can progress to sepsis in immunocompromised patients. These opportunistic conditions can even be associated with invasive pulmonary aspergillosis (Alves, 2017). Even in humans, there are descriptions in the literature in which the authors claim that aflatoxicosis can cause serious liver diseases, such as cancer, as aflatoxin has a necrotizing effect on this tissue (Oliveira & Germano, 1997& Oliveira, 2016. The pathogenesis of these fungal infections, when depicted in the literature, consists of mycotic skin diseases in humans and animals. Fungi found in animals can cause opportunistic mycotic infections, requiring monitoring for early diagnosis and control of these infections (Nobre et al, 1998, Naglik et al, 2004, Anaisse et al, 2009Alves, 2017). At first, the simple presence of these fungi in the microbiota of the studied animals may not represent a health problem. However, when these findings are added to immunocompromising factors, the meaning of these findings may change. Inadequate maintenance in captivity, poor nutrition, unhealthy sanitary conditions, stress, prolonged antibiotic therapy, climatic factors such as humidity, pH, temperature and type of substrate can be conditions that favor the prevalence and/or exaggerated proliferation of these agents that fabricate the normal microbiota of animals, taking these microorganisms from the commensal relationship to parasitism, when they can become pathogenic for their hosts.
The fungi of the genus Acremonium presented a macroscopic morphology slightly different from that observed in the previous isolates, forming colonies with a cottony appearance and white color with a slight pinkish hue in the center. That observation was not compatible with the description by means of Zhang et al (2012), who observed a slightly brownish hue in the isolates obtained in their research, something unusual for a hyaline fungus such as Acremonium spp. The microscopic morphology must present characteristics such as the presence of oval conidia, little elongated and even arcuate, with intercalated chlamydoconidia and septate hyphae. In this study, the isolates of Acremonium sp analyzed demonstrated definitely similar forms, with the exception of the chlamydoconidia (Novicki et al, 2003;Summerbell & Schroers, 2002).
Definitely contradictory references can be found in the scientific literature when we consider the pathogenicity of Acremonium Interestingly, both in the case of Thomas et al (2002) and Delgado et al (2017) the infection affected the skin; however it proved fatal in the case of the crocodile. Since the management of a gigantic and dangerous prehistoric reptile in captivity is extremely delicate, perhaps the difference between the prognosis observed for crocodile and the iguana perhaps was associated with the early diagnosis in the iguana.
The genus isolated with less frequency in the present research was the genus Mucor. In culture, the isolate demonstrated exuberant growth on the plate. The colony had a cottony, soft appearance; initially yellowish white color, which with maturity turned dark gray. Microscopically, the isolates had sporangiophores that were erect and were simple or branched and globose. These characteristics are compatible with those depicted by means of Alves et al (2002). Infections caused by means of zygomycetes may have different epidemiological characteristics, depending on the Order to which they belong.
Those belonging to the Orderm Entomoftorales usually affect immunocompetent individuals. The Order Mucorales are most commonly associated with infection in immunocompromised patients. In the case report by means of Xavier (2004), a decompensated diabetic patient who was affected by means of Mucor sp developed fungal sinusitis and consequent rhinocerebral mucormycosis. In this case, surgical intervention and systemic treatment with Amphotericin B were necessary to control the infection. However, there are researchers who alert to the possibility that the fungus additionally affects immonocompetent individuals (Santana et al, 2001).

Final Considerations
Through the present investigation, it was possible to conclude that non-dermatophytic keratinophilic fungi colonize the coat surface of giant anteaters and baby anteaters retained in captivity. Therefore, the staff involved with the maintenance of these animals must be aware of the predisposing factors for opportunistic infection for animals in captivity and examinations with the purpose of monitoring, both the environment and the animals inserted in them, must be carried out thus that it is possible to attribute a predictive character of infections when the risks are present in the context. The negative result for dermatophyte fungi should not be understood as an immutable condition, since the conditions found in this research were quite limited, not including such a wide sampling or the diversity found in a country with continental dimensions like Brazil. Future research should consider different environments, including free-living, as well as little-studied species such as the silky anteater (Cyclopes didactylus), a species not included in this investigation.