ABSTRACT:
In Brazil, the Atlantic Forest has been suffering from deforestation, which has had impacts on its flora, fauna, and microbiota. However, the fungal diversity present in these environments is little known and studied. In this study, a total of 90 samples of 45 wild birds (45 feathers and 45 feces) were collected in Ilha da Marambaia, southeastern Brazil. Filamentous fungi isolated from these samples were identified through macroscopic and microscopic characteristics. Some isolates were identified by molecular biology using the PCR technique. Acremonium, Alternaria, Aspergillus, Cunninghamella, Curvularia, Eurotium, Fusarium, Geotrichum, Neosartorya, Pestalotia, Paecilomyces, Penicillium, Rhizopus, Mucor and Syncephalastrum were identified. These results indicate the presence of saprophytic fungi species in the feathers and feces of wild birds of the capture site. Further studies should be conducted to elucidate if the mycobiota profile modifies with anthropization and if it interferes with bird health and environmental recovery.
INDEX TERMS:
Fungi; microbiota; passerines; Atlantic Forest
RESUMO:
No Brasil, a Mata Atlântica vem sofrendo com o desmatamento, que tem impactado sua flora, fauna e microbiota. No entanto, a diversidade fúngica presente nesses ambientes é pouco conhecida e estudada. Neste trabalho, um total de 90 amostras de 45 aves silvestres (45 penas e 45 fezes) foram coletadas na Ilha da Marambaia, Sudeste do Brasil. Fungos filamentosos isolados dessas amostras foram identificados por meio de características macroscópicas e microscópicas. Alguns isolados foram identificados por biologia molecular usando a técnica de PCR. Foram identificados Acremonium, Alternaria, Aspergillus, Cunninghamella, Curvularia, Eurotium, Fusarium, Geotrichum, Neosartorya, Pestalotia, Paecilomyces, Penicillium, Rhizopus, Mucor e Syncephalastrum. Esses resultados indicam a presença de espécies de fungos saprofíticos nas penas e fezes de aves silvestres do local de captura. Novos estudos devem ser realizados a fim de elucidar se o perfil da micobiota se modifica com a antropização e se interfere na saúde das aves e na recuperação ambiental.
TERMOS DE INDEXAÇÃO:
Fungos; microbiota; pássaros; Mata Atlântica
Introduction
In Brazil, a high variety of bird species can be found, being among the three countries with the greatest diversity of birds in the world. In this context, the Atlantic Forest, a tropical forest biome that covers the east, northeast, southeast, and south coast of Brazil, is among the top five in the list of world hotspots, even though its remaining area is less than 8% of its original extension (Schweizer et al. 2022Schweizer D., Petter G., César R.G., Ferraz S., Moreno V.S., Brancalion P.H.S. & Bugmann H. 2022. Natural forest regrowth under different land use intensities and landscape configurations in the Brazilian Atlantic Forest. For. Ecol. Manag. 508:120012. <https://dx.doi.org/10.1016/j.foreco.2022.120012>
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). The loss and fragmentation of habitats and biopiracy are the main threats to its biodiversity, generating direct impacts on the fauna, flora, and microbiota (Lindström 1999Lindström J. 1999 Early development and fitness in birds and mammals. Trends Ecol. Evol. 14(9):343-348. <https://dx.doi.org/10.1016/S0169-5347(99)01639-0> <PMid:10441307>
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). Within this biome, Marambaia Island is considered a biological reserve, which constitutes an environmental preservation area in accordance with Decree No. 9802 of March 12, 1987. The region is administered by the Brazilian Army, Air Force, and Navy, where they carry out armament experiments and military exercises. Moreover, around 430 remaining “quilombolas” are present in the area, making their living from fishing and agriculture. Access to the Island is restricted, which is only possible through navy vessels and with prior authorization (ICMBio 1987ICMBio 1987. Decreto nº 9.802 de 12 de março de 1987. Instituto Chico Mendes de Conservação da Biodiversidade. Available at <Available at http://www.icmbio.gov.br > Accessed on Nov. 1, 2021.
http://www.icmbio.gov.br...
, Lima et al. 2020Lima D.A., Novo S.P.C., Santos F.N. & Maciel E.M.S.G. 2020. Aspectos epidemiológicos, sociais e ambientais relacionados a transmissão e ao controle da leishmaniose visceral canina na Ilha da Marambaia, Mangaratiba - Rio de Janeiro. Revta Saúde Meio Amb. 10(1):157-174.).
Pollination, insect control, and seed dispersal are examples of how birds act in the ecosystem chain (Howard 2003Howard D.H. 2003. Pathogenic Fungi in Humans and Animals. Marcel Dekker, New York. 808p.). These birds are among the animals that can act as reservoirs and dispersers for various microbial agents such as fungi, which can associate with feathers, when bumping into some substrate, and also with internal organs, entering through the air pathways and orally (Howard 2003Howard D.H. 2003. Pathogenic Fungi in Humans and Animals. Marcel Dekker, New York. 808p., Reding 2003Reding P. 2003. Fungal diseases, p.275-291. In: Samour J. (Ed.), Avian Medicine. Edinburgh, UK., Oliveira et al. 2022Oliveira J., Bonci M.M., Conceição A.B.S., Silva L.G., Barone F.A., Berto B.P. & Oliveira Á. 2022. Fungi isolated from wild birds and litter in the Itatiaia National Park in Southeastern Brazil. Biodiv. Bras. 12(4):1-10. <https://dx.doi.org/10.37002/biodiversidadebrasileira.v12i4.2261>
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). Fungi are agents of the decomposition of organic matter and can be found in pollen, seeds, and soil (Simi et al. 2019Simi W.B., Leite Jr. D.P., Paula C.R., Hoffmann-Santos H.D., Takahara D.T. & Hahn R.C. 2019. Yeasts and filamentous fungi in psittacidae and birds of prey droppings in midwest region of Brazil: a potential hazard to human health. Braz. J. Biol. 79(3):414-422. <https://dx.doi.org/10.1590/1519-6984.181192> <PMid:30304251>
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, Kraisitudomsook et al. 2021Kraisitudomsook N., Healy R.A. & Smith M.E. 2021. Molecular systematics and taxonomic overview of the bird’s nest fungi (Nidulariaceae). Fungal. Biol. 125(9):693-703. <https://dx.doi.org/10.1016/j.funbio.2021.04.003> <PMid:34420696>
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). Furthermore, many of these are opportunistic, that is when in contact with immunocompromised hosts, they can cause disease (Pitt 1994Pitt J.I. 1994. The current role of Aspergillus and Penicillium in human and animal health. J. Med. Vet. Mycol. 32(Supl.1):17-32. <https://dx.doi.org/10.1080/02681219480000701>
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, Simi et al. 2019Simi W.B., Leite Jr. D.P., Paula C.R., Hoffmann-Santos H.D., Takahara D.T. & Hahn R.C. 2019. Yeasts and filamentous fungi in psittacidae and birds of prey droppings in midwest region of Brazil: a potential hazard to human health. Braz. J. Biol. 79(3):414-422. <https://dx.doi.org/10.1590/1519-6984.181192> <PMid:30304251>
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).
The diversity of fungi present in the tropical environment is very high and most of them are still unknown (Oliveira et al. 2022Oliveira J., Bonci M.M., Conceição A.B.S., Silva L.G., Barone F.A., Berto B.P. & Oliveira Á. 2022. Fungi isolated from wild birds and litter in the Itatiaia National Park in Southeastern Brazil. Biodiv. Bras. 12(4):1-10. <https://dx.doi.org/10.37002/biodiversidadebrasileira.v12i4.2261>
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). More studies about the frequency of environmental fungi become important since most of them have an opportunistic profile (Oliveira et al. 2022Oliveira J., Bonci M.M., Conceição A.B.S., Silva L.G., Barone F.A., Berto B.P. & Oliveira Á. 2022. Fungi isolated from wild birds and litter in the Itatiaia National Park in Southeastern Brazil. Biodiv. Bras. 12(4):1-10. <https://dx.doi.org/10.37002/biodiversidadebrasileira.v12i4.2261>
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). Therefore, it is of great importance to define the profile of the mycobiota residing in these places, as well as to establish the incidence of filamentous and/or opportunistic fungi.
When it comes to filamentous fungi, the most common descriptions are in broilers (Sugiharto 2019Sugiharto S. 2019. A review of filamentous fungi in broiler production. Ann. Agricult. Sci. 64(1):1-8. <https://dx.doi.org/10.1016/j.aoas.2019.05.005>
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, Hamza & Gunyar 2022Hamza A.A. & Gunyar O.A. 2022. Nutritional value of commercial broiler feed supplemented with olive mill waste fermented with probiotic Rhizopus oryzae strains. J. Appl. Microbiol. 133(3):1872-1881. <https://dx.doi.org/10.1111/jam.15694> <PMid:35771120>
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) in domestic birds, such as pigeons (Madsen et al. 2023Madsen A.M., Zhang F., Zeng Y. & Frederiksen M.W. 2023. Airborne methicillin-resistant Staphylococcus aureus, other bacteria, fungi, endotoxin, and dust in a pigeon exhibition. Environ. Res. 216(Pt 2):114642. <https://dx.doi.org/10.1016/j.envres.2022.114642> <PMid:36306875>
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), and captive birds (Talbot et al. 2018Talbot J.J., Thompson P., Vogelnest L. & Barrs V.R. 2018. Identification of pathogenic Aspergillus isolates from captive birds in Australia. Med. Mycol. 56(8):1038-1041. <https://dx.doi.org/10.1093/mmy/myx137> <PMid:29228225>
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). However, in free-living birds, this interaction remains poorly studied.
In this scenario, this study aimed to establish the incidence of filamentous fungi from feathers and feces of birds in localities of Marambaia Island, in the Southeast of Brazil, to understand the diversity and frequency of fungal species in this habitat.
Materials and Methods
Animal Ethics. Field-collecting permits were issued by the “Instituto Chico Mendes de Conservação da Biodiversidade” (Chico Mendes Institute for Biodiversity Conservation - ICMBio), through the “Sistema de Autorização e Informação em Biodiversidade” (Biodiversity Authorization and Information System - SISBIO) under license number 70132, and Animal Ethics Committee (CEUA) of the “Universidade do Grande Rio” (UNIGRANRIO) under protocol number 021/2019.
Study site and sample collection. This study was conducted on Marambaia Island, a protected area located in the State of Rio de Janeiro, in the Southeast of Brazil (22°26’17” S; 44°37’33” W). The expeditions were carried out in May, June, and July 2021. The captures took place three days per month and 10 mist nets were used, totaling 180 meters, and they remained open from 5 a.m. to 5 p.m., that is, 12 hours per day and 36 hours per month. A total of 45 birds of different species were captured (Table 1). The birds were kept in individual boxes and feces were collected immediately after defecation and packed in sterilized centrifuge tubes. The birds were identified according to Pacheco et al. (2021)Pacheco J.F., Silveira L.F., Aleixo A., Agne C.E., Bencke G.A., Bravo G.A., Brito G.R.R., Cohn-Haft M., Maurício G.N., Naka L.N., Olmos F., Posso S.R., Lees A.C., Figueiredo L.F., Carrano E., Guedes R.C., Cesari E., Franz I., Schunck F. & Piacentini V.Q. 2021. Annotated checklist of the birds of Brazil by the Brazilian Ornithological Records Committee - second edition. Ornithol. Res. 29:94-105. <https://dx.doi.org/10.1007/s43388-021-00058-x>
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. The feathers (plumage and tail) were removed with sterile tweezers and placed in previously sterilized white paper envelopes to eliminate moisture, thus preventing the growth of contaminating fungi and/or bacteria. After obtaining the samples, the birds were released into the same environment where they were captured. All samples were properly labeled, packed in thermal bags at room temperature, and transported to the Laboratory of Mycology and Mycotoxicology at the “Universidade Federal Rural do Rio de Janeiro” (UFRRJ).
Fungal isolation. Five to 10mg of feces were streaked on Sabouraud agar (Difco) plus chloramphenicol and each sample was incubated directly in a Petri dish (90 x 15cm) at 28°C for up to seven days (Simi et al. 2019Simi W.B., Leite Jr. D.P., Paula C.R., Hoffmann-Santos H.D., Takahara D.T. & Hahn R.C. 2019. Yeasts and filamentous fungi in psittacidae and birds of prey droppings in midwest region of Brazil: a potential hazard to human health. Braz. J. Biol. 79(3):414-422. <https://dx.doi.org/10.1590/1519-6984.181192> <PMid:30304251>
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). Whole and clipped feathers were streaked on Mycosel® Agar (Difco) and each sample was incubated in a Petri dish at 28°C for up to seven days (Nardoni & Mancianti 2021Nardoni S. & Mancianti F. 2021. Survey of keratinophilic fungi from feathers of birds in Tuscany. Biology 10(12):1317. <https://dx.doi.org/10.3390/biology10121317> <PMid:34943235>
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). For the identification of the fungi grown on the plates and manes, the following was observed: growth characteristics of the colonies, such as color and appearance (macromorphology), and characteristics of mycelium, presence, shape, size and septation of macroconidia; abundance and roughness of microconidia; presence or absence of chlamydoconium; presence or absence of forms of sexual reproduction; hyphal septation (Samson et al. 2000Samson R.A., Hoekstra E.S., Frisvad J.C. & Filtenborg O. 2000. Introduction to Food and Airborne Fungi. 6th ed. Centraalbureau Voor Schimmelcultures, Utrecht. 396p., Sidrim & Rocha 2004Sidrim J.J.C. & Rocha M.F.G. 2004. Micologia Médica à Luz de Autores Contemporâneos. Guanabara Koogan, Rio de Janeiro. 396p., De Hoog et al. 2020De Hoog G.S., Guarro J., Gené J., Ahmed S., AL-hatmi A.M.S., Figueiras M.J. & Vitale R.G. 2020. Atlas of Clinical Fungi. 4ª ed. Hilversum. 1595p.).
Molecular identification. DNA was extracted from a total of eight strains of different species, identified according to the morphological taxonomy, and the results of these identifications were compared. After isolating and obtaining pure cultures, total DNA extraction was performed using the commercial kit DNeasy Blood and Tissue Kit (Qiagen), following the manufacturer’s recommendations. Then, amplification was performed using the polymerase chain reaction (PCR) technique, in the region corresponding to the internal transcribed spacer (ITS) ITS1 - 5,8S - ITS2. The PCR reaction contained 12.5μl of GoTaq® G2 Hot Start Colorless Master Mix (Promega Labs, São Paulo, Brazil) (1×), 0.25μl of each primer (0.2μM), 9μl of nuclease-free water and 3μl of DNA (for the primary reaction) or 3μl primary PCR product (for the secondary reaction). This reagent mixture was subjected to amplification with a temperature profile that consisted of an initial denaturation step at 94°C for 5 minutes, followed by 35 cycles with denaturation at 94°C for 30 seconds, annealing at 60°C for 1 minute, and extension at 72°C for 2 minutes. At the end of the 35 cycles, a final extension was performed at 72°C for 10 minutes (Lima et al. 2017Lima A.K.S., Rodrigues J.R., Souza I.S., Rodrigues J.C., Souza T.C., Maia C.R. & Fernandes O.C.C. 2017. Fungos isolados da água de consumo de uma comunidade ribeirinha do médio Solimões, Amazonas - Brasil: potencial patogênico. Revta Amb. Água 12(6):1017-1024. <https://dx.doi.org/10.4136/ambi-agua.2018>
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). The primers used for amplification were ITS1 (5’ TCCGTAGGTGAACCTGCGG 3’) and ITS4 (5’ TCCTCCGCTTATTGATATGC 3’) (White et al. 1990White T.J., Bruns T., Lee S. & Taylor J. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics, p.315-322. In: Innis M.A., Gelfand D.H., Sninsky J.J. & White T.J. (Eds), PCR Protocols: a guide to methods and applications. Academic, San Diego.). The PCR amplicons were purified using the Qiagen MinElute PCR Purification (Qiagen, São Paulo, Brazil). All PCR amplicons were sequenced using the PCR forward and reverse primers by Ludwig Biotechnology, where an ABI-Prism 3500 Genetic Analyzer (Applied Biosystems, Foster City, California) was used for Sanger sequencing.
Results
A total of 90 samples from 45 wild birds captured were collected, which included feathers (n=45) and feces (n=45) (Table 1). From each sample, it was possible to isolate one or more filamentous colonies, while in others there was no growth and, therefore, the number of isolated fungi does not correspond to the total number of samples. Out of a total of 68 isolated fungi, 15 genera were identified, as shown in Table 2. The genera with a greater number of occurrences were Mucor and Fusarium, followed by Syncephalastrum, Penicillium, and Aspergillus.
The vast majority of fungal species isolated from the feathers and feces of birds in this study are considered to belong to the saprophytic fungi genera, occasionally being opportunistic pathogens. Based on the phenotypic characteristics and corresponding taxonomic keys, we can verify that, among the isolated samples, 15 genera were identified, namely Acremonium, Alternaria, Aspergillus, Cunninghamella, Curvularia, Eurotium, Fusarium, Geotrichum, Neosartorya, Pestalotia, Paecilomyces, Penicillium, Rhizopus, Mucor and Syncephalastrum (Table 2).
Discussion
It should be noted that studies involving the mycobiota present in wild birds, mainly Passeriformes, despite their great importance, are scarce, and, in Marambaia Island, no survey of the mycobiota present in the feathers or feces of these animals has been conducted so far. This seems to be the first study to report saprophytic fungi in wild birds on Marambaia Island.
The Tyrannidae family was the most prevalent in the capture (Fig.1). It is important to point out that tyrants are one of the most diverse and numerous groups of birds worldwide and, consequently, also in the neotropical region (Chaves et al. 2008Chaves A.V., Clozato C.L., Lacerda D.R., Sari E.H.R. & Santos F.R. 2008. Molecular taxonomy of Brazilian tyrant-flycatchers (Passeriformes: Tyrannidae). Mol. Ecol. Resour. 8(6):1169-1177. <https://dx.doi.org/10.1111/j.1755-0998.2008.02218.x> <PMid:21586004>
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). These birds have spread to every conceivable habitat (Ridgely & Tudor 1994Ridgely R.S. & Tudor G. 1994. The Birds of South America: the suboscine passerines. University of Texas Press, Texas. 940p.) and they adapt to a wide variety of ecological niches as they occupy all different vertical strata within tropical forests (Sick 1997Sick H. 1997. Ornitologia Brasileira. Editora Nova Fronteira, Rio de Janeiro. 1700p.). When separately analyzing fungal isolates from this family, we noticed that the most prevalent genus was Fusarium, found only from the feces of these animals and none from the feathers, which suggests the presence of these fungi in the diet and gastrointestinal tract of these birds. The vast majority of tyranids are insectivores and a few feed on fruits (Brum et al. 2012Brum F.T., Kindel A., Hartz S.M. & Duarte L.D.S. 2012. Spatial and phylogenetic structure drive frugivory in Tyrannidae birds across the range of Brazilian Araucaria forests. Oikos 121(6):899-906. <https://dx.doi.org/10.1111/j.1600-0706.2011.19978.x>
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). These results reinforce the need for further studies involving the presence of fungi and the correlation with the food consumed by these animals.
The genus Fusarium sp. is common in grains and commercial feed used for captive birds, as reported by Köptcke et al. (2021)Köptcke F.B.N., Pinto L.A., Moraes T.T., Farias V.M., Aronovich M. & Keller L.A.M. 2021. Determinação da micobiota e micotoxinas em rações comerciais destinadas para calopsitas (Nynphicus hollandicus) no Rio de Janeiro, Brasil. Braz. J. Anim. Environ Res. 4(3):4385-4394. <https://dx.doi.org/10.34188/bjaerv4n3-123>
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, who evaluated contamination by fungi and their mycotoxins in feed offered to birds of the species Nymphicus hollandicus, popularly known as cockatiels. Over six months, the feed intended for consumption by these birds was collected for a mycological analysis, resulting in a high fungal activity of the genus Fusarium.
Birds can carry pollen, seeds, small parasites, and even fungi on their feet, feathers and beak, thus acting as dispersers in an ecologically balanced environment (Hubalek 2004Hubalek Z. 2004. An annotated checklist of pathogenic microorganisms associated with migratory birds. J. Wild. Dis. 40(4):639-659. <https://dx.doi.org/10.7589/0090-3558-40.4.639> <PMid:15650082>
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). Therefore, it is possible to assume the importance of isolating fungi from the feces and feathers, as it was performed in the present study.
Among the 15 genera reported, the most frequent ones in this research were Mucor, Fusarium, and Syncephalastrum, followed by Penicillium, Aspergillus, and Rhizopus (Fig.2-7), and when analyzing the total number of fungi present in the substrates (feces and feathers), we observed a greater number of isolated genera in the feces than in the feathers (Table 1). Similar results were found by Oliveira et al. (2022)Oliveira J., Bonci M.M., Conceição A.B.S., Silva L.G., Barone F.A., Berto B.P. & Oliveira Á. 2022. Fungi isolated from wild birds and litter in the Itatiaia National Park in Southeastern Brazil. Biodiv. Bras. 12(4):1-10. <https://dx.doi.org/10.37002/biodiversidadebrasileira.v12i4.2261>
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who, when studying the fungal diversity present in the birds of the Itatiaia National Park in Brazil, reported the presence of Aspergillus spp., Mucor spp. Cladosporium spp., Fusarium spp., Penicillium spp. and Syncephalastrum spp. The same authors showed a higher prevalence of fungi in the feces than in the feathers of the captured birds.
Light microscopy of isolated fungi. (2) Mucor sp. with lactophenol cotton blue. (3) Fusarium sp. with lactophenol cotton blue. (4) Syncephalastrum sp. with lactophenol cotton blue. (5) Penicillium sp. with sodium hydroxide (20%). (6) Aspergillus sp. with lactophenol cotton blue. (7) Rhizopus sp. with lactophenol cotton blue. Isolate from feces.
Another genus largely found was Mucor, belonging to the order of Mucorales. These fungi have fast-growing and woolly colonies. Mucor is the main genus of the order, which has simple or branched sporangiophores, forms globular sporangia, and does not have rhizoids (De Hoog et al. 2020De Hoog G.S., Guarro J., Gené J., Ahmed S., AL-hatmi A.M.S., Figueiras M.J. & Vitale R.G. 2020. Atlas of Clinical Fungi. 4ª ed. Hilversum. 1595p., Freitas et al. 2021Freitas L.W.S., Lima C.L.F., Souza C.A.F., Cunha G.C.L., Leitão J.D.A., Silva S.B.G., Cruz M.O., Oliveira R.J.V. & Santiago A.L.C.M.A. 2021. A new occurrence of Mucor inaequisporus Dade (Mucorales, Mucoromycota) from soil of the Atlantic Forest in the Brazilian Northeast. Check List 17(3):753-758. <https://dx.doi.org/10.15560/17.3.753>
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). Further, when analyzing the presence of this fungus in the substrates, we noticed that it was reported in greater quantity in the feces than in the feathers, as also evidenced by Oliveira et al. (2022)Oliveira J., Bonci M.M., Conceição A.B.S., Silva L.G., Barone F.A., Berto B.P. & Oliveira Á. 2022. Fungi isolated from wild birds and litter in the Itatiaia National Park in Southeastern Brazil. Biodiv. Bras. 12(4):1-10. <https://dx.doi.org/10.37002/biodiversidadebrasileira.v12i4.2261>
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, reinforcing the need for further studies involving the feeding of these animals.
According to Oliveira et al. (2022)Oliveira J., Bonci M.M., Conceição A.B.S., Silva L.G., Barone F.A., Berto B.P. & Oliveira Á. 2022. Fungi isolated from wild birds and litter in the Itatiaia National Park in Southeastern Brazil. Biodiv. Bras. 12(4):1-10. <https://dx.doi.org/10.37002/biodiversidadebrasileira.v12i4.2261>
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, it is difficult to observe the dispersion of filamentous fungi through feces in the wild environment, since when the feces are dispersed, whether, in soil or litter, they generate cross-contamination with fungi that were present in these substrates, making it difficult to know its origin. Thus, the capture methodology of this study allows a more precise identification, since the feces are collected and kept in sterilized paper envelopes, therefore, avoiding cross-contamination. These results ensure that these fungi were present in the feces of the birds and that they are by them dispersed into the environment. Other studies have already reported this dispersion using different methodologies, such as Correia et al. (2019)Correia M., Heleno R., Silva L.P., Costa J.M. & Rodríguez-Echeverría S. 2019. First evidence for the joint dispersal of mycorrhizal fungi and plant diaspores by birds. New Phytol. 222(2):1054-1060. <https://dx.doi.org/10.1111/nph.15571> <PMid:30372538>
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. The authors analyzed the feces with intact seeds, which were placed in sterilized soil and kept for four months in a protected environment to avoid contamination. As a result, seven seedlings of Rubus ulmifolius obtained from four independent feces of Erithacus rubecula and Sylvia melanocephala, were colonized by arbuscular mycorrhizal fungi.
As for the genetic analysis, nucleotide sequences were obtained from the regions of interest (ITS) ITS1 - 5.8S - ITS2, and all these sequences were subjected to species-level identification through comparison with sequences deposited in the GenBank database, which made it possible to identify species such as Syncephalastrum racemosum, Pestalotiopsis microspora, Alternaria alternata, Penicillium herquei, Trichoderma asperellum and Fusarium sp. (Table 3). Despite the sequenced regions being widely used in several studies for the characterization of fungal species, for some isolates, these regions were not sensitive enough for amplification. Because it covers the diversity of the mycobiota of the Atlantic Forest, we may be dealing with new species that have not yet been described or a primer that does not have enough similarity for amplification.
The most modern techniques of molecular biology should complement (and not replace) the basic techniques of cultivation and identification to avoid identification errors, using morphological taxonomic keys and sequencing of nuclear genes, such as the ITS gene, which is the main gene used for molecular identification and phylogeny (Lima et al. 2017Lima A.K.S., Rodrigues J.R., Souza I.S., Rodrigues J.C., Souza T.C., Maia C.R. & Fernandes O.C.C. 2017. Fungos isolados da água de consumo de uma comunidade ribeirinha do médio Solimões, Amazonas - Brasil: potencial patogênico. Revta Amb. Água 12(6):1017-1024. <https://dx.doi.org/10.4136/ambi-agua.2018>
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). Studies conducted by Labrador et al. (2021)Labrador M.D.M., Doña J., Serrano D. & Jovani R. 2021. Quantitative interspecific approach to the stylosphere: Patterns of bacteria and fungi abundance on passerine bird feathers. Microb. Ecol. 81(4):1088-1097. <https://dx.doi.org/10.1007/s00248-020-01634-2> <PMid:33225409>
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verified the prevalence of Kingdom Fungi in relation to other microorganisms in the feathers of birds from southern Spain, showing fungi as the main microorganisms. However, the methodology used by the authors did not prioritize the description of morphospecies.
Conclusions
A diversity of filamentous fungi of various genera was isolated from the feathers and feces of birds. The most reported genera were Mucor, Fusarium, Syncephalastrum, Penicillium, Aspergillus, and Rhizopus.
According to the results found, it can be considered that the Atlantic Forest, even though it has suffered several impacts with the exponential growth and expansion of urban areas, is still a rich source of fungal species. The creation of new primers should be encouraged to shed light on a greater range of fungal species.
Moreover, as this region is still poorly investigated regarding the interaction of fungi with passerines, it is necessary that new mycological studies be conducted to survey the fungal species in the region, and molecular biology techniques be concomitantly applied (polyphasic taxonomy) to assist in the identification of these microorganisms.
Acknowledgments
We are thankful to the staff at the “Centro de Avaliação da Ilha da Marambaia” (CADIM) of the Brazilian Navy, and to the coordinator of the agreement between the “Universidade Federal Rural do Rio de Janeiro” (UFRRJ) and CADIM, Prof. Dr. Marcelo da Costa Souza (Departamento de Botânica - UFRRJ), that allowed us to access and use some facilities during the expeditions. This study was supported by “Conselho Nacional de Desenvolvimento Científico e Tecnológico” (CNPq), “Coordenação de Aperfeiçoamento de Pessoal de Nível Superior” (CAPES) and “Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro” (FAPERJ). JLGO has a scholarship from CAPES (Grant/Award Number: 001). MSO has a postdoctoral scholarship from FAPERJ (Grant/Award Number: E-26/204.228/2021). VML has a fellowship from FAPERJ (Grant/Award Number: E-27/211.566/2021). BPB has a fellowship from CNPq (Grant/Award Number: 302345/2022-1) and FAPERJ (Grant/Award Number: E-26/200.565/2023).
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Publication Dates
-
Publication in this collection
23 Feb 2024 -
Date of issue
2024
History
-
Received
11 Sept 2023 -
Accepted
14 Oct 2023