Abstract:
The functioning of diverse ecosystems relies on the dispersal processes facilitated by animals, known as zoochory. This ecological process is the only way in which some aquatic species can move between aquatic systems through the terrestrial matrix. Despite its paramount importance, the dispersal mechanisms involving certain vectors, such as mammals, have remained relatively poorly understood. Based on observation of capybaras Hydrochoerus hydrochaeris emerging from a wetland with various aquatic plant species attached to their fur, we hypothesized that these mammals play a crucial role in dispersing aquatic plants. We conducted a controlled experiment and confirmed that capybaras disperse two species of duckweed, Lemna valdiviana and Wolffia columbiana, through both endozoochory and epizoochory. The discovery of entire plant dispersal is noteworthy because it is not dependent on the season and does not rely on the production of specific reproductive diaspores. This study presents pioneering documentation of capybaras capacity to disperse entire plants through their gastrointestinal passage and offers further evidence of their role in epizoochory within neotropical wetlands.
Keywords:
endozoochory; epizoochory; aquatic macrophytes; plant dispersal; wetlands
Resumo:
O funcionamento de diversos ecossistemas depende de processos de dispersão facilitados pelos animais, conhecidos como zoocoria. Este processo ecológico é a única forma pela qual algumas espécies aquáticas podem se mover entre sistemas aquáticos, através da matriz terrestre. Apesar da sua importância, os mecanismos de dispersão envolvendo certos vetores, como os mamíferos, permanecem relativamente pouco compreendidos. Com base na observação de capivaras Hydrochoerus hydrochaeris emergindo de uma área úmida com diversas espécies de plantas aquáticas aderidas à sua pelagem, levantamos a hipótese de que esses mamíferos desempenham um papel crucial na dispersão de plantas aquáticas. Conduzimos um experimento controlado e confirmamos que capivaras dispersam duas espécies de lentilha-d’água Lemna valdiviana Fil. e Wolffia columbiana Karsten, ambas através de endozoocoria e epizoocoria. A descoberta da dispersão de plantas inteiras é notável porque não depende da estação do ano e da produção de diásporos reprodutivos específicos. Este estudo apresenta uma documentação pioneira da capacidade das capivaras de dispersar plantas inteiras através do seu trato gastrointestinal e oferece evidências adicionais de seu papel na epizoocoria em áreas úmidas Neotropicais.
Palavras-chave:
endozoocoria; epizoocoria; macrófitas aquáticas; dispersão de plantas; zonas úmidas
Introduction
The colonization of aquatic organisms in isolated wetlands has been debated since the time of the naturalists (Darwin 1859DARWIN, C. 1859. On the origin of species by means of natural selection. John Murray, London, UK., Brown and Lomolino 2006BROWN, J.H. & LOMOLINO, M.V. 2006. Biogeografia. Pages 261–293. Funpec, Ribeirão Preto, Brazil., Green et al. 2023GREEN, A.J., LOVAS-KISS, A., REYNOLDS, C., SEBASTIÁN-GONZÁLEZ, E., SILVA, G.G., VAN LEEUWEN, C.A.H. & WILKINSON, D.M. 2023. Dispersal of aquatic and terrestrial organisms by waterbirds: A review of current knowledge and future priorities. Freshwater Biology. 68:173–190.). Understanding the role of animals in the dispersal of aquatic organisms (zoochory) is crucial for comprehending the distribution of plant species across the landscape (Green et al. 2023GREEN, A.J., LOVAS-KISS, A., REYNOLDS, C., SEBASTIÁN-GONZÁLEZ, E., SILVA, G.G., VAN LEEUWEN, C.A.H. & WILKINSON, D.M. 2023. Dispersal of aquatic and terrestrial organisms by waterbirds: A review of current knowledge and future priorities. Freshwater Biology. 68:173–190.). In this sense zoochory has proven to be essential for the dispersal of seeds (Figuerola et al. 2003FIGUEROLA, J., GREEN, A.J. & SANTAMARÍA, L. 2003. Passive internal transport of aquatic organisms by waterfowl in Doñana, south-west Spain. Global Ecology and Biogeography. 12:427–436., Flaherty et al. 2018FLAHERTY, K.L., RENTCH, J.S. & ANDERSON, J.T. 2018. Wetland seed dispersal by white-tailed deer in a large freshwater wetland complex. AoB Plants. 10(1):plx074, Silva et al. 2020SILVA, G.G., GREEN, A.J., HOFFMAN, P., WEBER, V., STENERT, C., LOVAS-KISS, A. & MALTCHIK, L. 2020. Seed dispersal by neotropical waterfowl depends on bird species and seasonality. Freshwater Biology, 66(1):78–88., Lee et al. 2022LEE, S.K., RYU, Y. & LEE, E.J. 2022. Endozoochorous seed dispersal by Korean water deer (Hydropotes inermis argyropus) in Taehwa Research Forest, South Korea. Global Ecology and Conservation. 40:e02325.) and whole plants (Coughlan et al. 2017COUGHLAN, N.E., KELLY, T.C. & JANSEN, M.A.K. 2017. “Step by step”: high frequency short-distance epizoochorous dispersal of aquatic macrophytes. Biological Invasions. 19:625–634., Silva et al. 2018SILVA, G.G., GREEN, A.J., HOFFMAN, P., WEBER, V., STENERT, C., LOVAS-KISS, A. & MALTCHIK, L. (2018). Whole angiosperms Wolffia columbiana disperse by gut passage through wildfowl in South America. Biology Letters. 14:20180703., Paolacci et al. 2023PAOLACCI, S., JANSEN, M.A.K., STEJSKAL, V., KELLY, T.C. & COUGHLAN, N.E. 2023. Metabolically active angiosperms survive passage through the digestive tract of a large-bodied waterbird. Royal Society Open Science. 10(3):230090.).
During a field expedition at the Taim Ecological Station (ESEC Taim; 32°32’51.76” S, 52°32’37.66” W), a Ramsar site in southern Brazil (Figure 1a), we observed a group of free-ranging capybaras emerging from a wetland while carrying various species of aquatic plants attached in their furs. We hypothesized that this species participates in the dispersal of aquatic plants between wetlands, and therefore contributes to their patterns of geographic distribution. The capybara, Hydrochoerus hydrochaeris Linnaeus, is the world’s largest rodent (Mones and Ojasti 1986MONES, A. & OJASTI, J. 1986. Hydrochoerus hydrochaeris. Mammalian Species. 264:1–7.). Capybaras inhabit wetlands and are widely distributed in the South America, ranging from southern Panamá to Buenos Aires, in Argentina (Mones and Ojasti 1986MONES, A. & OJASTI, J. 1986. Hydrochoerus hydrochaeris. Mammalian Species. 264:1–7.). Categorized as semiaquatic mammals, they have webbed hind feet and are being commonly found in aquatic habitats (Mones and Ojasti 1986MONES, A. & OJASTI, J. 1986. Hydrochoerus hydrochaeris. Mammalian Species. 264:1–7., Silva 2014SILVA, F. 2014. Mamíferos Silvestres Rio Grande do Sul. Via Sapiens, Porto Alegre, Brazil.). These large herbivores live in groups and 80% of their food comprises aquatic plants (Borges and Colares 2007BORGES, L.V. & COLARES, I.G. 2007. Feeding habits of capybaras (Hydrochoerus hydrochaeris, Linnaeus 1766), in the Ecological Reserve of Taim (ESEC – Taim) – south of Brazil. Brazilian Archives of Biology and Technology. 50(3):409–416., Garcias and Bager 2009GARCIA, M.F. & BAGER, A. 2009. Estrutura populacional de capivaras na Estação Ecológica do Taim, Brasil, RS. Ciência Rural. 39(8):2441–2447.). The main goal of this study was to experimentally recognize the potential of capybaras to disperse aquatic plants in wetlands.
Capybaras in their natural habitat, the capybara of this study in its enclosure, and the aquatic plants that survived gut passage. (a) Epizoochorous evidence by indigenous capybaras at Estação Ecológica do Taim; (b) capybara in its enclosure, container with aquatic plants and the enclosure’s pool in the beginning of the experiment; (c) capybara interacting with the aquatic plants; (d) capybara with aquatic plants attached in its fur; (e) screening of feces sample, in the detail on the right, three L. valdiviana retained in the sieve; (f) L. valdiviana of A2 sample after the passage through the capybara gut; (g) L. valdiviana of A2 sample after 14 days of its passage through the capybara gut; (h) W. columbiana of A2 sample after its passage through the capybara gut; (i) W. columbiana of A2 sample 14 days after its passage through the capybara gut.
Materials and Methods
The dispersal of entire aquatic plants by capybaras was examined at a zoological park in southern Brazil (Parque Zoológico da Fundação Zoobotânica do Rio Grande do Sul – PZFZB, 29°47’47.99” S, 51°10’10.21” W). The model used was a male capybara of 35 kg and two years of age, born and raised in captivity. The capybara was housed in an enclosure that measured 18 m2. It had a floor made of concrete and sand and free access to a 3 m2 artificial pool (Figure 1b). The capybara diet at the park comprised fruits, vegetables, and sugarcane, and drinking water was always provided ad libitum during the experiment.
To conduct the experiment, we installed a 0.415 m × 0.315 m × 0.16 m container on the floor of the enclosure. Subsequently, we filled the container with clean water and included four species of floating aquatic plants (Azolla filiculoides Lam, Salvinia minima Bak, Lemna valdiviana Fil., and Wolffia columbiana Karsten) until they covered the water surface, totaling 0.13 m2 (see Figure 1b). The selected aquatic plants naturally occur in Zoo’s lakes and are widely distributed in southern Brazil (Rolon and Maltchik 2006ROLON, A.S. & MALTCHIK, L. 2006. Environmental factors as predictors of aquatic macrophyte richness and composition in wetlands of Southern Brazil. Hydrobiologia. 556(1):221–231.) and the world, except for S. minima an endemic plant to Brazil (Pena et al. 2020PENA, N.T.L., MIRANDA, C.V., SCHWARTSBURD, P.B., OLIVEIRA, A.G.S. & SMITH-BRAGA, N. 2020. Salviniaceae In Flora do Brasil. Jardim Botânico do Rio de Janeiro. http://floradobrasil 2020.jbrj.gov.br/reflora/floradobrasil/FB92034. Retrieved June 20, 2024.
http://floradobrasil 2020.jbrj.gov.br/re...
). The aquatic plants were made available to the capybara for 26 hours and 30 minutes, during which the capybara could interact ad libitum (Figure 1c-d).
The percentage of aquatic plants added to the container matched the natural proportion found in the zoo’s lake. The lake showed its entire surface covered by the plants, with W. columbiana and L. valdiviana being visually more abundant. The specific percentage of aquatic plants offered to the capybara is shown in the results section. The number of aquatic plants added to the container was estimated by counting all individuals in 12 random samples using an 8.55 cm2 sampler. Counts of individuals were performed using a Zeiss Stemi 2000-C stereomicroscope. The mean and standard error were calculated for each species of aquatic plant based on these 12 samples. The values were extrapolated to estimate the population in the container. Before the experiment, no aquatic plants were detected in the enclosure.
We analyzed the dispersal of intact aquatic plants by capybaras through the digestive tract (endozoochory) and via fur over short distances (epizoochory). For endozoochory, we collected all fecal samples produced during 48 hours after the provision of aquatic plants (Figure 1e). During this period, a total of eight fecal samples were collected, taken to the laboratory, and washed under running tap water using stacked sieves with mesh sizes of 2 mm, 1 mm, 500 µm, and 250 µm. The retained aquatic plants were examined under a Zeiss Stemi 2000-C stereomicroscope and incubated separately in Petri dishes with filtered water from Zoo lake. The aquatic plants were kept in a greenhouse to assess their viability for 21 days. Throughout this period, the temperature ranged from 13°C to 29°C. Mortality and emergence of new aquatic plants were recorded every seven days during the incubation period. Epizoochorous dispersal was verified by observing the presence of aquatic plants in the pool area of the enclosure after 24 hours of the experiment. The number of plants carried to the pool was estimated by counting all individuals in 12 random samples using a 79.75 cm2 sampler.
Results
A total of 97,611 ± 11,459 individuals of W. columbiana, 24,960 ± 2,008 of L. valdiviana, 497 ± 195 of S. minima, and 395 ± 64 of A. foliculoides were offered to the capybara, distributed in the following percentages: 79.1% W. columbiana, 20.2% L. valdiviana, 0.4% S. mínima, and 0.3% A. foliculoides. Out of the eight collected fecal samples, three contained apparently viable aquatic plants (Figure 1e, f & h). We identified these samples as A1, A2, and A3, respectively (Table 1). In sample A1, an individual of W. columbiana and one of L. valdiviana were recorded. In sample A2, 28 individuals of W. columbiana, 18 individuals of L. valdiviana, and three individuals of A. filiculoides were recorded. Sample A3 contained one individual of W. columbiana and three individuals of L. valdiviana. In total, we recorded 55 aquatic plants, comprising 30 individuals of W. columbiana, 22 of L. valdiviana, and 3 of A. filiculoides. No individuals of the species S. minima were observed in fecal samples.
Asexual reproduction of Wolffia columbiana, Lemna valdiviana, and Azolla filiculoides recovered from three capybara droppings, showing changes in the cumulative number of live and dead plants after 7, 14, and 21 days.
During the seventh day of incubation, there was no emergence of new aquatic plants. However, it was observed that 19 individuals of W. columbiana, seven of L. valdiviana, three of A. filiculoides in sample A2, and three individuals of L. valdiviana in sample A3, had died (see Table 1). On the 14th day of incubation, six new plant individuals were observed in the experiment: five individuals of L. valdiviana in sample A2 and one individual of W. columbiana in sample A3 (Table 1). On the 21st day of incubation, 24 new plant individuals were observed: one individual of W. columbiana in sample A1, 18 individuals of L. valdiviana and one of W. columbiana in sample A2, and four individuals of W. columbiana in sample A3 (Table 1). After 21 days of incubation, 53 aquatic plants remained alive (Table 1), confirming the dispersal of intact aquatic plants through the digestive tract of capybaras. Regarding epizoochorous dispersal, approximately 12,400 ± 3,365 W. columbiana and 5,017 ± 911 L. valdiviana plants were found in the enclosure’s pool 24 hours after the experiment began. All the aquatic plants present in the pool were viable, without tissue damage, and capable of continuing their development. Of the total plants available for ingestion by the capybara or attachment to its fur, 0.03% of W. columbiana, 0.09% of L. valdiviana, and 0.76% of A. filiculoides were recovered from the fecal samples (endozoochory). Additionally, 13% of W. columbiana and 20% of L. valdiviana were found in the pool after 24 hours (epizoochory).
Discussion
We demonstrate for the first time that capybaras can disperse intact aquatic plants through their digestive tract. The dispersal of whole aquatic plants through endozoochory has been previously documented to water birds (Silva et al., 2018SILVA, G.G., GREEN, A.J., HOFFMAN, P., WEBER, V., STENERT, C., LOVAS-KISS, A. & MALTCHIK, L. (2018). Whole angiosperms Wolffia columbiana disperse by gut passage through wildfowl in South America. Biology Letters. 14:20180703.; Paolacci et al., 2023PAOLACCI, S., JANSEN, M.A.K., STEJSKAL, V., KELLY, T.C. & COUGHLAN, N.E. 2023. Metabolically active angiosperms survive passage through the digestive tract of a large-bodied waterbird. Royal Society Open Science. 10(3):230090.) and recently to Myocastor coypus, another semiaquatic rodent (Hoffmann et al. 2024HOFFMANN, P.H.O., ADOLFO, A., GREEN, A.J., STENERT, C., SILVA, G.G., WEBER, V. & MALTCHIK, L. 2024. Big rodents disperse small seeds and spores in Neotropical wetlands. Journal of Ecology. 112(8): 1743–1757. https://doi.org/10.1111/1365-2745.14349.
https://doi.org/10.1111/1365-2745.14349...
). The understanding of how two small macrophyte species survive passage through the digestive tract of a large herbivore remains an open question for future research. The small size of these aquatic plants might have facilitated their passage through the gut. Smaller seeds are known to pass through the digestive tract of wild ducks more quickly and in greater numbers (Soons et al. 2008SOONS, M.B., VAN DER VLUGT, C., VAN LITH, B., HEIL, G.W., & KLAASSEN, M. 2008. Small seed size increases the potential for dispersal of wetland plants by ducks. Journal of Ecology. 96(4):619–627.). Additionally, the small size of the plants could enhance survival during mastication, and when ingested with parts of other plants, they might minimize the mechanical impact on the digestive tract. We also observed the potential dispersal of two aquatic macrophyte species, W. columbiana, and L. valdiviana, via capybara fur.
The opportunity presented by this study allowed us to quantify the dispersal of aquatic plants over short distances, similar to a study done with waterbirds (Coughlan et al. 2017COUGHLAN, N.E., KELLY, T.C. & JANSEN, M.A.K. 2017. “Step by step”: high frequency short-distance epizoochorous dispersal of aquatic macrophytes. Biological Invasions. 19:625–634.). Compared to endozoochory, epizoochory led to a higher percentage of plants being carried by the capybara. The efficiency of plant dispersal between wetlands may decrease as the distances increase, since capybaras tend to shake themselves after exiting the water. However, dispersal between distant wetlands is not ruled out, as step-by-step dispersal between nearby wetlands is likely (Coughlan et al. 2017COUGHLAN, N.E., KELLY, T.C. & JANSEN, M.A.K. 2017. “Step by step”: high frequency short-distance epizoochorous dispersal of aquatic macrophytes. Biological Invasions. 19:625–634.).
The dispersal of intact aquatic plants over long distances is rare due to desiccation and death of leaves (Landolt 1998LANDOLT, E. 1998. Lemnaceae. In K. KUBITZKI (Eds.), Flowering Plants Monocotyledons the Families and Genera of Vascular Plants. Springer Berlin, Heidelberg, Germany. pp 264–270., Coughlan et al. 2017COUGHLAN, N.E., KELLY, T.C. & JANSEN, M.A.K. 2017. “Step by step”: high frequency short-distance epizoochorous dispersal of aquatic macrophytes. Biological Invasions. 19:625–634.). Ridley (1930)RIDLEY, H.N. 1930. The dispersal of the plants throughout the world. L. Reeve and Company, Ashford, England., however, cultivated individuals of the aquatic macrophyte L. minor previously attached to bird feathers for 12 and 22 hours and demonstrated the ability of these aquatic plants to recover from the stress of being removed from the water. In a similar fashion, our findings suggest that, under specific conditions of humidity and protection against the wind, the capybara’s fur may provide adequate protection against desiccation, enabling aquatic plants to reach new habitats. In addition, species of Lemnaceae have a great capacity for vegetative propagation, and under ideal circumstances, the number of aquatic plants can increase twofold within a day, and a solitary plant can give rise to a community of more than a million individuals in only 30 days (Landolt 1998LANDOLT, E. 1998. Lemnaceae. In K. KUBITZKI (Eds.), Flowering Plants Monocotyledons the Families and Genera of Vascular Plants. Springer Berlin, Heidelberg, Germany. pp 264–270.). It has been found that, the dispersal of intact plants contributes to the increase in biomass and the establishment of new species in new habitats (van der Pijl 1982VAN DER PIJL, L. 1982. Principles of Dispersal in Higher Plants. Springer Berlin, Heidelberg, Germany.), and in addition to that the zoochory of asexual propagules facilitates the colonization of wetland areas, even outside the seed production period (Silva et al. 2018SILVA, G.G., GREEN, A.J., HOFFMAN, P., WEBER, V., STENERT, C., LOVAS-KISS, A. & MALTCHIK, L. (2018). Whole angiosperms Wolffia columbiana disperse by gut passage through wildfowl in South America. Biology Letters. 14:20180703.).
Capybara herds exhibit a home range of about 10 ha, with a daily average displacement of around 1 kilometer (Azcarate 1980AZCARATE, T. 1980. Sociobiologia y manejo del capibara (Hydrochoerus hydrochaeris). Dofiana Acta Vertebrata. 7:l–228.). Extensive home ranges can facilitate the dispersal of plants over long distances (Pellerin et al. 2016PELLERIN, M., PICARD, M., SAÏD, S., BAUBET, E. & BALTZINGER, C. 2016. Complementary endozoochorous long-distance seed dispersal by three native herbivorous ungulates in Europe. Basic and Applied Ecology. 17(2016):321–332.). Capybaras are social animals that live in family groups of 5–14 adult individuals (Herrera 2012bHERRERA, E.A. 2012b. Capybara social behavior and use of space: patterns and processes. In J.R. MOREIRA, K.M.P.M.B. FERRAZ, E.A. HERRERA, D.W. MACDONALD (Eds.), Capybara: biology, use and conservation of an exceptional neotropical species. Springer, New York, pp 185–207., Moreira et al. 2013MOREIRA, J.R., FERRAZ, K.M.P.M.B., HERRERA, E.A. & MACDONALD, D.W. 2013. Capybara: Biology, use and conservation of an exceptional neotropical species. Springer. 419 pp.), but they can also live in groups of up to 100 individuals (Garcia and Bager 2009GARCIA, M.F. & BAGER, A. 2009. Estrutura populacional de capivaras na Estação Ecológica do Taim, Brasil, RS. Ciência Rural. 39(8):2441–2447.). These groups typically consist of a dominant male, a few subordinate males, and several females (Moreira et al. 2013MOREIRA, J.R., FERRAZ, K.M.P.M.B., HERRERA, E.A. & MACDONALD, D.W. 2013. Capybara: Biology, use and conservation of an exceptional neotropical species. Springer. 419 pp.). Many males are found as peripheral elements to the group, and generally, young individuals disperse themselves (Moreira et al. 2013MOREIRA, J.R., FERRAZ, K.M.P.M.B., HERRERA, E.A. & MACDONALD, D.W. 2013. Capybara: Biology, use and conservation of an exceptional neotropical species. Springer. 419 pp.). Large herds of capybaras can transport a higher number of plants compared to solitary individuals, as the number of plants in their fur or guts is multiplied by the number of individuals in the group. This can lead to increased plant dispersal rates and potentially increase the local abundance of certain species. Despite this, family groups are more sedentary, while solitary individuals of both sexes have less restricted home ranges and can cover distances of up to 5 km (Herrera 1992bHERRERA, E.A. 1992b. Growth and dispersal of capybaras (Hydrochaeris* hydrochaeris) in the Llanos of Venezuela. Journal of Zoology. 228:307–316., Moreira et al. 2013MOREIRA, J.R., FERRAZ, K.M.P.M.B., HERRERA, E.A. & MACDONALD, D.W. 2013. Capybara: Biology, use and conservation of an exceptional neotropical species. Springer. 419 pp.). In this way solitary individuals are more likely to disperse to locations outside of the family groups territories enabling the dispersal of aquatic plants over long distances (Bartel and Orrock 2022BARTEL, S.L. & ORROCK, J.L. 2021. The important role of animal social status in vertebrate seed dispersal. Ecology Letters. 25:1094–1109. https://doi.org/10.1111/ele.13988.
https://doi.org/10.1111/ele.13988...
). Another factor that might enhance the chances of colonization by capybara-dispersed aquatic plants is their behavior of depositing feces directly into the water (Piccinini et al. 1971PICCININI, R.S., VALE, W.G. & GOMES, F.W.R. 1971. Criadouros artificiais de animais silvestres. Sudam, Belém, Brazil.), a favorable substrate for the plants to develop. This is an indication that capybaras could play a significant role in the dispersal of aquatic plants in southern Brazil, a region characterized by numerous small and isolated wetlands (Maltchik et al. 2003MALTCHIK, L., COSTA, E.S., BECKER, C.G. & OLIVEIRA, A.E. 2003. Inventory of wetlands of Rio Grande do Sul (Brazil). Pesquisas: Botânica, 53:89–100.).
We propose that the widespread distribution of the studied macrophyte species (Rolon and Maltchik 2006ROLON, A.S. & MALTCHIK, L. 2006. Environmental factors as predictors of aquatic macrophyte richness and composition in wetlands of Southern Brazil. Hydrobiologia. 556(1):221–231., Rolon et al. 2004ROLON, A.S., MALTCHIK, L. & IRGANG, B. 2004. Levantamento de macrófitas aquáticas em áreas úmidas do Rio Grande do Sul, Brasil. Acta Biologica Leopoldensia. 26(1):17–35.) might be a consequence of their substantial dispersal through capybaras (Hoffmann et al. 2024HOFFMANN, P.H.O., ADOLFO, A., GREEN, A.J., STENERT, C., SILVA, G.G., WEBER, V. & MALTCHIK, L. 2024. Big rodents disperse small seeds and spores in Neotropical wetlands. Journal of Ecology. 112(8): 1743–1757. https://doi.org/10.1111/1365-2745.14349.
https://doi.org/10.1111/1365-2745.14349...
) and aquatic birds (Silva et al. 2018SILVA, G.G., GREEN, A.J., HOFFMAN, P., WEBER, V., STENERT, C., LOVAS-KISS, A. & MALTCHIK, L. (2018). Whole angiosperms Wolffia columbiana disperse by gut passage through wildfowl in South America. Biology Letters. 14:20180703.). Compared with aquatic birds, capybaras possess a larger body area and thus will play a prominent role in the local dispersal of aquatic plants via epizoochory. Additionally, capybaras can spread aquatic plants to new habitats through gut passage. In this sense, capybaras play a crucial role in the dispersal processes across continental wetlands, significantly influencing the distribution of species in these environments.
Acknowledgments
PHOH is grateful to the Coordenação de Aperfeiçoamento de Pessoal de Ensino Superior (CAPES) for a master’s degree scholarship (proc. no. 88887.686236/2022-00). AA is grateful to CAPES for the doctoral scholarship (proc. no. 88887.841668/2023-00). LM holds a research productivity grant from the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (grant no. 307455/2021-1). We extend our sincere gratitude to the dedicated zookeepers Lisandro da Silva Siqueira, Maria Catarina Meireles Azevedo, João Felipe Bussolo da Silva and the veterinarian Maria do Carmo Both for their invaluable support throughout our work with the capybara. Furthermore, we would like to express our heartfelt appreciation to the veterinarian Raquel Von Hohendorff for her unwavering support in making our research at the park possible and for facilitating its execution.
Data Availability
The data collected and generated during this study are available on SciELO Data at https://doi.org/10.48331/scielodata.UAK9VD. This dataset includes the count data used in the analyses. The authors confirm that all data necessary for reproducing the study findings are available in the designated dataset.
References
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- BARTEL, S.L. & ORROCK, J.L. 2021. The important role of animal social status in vertebrate seed dispersal. Ecology Letters. 25:1094–1109. https://doi.org/10.1111/ele.13988.
» https://doi.org/10.1111/ele.13988 - BORGES, L.V. & COLARES, I.G. 2007. Feeding habits of capybaras (Hydrochoerus hydrochaeris, Linnaeus 1766), in the Ecological Reserve of Taim (ESEC – Taim) – south of Brazil. Brazilian Archives of Biology and Technology. 50(3):409–416.
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Publication Dates
-
Publication in this collection
16 Sept 2024 -
Date of issue
2024
History
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Received
22 Mar 2024 -
Accepted
06 Aug 2024