Daily and seasonal activity patterns of a felid assemblage in a forest-grassland mosaic in southern Brazil

Alberti, Maria Eduarda S.; Tirelli, Flávia P.; Prestes, Nêmora P.; Martinez, Jaime

doi:10.1590/1678-4766e2023006

ABSTRACT

The mechanisms of ecological segregation involved in the coexistence between Neotropical felids are the key to support strategies for conservation. Due to their inconspicuous and elusive behavior, camera trapping constitute a strategic, non-invasive method to study these species. The present work aimed to evaluate the daily and seasonal activity patterns of four felid species: Leopardus guttulus (Hensel, 1872), L. pardalis (Linnaeus, 1758), L. wiedii (Schinz, 1821) and Puma concolor (Linnaeus, 1771), in the Papagaios-de-Altitude Private Protected Area, state of Santa Catarina, southern Brazil. Data were collected from January 2018 to December 2019, using 25 sites of camera traps among the study area. We collected 624 independent records from L. guttulus (108), L. pardalis (55), L. wiedii (77) and P. concolor (384) in a sampling effort of 12,266 camera-traps/day. All species analysed showed a non-uniform distribution of daily activity, when considering the two years. We report the peak of seasonal activity for all species between the months of June and September, coinciding with the Araucaria nut harvest in the study area, and with the increase in populations of small rodents. We also report a high overlap between the activity patterns of the four species. The daily and seasonal activity patterns of the species in this study seem to reflect the intrinsic dynamics of the Araucaria Forest, as well as possible adaptations to prey availability.

KEYWORDS.
Camera traps; Felidae; Atlantic Forest; circadian rhythm; Private Protected Area

RESUMO

Os mecanismos de segregação ecológica envolvidos na coexistência entre felídeos neotropicais são a chave para subsidiar estratégias para sua conservação. Por apresentarem comportamento inconspícuo e esquivo, as armadilhas fotográficas constituem um método não invasivo estratégico para estudá-los. O presente trabalho buscou avaliar o padrão de atividade diário e sazonal de quatro espécies de felídeos: Leopardus guttulus (Hensel, 1872), L. pardalis (Linnaeus, 1758), L. wiedii (Schinz, 1821) e Puma concolor (Linnaeus, 1771), na RPPN Papagaios-de-Altitude, no estado de Santa Catarina, sul do Brasil. Coletamos os dados através de 25 sítios de armadilhas fotográficas na área de estudo. Obtivemos 624 registros independentes de L. guttulus (108), L. pardalis (55), L. wiedii (77) e P. concolor (384) em um esforço amostral de 12.266 armadilhas/dia. Todas as espécies analisadas apresentaram distribuição de atividade diária não uniforme, quando considerados os dois anos. Relatamos o pico de atividade sazonal de todas as espécies entre os meses de junho a setembro, coincidindo com a safra de pinhão na região, e com o aumento nas populações de pequenos roedores. Também relatamos uma alta sobreposição entre os padrões de atividade das quatro espécies. A atividade diária e sazonal das espécies neste estudo parece refletir as dinâmicas intrínsecas da Floresta Ombrófila Mista, além de possíveis adaptações à disponibilidade de presas.

PALAVRAS-CHAVE.
Armadilhas fotográficas; Felidae; Mata Atlântica; ritmo circadiano; RPPN

Wild felids are indispensable in regulating and maintaining the ecological structure of neotropical forests, acting as top predators or mesopredators (Roemer et al., 2009Roemer, G. W.; Gompper, M. E. & Valkenburgh, B. V. 2009. The ecological role of the mammalian mesocarnivore. BioScience 59(2):165-173.; Estes et al., 2011Estes, J. A.; Terborgh, J.; Brashares, J. S.; Power, M. E.; Berger, J.; Bond, W. J.; Carpenter, S. R.; Essington, T. E.; Holt, R. D.; Jackson, J. B. C.; Marquis, R. J.; Oksanen, T.; Paine, R. T.; Pikitch, E. K.; Ripple, W. J.; Sandin, S. A.; Scheffer, M.; Schoener, T. W.; Shurin, J. B.; Sinclair, A. R.; Soulé, M. E.; Virtanen, R. & Wardle, D. A. 2011. Trophic downgrading of planet Earth. Science 333.6040:301-306.). Felids show high morphological and functional similarity, given the relatively recent divergence of the clade, dating from the late Miocene (Morales & Giannini, 2010Morales, M. M. & Giannini, N. P. 2010. Morphofunctional patterns in Neotropical felids: species co-existence and historical assembly. Biological Journal of the Linnean Society 100(3):711-724.). The high similarity among these predators is a factor that could increase agonistic interactions (Pianka, 1974Pianka, E. R. 1974. Evolutionary Ecology. New York, Harper & Row. 356p.), which include indirect competition for food resources and home range, and in more extreme cases, interspecific predation (Di Bitetti et al., 2010Di Bitetti, M. S.; De Angelo, C. D.; Di Blanco, Y. E. & Paviolo, A. 2010. Niche partitioning and species coexistence in a Neotropical felid assemblage. Acta Oecologica 36:403-412.; Oliveira & Pereira, 2014Oliveira, T. G. & Pereira, J. A. 2014. Intraguild predation and interspecific killing as structuring forces of carnivoran communities in South America. Journal of Mammalian Evolution 21(4):427-436.; Santos et al., 2019Santos, F.; Carbone, C.; Wearn, O. R.; Rowcliffe, J. M.; Espinosa, S.; Lima, M. G. M.; Ahumada, J. A.; Gonçalves, A. L. S.; Trevelin, L. C.; Alvarez-Loayza, P.; Spironello, W. R.; Jansen, P. A.; Juen, L. & Peres, C. A. 2019. Prey availability and temporal partitioning modulate felid coexistence in Neotropical forests. PLoS One 14(3):e0213671.). The niche complementarity hypothesis (Schoener, 1974Schoener, T. W. 1974. Resource partitioning in ecological communities. Science 185:27-39.) states that there must be differences in the use of at least one resource dimension (spatial, temporal or trophic) by competitor species, in order to reduce agonistic events. One of the most used forms of ecological partition between carnivores is temporal segregation (Schoener, 1974), which aims to reduce intraguild competition, especially between animals of similar body size or diet (Di Bitetti et al., 2010Di Bitetti, M. S.; De Angelo, C. D.; Di Blanco, Y. E. & Paviolo, A. 2010. Niche partitioning and species coexistence in a Neotropical felid assemblage. Acta Oecologica 36:403-412.).

Analyzing the activity patterns of sympatric species is the first step to evaluate possible differences in their temporal niche. The daily and seasonal activity patterns of mammals are shaped by a range of factors including environmental conditions, prey availability, social interactions or between competitors (Zielinski, 1986Zielinski, W. J. 1986. Circadian rhythms of small carnivores and the effect of restricted feeding on daily activity. Physiology & Behavior 38(5):613-620.; Beltrán & Delibes, 1994Beltrán, J. F. & Delibes, M. 1994. Environmental determinants of circadian activity of free-ranging Iberian lynxes. Journal of Mammalogy 75(2):382-393.; Foster et al., 2013Foster, V. C.; Sarmento, P.; Sollmann, R.; Tôrres, N.; Jácomo, A. T.; Negrões, N.; Fonseca, C. & Silveira, L. 2013. Jaguar and puma activity patterns and predator-prey interactions in four Brazilian Biomes. Biotropica 45:373-379.; Botts et al., 2020Botts, R. T.; Eppert, A. A.; Wiegman, T. J.; Rodriguez, A.; Blankenship, S. R.; Asselin, E. M.; Garley, W. M.; Wagner, A. P.; Ullrich, S. E.; Allen, G. R. & Mooring, M. S. 2020. Circadian activity patterns of mammalian predators and prey in Costa Rica. Journal of Mammalogy 101(5):1313-1331.). The temporal segregation strategy as a mean of coexistence is a recurring theme in the study of Neotropical felids (Oliveira-Santos et al., 2012Oliveira-Santos, L. G. R.; Graipel, M. E.; Tortato, M. A. & Zucco, C. A. 2012. Abundance changes and activity flexibility of the oncilla, Leopardus tigrinus (Carnivora: Felidae), appear to reflect avoidance of conflict. Zoologia 29(2):115-120.; Graipel et al., 2014Graipel, M. E.; Oliveira-Santos, L. G. R.; Goulart, F. V. B.; Tortato, M. A.; Miller, P. R. M. & Cáceres, N. C. 2014. The role of melanism in oncillas on the temporal segregation of nocturnal activity. Brazilian Journal of Biology 74(3):142-145.; Massara et al., 2018Massara, R. L.; Barreto, M. & Chiarello, A. G. 2018. Effect of humans and pumas on the temporal activity of ocelots in protected areas of Atlantic Forest. Mammalian Biology 92:86-93.; Santos, 2019Santos, F.; Carbone, C.; Wearn, O. R.; Rowcliffe, J. M.; Espinosa, S.; Lima, M. G. M.; Ahumada, J. A.; Gonçalves, A. L. S.; Trevelin, L. C.; Alvarez-Loayza, P.; Spironello, W. R.; Jansen, P. A.; Juen, L. & Peres, C. A. 2019. Prey availability and temporal partitioning modulate felid coexistence in Neotropical forests. PLoS One 14(3):e0213671.; Nagy-Reis et al., 2019Nagy-Reis, M. B.; Iwakami, V. H. S.; Estevo, C. A. & Setz, E. Z. F. 2019. Temporal and dietary segregation in a neotropical small-felid assemblage and its relation to prey activity. Mammalian Biology 95:1-8.). However, it is still incipient for the state of Santa Catarina, Brazil, which is entirely distributed in the threatened Atlantic Forest biome.

Given the high degree of fragmentation of the Araucaria Forest and natural grasslands on the Santa Catarina plateau, human influence represents a serious threat to wild felids. Understanding the activity patterns of these species is essential to elucidate their responses to environmental conditions and exogenous disturbances, and its implications for conservation. In the Papagaios-de-Altitude Private Protected Area, five species of felids are found: Herpailurus yagouaroundi (É. Geoffroy Saint-Hilaire, 1803), Leopardus guttulus (Hensel, 1872), L. pardalis (Linnaeus, 1758), L. wiedii (Schinz, 1821) and Puma concolor (Linnaeus, 1771), the majority is considered threatened species by the Brazilian National Red List (Ministério do Meio Ambiente, 2022Ministério do Meio Ambiente. 2022. Lista Oficial de Espécies da Fauna Brasileira Ameaçadas de Extinção. Brasília, ICMBio/MMA.). The threatened species are H. yagouaroundi, L. guttulus and L. wiedii, while P. concolor and L. pardalis are not considered threatened.

The objective of this study is to characterize aspects of the ecology of felids in the Papagaios-de-Altitude Private Protected Area, with emphasis on their patterns of daily and seasonal activity, over a period of two years. We hypothesized that this felid assemblage would present temporal segregation, with low activity overlap between the four species.

MATERIAL AND METHODS

Study area. The Papagaios-de-Altitude Private Protected Area is located in the state of Santa Catarina (SC), southern Brazil. It is inserted within the rural matrix of the municipality of Urupema (27°56’42.87”S, 49°54’55.33”W), a plateau region in which accour the largest remnants of the Araucaria Forest in the state, one of the most threatened phytophysiognomies of Brazilian Atlantic Forest (Martinez et al., 2021Martinez, J; Gaboardi, V. T. R.; Prestes, N. P.; Bortoncello, V. L.; Dos Santos, L. E. S.; Tomasi , R.Jr & Perez, A.V. R. 2021. RPPN Papagaios-de-Altitude: reserva estratégica de pinhões para a fauna silvestre. In: Martinez, J. & Prestes, N. P. org. Biologia da Conservação: Programa Nacional para a Conservação do Papagaio-de-peito-roxo e Outras Iniciativas. Tapera, Ed. Lew, p. 317-343.) (Fig. 1). It comprises an area of 36.07 hectares, the largest portion of which is covered by Upper Montane Araucaria Forest. There are also areas with a predominance of tree fern (Dicksonia sellowiana (Presl.) Hook.) and natural grasslands, with peat bogs and herbaceous vegetation associated with rocky outcrops.

Fig. 1.
Study area: Papagaios-de-Altitude Private Protected Area in Urupema, Santa Catarina, Brazil. On the top-right panel, colors indicate the type of soil-use in the area and its limits. The black dots in the map indicate the location of the camera traps.

The area is located at an average altitude of 1,418 meters above sea level, belonging to the Cfb climate (marine temperate) according to the Köppen-Geiger classification. The average annual temperature is 13.5 °C. Temperatures below 5 °C are common throughout all months of the year, with a strong presence of frost mainly between April and November. The average annual rainfall is 1,656 mm (EPAGRI/CIRAM, 2022EPAGRI/CIRAM. Caracterização biofísica do estado de Santa Catarina. 2022. Available at https://ciram.epagri.sc.gov.br/index.php/2022/03/11/caracterizacao-biofisica-do-estado-de-santa-catarina/ >. Accessed on 10 March 2022.
https://ciram.epagri.sc.gov.br/index.php... ).

Camera trapping. Data were collected from records of 25 camera traps, which are in the image database of Papagaios-de-Altitude Private Protected Area maintained by Projeto Charão (AMA/ICB-UPF), during the period from January 2018 to December 2019. The number of camera traps used in monitoring progressively increased in this period, from 10 to 25 in total. The additional cameras were installed during the first semester of 2019. All camera traps installed remained active simultaneously for 24 hours in all months sampled, and there was no pause or interval in monitoring. We performed a review of traps and exchange of memory cards at an average interval of 30 days. No baits were used.

We programmed the 25 camera traps (Bushnell Trophy Cam) for hybrid function (photo and video). Triggering speed was set to 0.5 seconds, the duration of each video was set to 10 seconds, and the interval time between each capture was 5 seconds. The camera traps were installed between 30 and 50 centimeters from the ground, respecting an interval of 100 to 400 meters between each installation site (Fig. 1). The sites were selected by previous found of wild mammals evidences (feces, marks on trunks or footprints), seeking to contemplate the greatest diversity of environments within the Papagaios-de-Altitude Private Protected Area.

The set of images containing felid records were separeted and identified. We selected those referring to the species: Herpailurus yagouaroundi, Leopardus guttulus, L. pardalis, L. wiedii and Puma concolor. For each record, we evaluated the following aspects: camera positioning location (georeferenced); date; time; image quality and format (photo/video) and species identification. We did not differentiate individuals.

Data analysis. To investigate the activity patterns of the felids at the Papagaios-de-Altitude Private Protected Area, we applied a pre-selection of one-hour independence between the records, considering the proximity of the camera traps. Records of the same species at immediately adjacent points (distance of 250 meters or lower), within the same one-hour interval, were accounted as a single record. We calculated the capture success through the ratio between the number of independent records of each species and the sampling effort, multiplied by 100, according to Srbek-Araujo & Chiarello (2007Srbek-Araujo, A. C. & Chiarello, A. G. 2007. Armadilhas fotográficas na amostragem de mamíferos: considerações metodológicas e comparação de equipamentos. Revista Brasileira de Zoologia 24(3):647-656.). Subsequently, we performed circular analyses, with the Rayleigh Test of Uniformity in the “circular” package version 0.4-93 (Agostinelli & Lund, 2017Agostinelli, C. & Lund, U. 2017. R package ʽcircularʼ: Circular Statistics (version 0.4-93). Available at https://r-forge.r-project.org/projects/circular/ >. Accessed on 10 December 2021.
https://r-forge.r-project.org/projects/c... ) in the R software (R Core Team, 2020R Core Team. 2020. R: A language and environment for statistical computing. R Foundation for Statistical Computing. Available at https://www.R-project.org/ >. Access on 5 June 2021.
https://www.R-project.org/... ). Circular analysis was performed both for the distribution of activity over 24 hours of the day, as well as over 12 months of the year, in which the information of hours and months were converted to radians (ranging from 0 to 2 π). In this analysis, by means of the indicative arrow in the circular histograms, we observe the angular mean (µ) and mean vector length (r), where values closer to 1 indicate a high concentration of data close to the mean, while values closer to zero indicate a low concentration. A significant value for the Rayleigh’s Test of Uniformity (p < 0.05) indicates non-uniform distribution, where records are concentrated in a certain time interval. A non-significant value (p ≥ 0.05) does not refute the null hypothesis of uniformity, with no activity peak concentrated at any time interval. Circular analysis performed with the number of records obtained throughout the year was used to assess the existence of differential patterns among months, relating them to the seasons of the year. We compared the results using Watson’s Two-sample Test of Homogeneity (U²), also included in the “circular” package. This test was performed comparing the activity patterns of different species in the same year, and between the same species in different years.

To analyze the daily activity of the species, we used all the records selected for the years 2018 and 2019. For the seasonal activity, we standardized the sampling effort within the same analyzed year, so that all months of the same year had the same number of active camera traps. For the year 2018, we selected 10 camera traps, and for 2019, we selected 16.

Species were classified as diurnal (<15% of records at night), nocturnal (>85% of records at night), mostly diurnal (15-35% of records at night), mostly nocturnal (65-85% of records at night), or cathemerals (the ones that do not fit the limits considered for the previous categories), according to Romero-Muñoz et al. (2010Romero-Muñoz, A.; Maffei, L.; Cuéllar, E.; Noss, A. J. 2010. Temporal separation between jaguar and puma in the dry forests of southern Bolivia. Journal of Tropical Ecology 26:303-311.). We considered as night the entire period from the mean time of sunset in the study region (18:40h) until sunrise (06:36h), and day as the period after sunrise (06:37h) until sunset (18:39h). Data was obtained through the Sunrise and Sunset platform (https://sunrise-sunset.org/), which shows the exact time of sunrise and sunset in the study area.

Additionally, we estimated the similarity of the daily activity between the species, using the “overlap” package version 0.3.4 (Ridout & Linkie, 2009Ridout, M. & Linkie, M. 2009. “Estimating overlap of daily activity patterns from camera trap data.” Journal of Agricultural, Biological, and Environmental Statistics 14:322-337.). We considered the overlap coefficients (Dhat1 for sample sets < 70; Dhat4 for sample sets ≥ 70). Dhat1 and Dhat4 values closer to 1 indicate high activity overlap, while values close to zero indicate low overlap. We calculated confidence intervals through 1,000 bootstrap resamplings. These results were correlated with the daily luminosity periods recorded for the study area. We added the mean of sunrise and sunset times in the area to the daily activity histograms for each species, thus illustrating the relationship between the luminosity periods in the area and the activity of the felids.

RESULTS

We obtained a total of 624 independent records (n₂₀₁₈= 315, n₂₀₁₉ = 309) including 108 records of the species Leopardus guttulus (n₂₀₁₈= 57, n₂₀₁₉= 51), 55 records of L. pardalis (n₂₀₁₈= 25, n₂₀₁₉= 30), 77 records of L. wiedii (n₂₀₁₈= 30, n₂₀₁₉= 47) and 384 records of Puma concolor (n₂₀₁₈= 202, n₂₀₁₉=182). The number of records for Herpailurus yagouaroundi was much lower than the others (n_total= 8) , and we chose not to include it in the analysis. The total sampling effort was 12,266 cameras/day (2018= 5,424 cameras/day, 2019= 6,842 cameras/day). Regarding capture success, for the two years together, we obtained values of 0.88% for L. guttulus (2018= 1.05%, 2019= 0.74%), 0.45% for L. pardalis (2018= 0.46%, 2019= 0.44%), 0.63% for L. wiedii (2018= 0.55%, 2019= 0.69%) and 3.13% for P. concolor (2018= 3.72%, 2019= 2.66%). All species analyzed showed non-uniform distribution of daily activity, when considering both years (Fig. 2). However, this was not the pattern found for L. guttulus and L. wiedii in 2018 and for L. pardalis in 2019 (see below more details in species items).

Fig. 2.
Circular histograms with distribution and frequency of daily activity of Leopardus guttulus, L. pardalis, L. wiedii and Puma concolor in Papagaios-de-Altitude Private Protected Area, Santa Catarina, Brazil. The black arrows on each graph indicate the direction of the mean angle (µ). Each graph also exhibits the values of P and mean vector length (r).

Regarding seasonal activity patterns, we analyzed 543 independent records (n₂₀₁₈= 246, n₂₀₁₉= 297) . Of these, 72 refer to L. guttulus (n₂₀₁₈= 23, n₂₀₁₉= 49), 47 to L. pardalis (n₂₀₁₈= 18, n₂₀₁₉= 29), 64 to L. wiedii (n₂₀₁₈= 21, n₂₀₁₉= 43) and 360 to P. concolor (n₂₀₁₈= 184, n₂₀₁₉= 176). The highest frequency of records occurred in winter, between June and September (Fig. 3).

Fig. 3.
Circular histograms with distribution and frequency of the seasonal activity of Leopardus guttulus, L. pardalis, L. wiedii and Puma concolor in Papagaios-de-Altitude Private Protected Area, Santa Catarina, Brazil. The arrows on each graph indicate the direction of the mean angle (µ). Each graph also exhibits the values of P and mean vector length (r).

Leopardus guttulus. We classified the habit of L. guttulus as cathemeral (Tab. I), with non-uniform activity (Rayleigh’s Test= 0.278, p < 0.001) and high dispersion of the records over 24 hours of the day in relation to the mean vector, indicated between 02:00h and 03:00h (Fig. 2). The species presented a large peak of activity in the interval between 00:00h and 08:00h, and a smaller one between 18:00h and 19:00h. We found no significant difference in the daily activity patterns of this species between the two sampled years (U²= 0.0569, p> 0.10). We observed that L. guttulus was more active between June and July, showing a non-uniform distribution throughout the year (Rayleigh Test= 0.335, p < 0.001) and high dispersion of records. When analyzing the 2018 and 2019 data separately, we observed that this pattern was maintained, and that the species showed a non-uniform distribution in the two years (Fig. 3) and there was no significant difference between the years (U²= 0.1011, p > 0.10).

Leopardus pardalis. We classified the habit of L. pardalis as mostly nocturnal (Tab. I), with non-uniform activity (Rayleigh Test= 0.429, p < 0.001), and peak of activity concentrated between 00:00h and 03:00h, with high dispersion of records in relation to the mean vector, indicated between 00:00h and 01:00h (Fig. 2). We found a significant difference in the daily activity patterns of this species between the two sampled years (U²= 0.2502, p< 0.05). Concerning the seasonal distribution of activity, throughout the entire sampled period, we observed that L. pardalis had the highest activity between July and August (Rayleigh Test= 0.611, p < 0.001) and an intermediate dispersion of records throughout the year, in relation to the mean. Analyzing 2018 independently, we found that there was a peak of activity of the species during the month of September, and that there was a high concentration of records in relation to the mean vector. In 2019, we observed a pattern similar to the result obtained for the total period (Fig. 3). Species patterns in 2018 and 2019 differed significantly (U²= 0.2963, p < 0.01).

Leopardus wiedii. This species had mostly nocturnal habits (Tab. I), with non-uniform activity (Rayleigh Test= 0.319, p < 0.001), and a peak of activity concentrated between 21:00h and 06:00h, with high dispersion of records in relation to the mean, indicated between 00:00h and 02:00h (Fig. 2). We found no significant difference in the daily activity patterns of this species between the two sampled years (U²= 0.1612, p> 0.05). As for the seasonal distribution of activity, throughout the entire sampled period, we observed that L. wiedii was more active between the months of July and August, with a non-uniform distribution throughout the year (Rayleigh Test= 0.492, p < 0.001) and high dispersion of records. By independently analyzing the records for 2018, we found that the pattern was similar to that found for the total period (Fig. 3). However, in 2019 we recorded a peak of activity for the species between the months of June and July, with an intermediate dispersion of records throughout the year. It was not sufficient to differentiate the patterns between the two years (U²= 0.0508, p > 0.10).

Puma concolor. The habit of P. concolor was cathemeral (Tab. I), with a non-uniform activity (Rayleigh Test= 0.227, p < 0.001). This species showed several peaks of activity, with high dispersion of records over 24 hours, in relation to the mean (Fig. 2). We found no significant difference in the daily activity patterns of this species between the two sampled years (U²= 0.0678, p> 0.10). Regarding the seasonal distribution of activity, throughout the entire sampled period, we observed that P. concolor was more active during the months of July and August, showing a non-uniform distribution throughout the year (Rayleigh Test= 0.250, p < 0.001) and a high dispersion of records. Independent analysis of the 2018 records revealed a different pattern, showing a peak between August and September. In 2019, the peak of activity occurred between the months of May and June (Fig. 3). The difference between the two years was significant (U²= 1.3815, p < 0.001).

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Tab. I.
Distribution of records of each species, in percentage, for each period (day and night) at Papagaios-de-Altitude Private Protected Area in Urupema, Santa Catarina, Southern Brazil.

Pairwise comparisons. We performed the Watson’s Two Sample Test of Homogeneity to assess differences in daily activity patterns between pairs of species. Regarding the whole period, only L. pardalis and P. concolor showed a significant difference (U²= 0.27, p< 0.01). The other pairs presented only slight and non-significant differences: L. guttulus and L. pardalis (U²= 0.1195, p> 0.10); L. guttulus and L. wiedii (U²= 0.0664, p> 0.10); L. guttulus and P. concolor (U²= 0.163, p> 0.05); L. wiedii and L. pardalis (U²=0.1328, p> 0.10); L. wiedii and P. concolor (U²= 0.1194, p> 0.10). Results for each year separately can be accessed in ^{Supplementary Material 1} Supplementary Material 1. Results from the Watson’s Two Test of Homogeneity (U²) to assess differences in the daily activity patterns between pairs of species in the Papagaios-de-Altitude Private Protected between pairs of species in the Papagaios-de-Altitude Private Protected Area. (S1).

Watson’s Test was also performed to pairwise comparisons in the seasonal activity patterns between species. Regarding the whole period, significant differences were found for the pairs of species: L. guttulus and L. pardalis (U²= 0.5087, p< 0.001); L. guttulus and L. wiedii (U²= 0.2044, p< 0.05); L. pardalis and L. wiedii (U²= 0.3326, p< 0.01); L. pardalis and P. concolor (U²= 0.8746, p< 0.001); L. wiedii and P. concolor (U²= 0.4792, p< 0.001). Only L. guttulus and P. concolor showed a non-significant difference (U²= 0.1778, p> 0.05). Results for each year separately can be accessed in ^{Supplementary Material 2} Supplementary Material 2. Results from the Watson’s Two Test of Homogeneity (U²) to assess differences in the seasonal activity patterns of Homogeneity (U²) to assess differences in the seasonal activity patterns between pairs of species in the Papagaios-de-Altitude Private Protected Area (S2).

Daily activity overlap. We observed that the four species showed high overlap of daily activity (Fig. 4), but with distinct peaks of activity. The largest activity overlaps between species were Leopardus guttulus and L. wiedii (Dhat4= 0.84; Confidence Interval [CI]: 0.8 - 0.98); L. guttulus and Puma concolor (Dhat4 = 0.83; CI: 0.78 - 0.93) and L. wiedii and P. concolor (Dhat4 = 0.84; CI: 0.79 - 0.95). We observed a high overlap of activity between L. guttulus and L. pardalis (Dhat1= 0.79; CI: 0.73 - 0.9) and L. pardalis with L. wiedii (Dhat1= 0.79; CI: 0, 7 - 0.93). L. pardalis and P. concolor presented the lowest coefficient of overlap in our study (Dhat1= 0.77; CI: 0.68 - 0.87).

Fig. 4.
Overlap of daily activities between the pairs of the four felid species found in the Papagaios-de-Altitude Private Protected Area in Urupema, Santa Catarina, southern Brazil. The area colored in gray indicates the overlapping of daily activity in each species pair. The parallel lines in each graph indicate the mean time of sunrise (yellow) and sunset (blue) in the study region. Below each graph is the coefficient of overlap for each pair of species, and the confidence interval.

DISCUSSION

Our results indicate predominantly nocturnal activity patterns for two species of Leopardus (L. pardalis and L. wiedii), while Puma concolor and L. guttulus behaved as cathemerals. However, the species showed slight differences in daily activity patterns between years, especially L. pardalis, in which the difference was significant. We found high coefficients of overlap between the daily activity patterns of all four species. Additionally, we observed a similar pattern of seasonal activity for all species, with the highest peaks concentrated between the months of June and September. Pairwise comparisons indicated differences between the seasonal activity patterns of most pairs of species, when considering the two years.

The cathemeral behavior of L. guttulus found in our study, with peaks of nocturnal activity, corroborates previous studies of this species in other regions. According to Oliveira-Santos et al. (2012Oliveira-Santos, L. G. R.; Graipel, M. E.; Tortato, M. A. & Zucco, C. A. 2012. Abundance changes and activity flexibility of the oncilla, Leopardus tigrinus (Carnivora: Felidae), appear to reflect avoidance of conflict. Zoologia 29(2):115-120.) and Nagy-Reis et al. (2019Nagy-Reis, M. B.; Iwakami, V. H. S.; Estevo, C. A. & Setz, E. Z. F. 2019. Temporal and dietary segregation in a neotropical small-felid assemblage and its relation to prey activity. Mammalian Biology 95:1-8.) the species may present a cathemeral behavior in the presence of other felids. Linck et al. (2021Linck, P; Tirelli, F. P.; Bastos, M. C.; Fonseca, A. N.; Cardoso, L. F. & Trigo, T. C. 2021. Daily activity patterns and occurrence of Leopardus guttulus (Carnivora, Felidae) in Lami Biological Reserve, southern Brazil. Iheringia, Série Zoologia, 111:e2021006.) suggest that L. guttulus may modulate their activity in order to reflect the activity of their prey, showing a more nocturnal activity in the warmer months of the year. Similar pattern has been documented for L. tigrinus (previously considered as the same species as L. guttulus) in the Caatinga biome, showing a large peak of activity before dawn and a smaller one at midnight (Penido et al., 2017Penido, G.; Astete, S.; Jácomo, A. T. A.; Sollmann, R.; Tôrres, N.; Silveira, L. & Marinho , JFilho. 2017. Mesocarnivore activity patterns in the semiarid Caatinga: limited by the harsh environment or affected by interspecific interactions? Journal of Mammalogy 98(6):1732-1740.) and it is suggested that the nocturnal behavior of the species is more likely reflecting temperature extremes and the activity of potential prey, rather than influenced by intraguild interactions (Penido et al,. 2017Penido, G.; Astete, S.; Jácomo, A. T. A.; Sollmann, R.; Tôrres, N.; Silveira, L. & Marinho , JFilho. 2017. Mesocarnivore activity patterns in the semiarid Caatinga: limited by the harsh environment or affected by interspecific interactions? Journal of Mammalogy 98(6):1732-1740.). Cruz et al. (2018Cruz, P.; Iezzi, M. E.; De Angelo, C.; Varela, D.; Di Bitetti, M. & Paviolo, M. 2018. Effects of human impacts on habitat use, activity patterns and ecological relationships among medium and small felids of the Atlantic Forest. PLoS ONE 13(8):e0200806.) also identified a mostly nocturnal activity pattern of this species associated with sites with an anthropic presence. Cathemeral species may be able to adjust their activity pattern to local conditions (Di Bitetti et al., 2010Di Bitetti, M. S.; De Angelo, C. D.; Di Blanco, Y. E. & Paviolo, A. 2010. Niche partitioning and species coexistence in a Neotropical felid assemblage. Acta Oecologica 36:403-412.), which could explain the pattern exhibited by L. guttulus in our study.

Leopardus wiedii showed a mostly nocturnal behavior, as it is documented in previous knowledge from this species (Hernández-Sánchez & Santos-Moreno, 2020Hernández-Sánchez, A. & Santos-Moreno, A. 2020. Activity patterns in a feline assemblage in south-west Mexico, and their relationship with prey species. Journal of Tropical Ecology 36(5):225-233.; Horn et al., 2020Horn, P. E.; Pereira, M. J. R.; Trigo, T. C.; Eizirik, E. & Tirelli, F. P. 2020. Margay (Leopardus wiedii) in the southernmost Atlantic Forest: Density and activity patterns under different levels of anthropogenic disturbance. PLoS ONE 15(5):e0232013.). According to Sunquist & Sunquist (2002Sunquist, M. & Sunquist, F. 2002. Wild cats of the world. Chicago, University of Chicago Press. 462p.), the nocturnal behavior is likely related to the activity of their prey, since L. wiedii consumes mainly small rodents (Oliveira, 1994Oliveira, T. 1994. Neotropical Cats: Ecology and Conservation. São Luiz, EDUFMA. 244p.; Rocha-Mendes et al., 2010Rocha-Mendes, F.; Mikich, S. B.; Quadros, J. & Pedro, W. A. 2010. Feeding ecology of carnivores (Mammalia, Carnivora) in Atlantic Forest remnants, Southern Brazil. Biota Neotropica 10(4):21-30.; Bianchi et al., 2011Bianchi, R. C.; Rosa, A. F.; Gatti, A. & Mendes, S. L. 2011. Diet of margay, Leopardus wiedii, and jaguarundi, Puma yagouaroundi, (Carnivora: Felidae) in Atlantic Rainforest, Brazil. Zoologia 28(1):127-132.) that are mostly active at night. Hernández-Sánchez & Santos-Moreno (2020Hernández-Sánchez, A. & Santos-Moreno, A. 2020. Activity patterns in a feline assemblage in south-west Mexico, and their relationship with prey species. Journal of Tropical Ecology 36(5):225-233.) also described a mostly nocturnal activity for L. wiedii and suggested that this pattern could be influenced by prey availability. Horn et al. (2020Horn, P. E.; Pereira, M. J. R.; Trigo, T. C.; Eizirik, E. & Tirelli, F. P. 2020. Margay (Leopardus wiedii) in the southernmost Atlantic Forest: Density and activity patterns under different levels of anthropogenic disturbance. PLoS ONE 15(5):e0232013.) found similar pattern in the Brazilian southernmost Atlantic Forest, where the species was strictly nocturnal even in the human-altered landscapes.

Our results indicate that L. pardalis behaved as mostly nocturnal in the study area. Nagy-Reis et al. (2019Nagy-Reis, M. B.; Iwakami, V. H. S.; Estevo, C. A. & Setz, E. Z. F. 2019. Temporal and dietary segregation in a neotropical small-felid assemblage and its relation to prey activity. Mammalian Biology 95:1-8.) described a similar pattern for the Brazilian southeastern Atlantic Forest, and found a high overlap between the activity of L. pardalis and their potential prey. The predominantly nocturnal activity was also described in Araucaria forest by Marques & Fábian (2018Marques, R. & Fabián, M. E. 2018. Daily activity patterns of medium and large neotropical mammals during different seasons in an area of High Altitude Atlantic Rain Forest in the South of Brazil. Zoociências 19(3):38-64.), where the activity was reduced after daybreak and increased between one and two hours before nightfall, similar to our findings. There are evidences of L. pardalis increasing their nocturnal activity to avoid human presence (Cruz et al., 2018Cruz, P.; Iezzi, M. E.; De Angelo, C.; Varela, D.; Di Bitetti, M. & Paviolo, M. 2018. Effects of human impacts on habitat use, activity patterns and ecological relationships among medium and small felids of the Atlantic Forest. PLoS ONE 13(8):e0200806.), however, the nocturnal behavior is an expected result for this species even in undisturbed areas (Kolowski & Alonso, 2010Kolowski, J. M. & Alonso, A. 2010. Density and activity patterns of ocelots (Leopardus pardalis) in northern Peru and the impact of oil exploration activities. Biological Conservation 143:917-925.). The daily activity patterns of L. pardalis differed significantly between years, showing lower concentration of records close to the mean in 2019 comparing to 2018. This difference might be caused by inter-annual variations in environmental and ecological conditions, however the nocturnal behavior of the species is maintained in both years.

In our study, P. concolor exhibited cathemeral behavior, with several peaks of activity, which is consistent with previous studies in South America. In the Green Corridor of Misiones province, Argentina, and contiguous areas of Brazil, P. concolor is active during the entire day, with a peak of activity in the early morning (Di Bitetti et al., 2010Di Bitetti, M. S.; De Angelo, C. D.; Di Blanco, Y. E. & Paviolo, A. 2010. Niche partitioning and species coexistence in a Neotropical felid assemblage. Acta Oecologica 36:403-412.). This pattern was also found for P. concolor in a tropical montane forest of Costa Rica (Botts et al., 2020Botts, R. T.; Eppert, A. A.; Wiegman, T. J.; Rodriguez, A.; Blankenship, S. R.; Asselin, E. M.; Garley, W. M.; Wagner, A. P.; Ullrich, S. E.; Allen, G. R. & Mooring, M. S. 2020. Circadian activity patterns of mammalian predators and prey in Costa Rica. Journal of Mammalogy 101(5):1313-1331.), where the species co-exist with four other felids. This study emphasized that prey availability is more important than intraguild competition in determining the activity patterns of the felid assemblage. The role of food resource in modulating P. concolor activity patterns is also described by Foster et al. (2013Foster, V. C.; Sarmento, P.; Sollmann, R.; Tôrres, N.; Jácomo, A. T.; Negrões, N.; Fonseca, C. & Silveira, L. 2013. Jaguar and puma activity patterns and predator-prey interactions in four Brazilian Biomes. Biotropica 45:373-379.) in four Brazilian biomes, where both P. concolor and Panthera onca showed intensive nocturnal and crepuscular activity, with high coefficients of overlap.

All pairs of species analyzed in the present study exhibited high coefficients of daily activity overlap. Hernández-Sánchez & Santos-Moreno (2020Hernández-Sánchez, A. & Santos-Moreno, A. 2020. Activity patterns in a feline assemblage in south-west Mexico, and their relationship with prey species. Journal of Tropical Ecology 36(5):225-233.) reported a high activity overlap between L. tigrinus and L. pardalis (Dhat1= 0.76); between L. tigrinus and P. concolor (Dhat1= 0.79) and between L. pardalis and P. concolor (Dhat1= 0.74-0.77), that are very similar to our findings. The authors pointed out that prey diversity and availability at the site facilitated temporal overlap between felid species. Furthermore, we found that the overlap of the daily activity of L. pardalis and P. concolor was the lowest in our study, with very different peak times. This pattern may suggest an attempt by L. pardalis to avoid encountering P. concolor, as observed in previous studies (Massara et al., 2018Massara, R. L.; Barreto, M. & Chiarello, A. G. 2018. Effect of humans and pumas on the temporal activity of ocelots in protected areas of Atlantic Forest. Mammalian Biology 92:86-93.; Finnegan et al., 2021Finnegan, S. P.; Gantchoff, M. G.; Hill, J. E.; Silveira, L.; Tôrres, N. M.; Jácomo, A. T. & Uzal, A. 2021. “When the felid’s away, the mesocarnivores play”: seasonal temporal segregation in a neotropical carnivore guild. Mammalian Biology 101:631-638.). However, Herrera et al. (2018Herrera, H.; Chávez, E. J.; Alfaro, L. D.; Fuller, T. K.; Montalvo, V.; Rodrigues, F. & Carrillo, E. 2018. Time partitioning among jaguar Panthera onca, puma Puma concolor and ocelot Leopardus pardalis (Carnivora: Felidae) in Costa Rica’s dry and rainforests. Revista de Biología Tropical 66(4):1559-1568.) found high overlap coefficients among the two felids, and suggested that space use or prey availability may have a main role in determining their activity patterns. In the same study, the two species also differed in their peaks of activity and showed different degrees of nocturnality, which was also observed in the Papagaios-de-Altitude area.

Studies have shown that the diet overlap of felid species is variable and influenced by morphological and behavioral differences, in addition to environmental factors and prey availability (Martins et al., 2008Martins, R.; Quadros, J. & Mazzolli, M. 2008. Food habits and anthropic interference on the territorial marking activity of Puma concolor and Leopardus pardalis (Carnivora: Felidae) and other carnivores in the Juréia-Itatins Ecological Station, São Paulo, Brazil. Revista Brasileira de Zoologia 25(3):427-435.; Kasper et al., 2016Kasper, C. B.; Peters, F. B.; Christoff, A. U. & De Freitas, T. R. O. 2016. Trophic relationships of sympatric small carnivores in fragmented landscapes of southern Brazil: niche overlap and potential for competition. Mammalia 80(2):143-152.; Nagy-Reis et al., 2019Nagy-Reis, M. B.; Iwakami, V. H. S.; Estevo, C. A. & Setz, E. Z. F. 2019. Temporal and dietary segregation in a neotropical small-felid assemblage and its relation to prey activity. Mammalian Biology 95:1-8.). The broad habitat and diet profile of these animals contributes to greater plasticity, and may allow them to adapt locally to available resources. In more restricted and fragmented landscapes, space could become a limiting factor, forcing smaller species to temporarily segregate with top predators. However, we consider that the connectivity of the Papagaios-de-Altitude with an adjacent area, the Complexo Serra da Farofa Private Protected Area, with a similar phytophysiognomy and an area of approximately 4,987 hectares, may facilitate the activity overlap of these species. Felids tend to occupy a wide home range and benefit from the set of interconnected environments, which support an abundance of resources for each species (Ashrafzadeh et al., 2020Ashrafzadeh, M. R.; Khosravi, R.; Adibi, M. A.; Taktehrani, A.; Wan, H. Y. & Cushman, S. A. 2020. A multi-scale, multi-species approach for assessing effectiveness of habitat and connectivity conservation for endangered felids. Biological Conservation 245:10852.).

When comparing the seasonal activity patterns between pairs of species, we found that most pairs showed significant differences. However, all species showed the highest peak of activity concentrated between the months of June and September, a period that corresponds to winter in the southern hemisphere. During these months, Araucaria (Araucaria angustifolia (Bertol.) Kuntze) nuts fall in the Araucaria Forest. The nuts are an important food resource for the fauna, mainly birds and small rodents. The winter period is scarce in zoochoric fruits in the forests (Vieira & Paise, 2006Vieira, E. M. & Paise, G. 2006. Feeding of small rodents on seeds and fruits: A comparative analysis of three species of rodents of the Araucaria forest, southern Brazil. Acta Theriologica 51(3):311-318.; Paise & Vieira, 2005Paise, G. & Vieira, E. M. 2005. Produção de frutos e distribuição espacial de angiospermas com frutos zoocóricos em uma Floresta Ombrófila Mista no Rio Grande do Sul, Brasil. Revista Brasileira de Botânica 28(3):615-625.), and the Araucaria nut has a high energy content, especially of starch and protein (Rosado et al., 1994Rosado, R. M.; Ferreira, A. G.; Mariath, J. E. A. & Cocucci, A. E. 1994. Amido no megagametófito de Araucaria angustifolia (Bert.) O. Ktze: degradação durante a germinação e desenvolvimento do esporófito. Acta Botanica Brasilica 8(1):35-43.), presenting a high relevance for the maintenance of animal populations. Small rodents are especially influenced by this dynamic, since their populations can present an abrupt increase in their densities correlated with the high availability of food resources (Alho & Pereira, 1985Alho, C. J. R. & Pereira, L. A. 1985. Population ecology of a cerrado rodent community in central Brazil. Revista Brasileira de Biologia 45(4):597-607.; Greenwood, 1985Greenwood, J. J. D. 1985. Frequency-dependent selection by seed predators. Oikos 44:195-210.; Orland & Kelt, 2007Orland, M. C. & Kelt, D. A. 2007. Responses of a Heteromyid Rodent Community to Large and Small Scale Resource Pulses: Diversity, Abundance, and Home-Range Dynamics. Journal of Mammalogy 88(5):1280-1287.; Prevedello et al., 2013Prevedello, J. A.; Dickman, C. R.; Vieira, M. V. & Vieira, E. M. 2013. Population responses of small mammals to food supply and predators: A global meta-analysis. Journal of Animal Ecology 82(5):927-936.). Furthermore, it is known that rodents are important predators of the Araucaria nut, also acting as dispersers (Vieira & Iob, 2009Vieira, E. M. & Iob, G. 2009. Dispersão e predação de sementes da araucária (Araucaria angustifolia). In: Fonseca, C. R.; Souza, A. F.; Leal-Zanchet, A. M.; Dutra, T.; Backes, A. & Ganade, G. eds. Floresta de Araucária: Ecologia, Conservação e Desenvolvimento Sustentável. Ribeirão Preto, Holos, p. 85-95.). Studies show the increase in the abundance of small rodents linked to the Araucaria nut harvest in southern Brazil (Cademartori et al., 2004Cadermatori, C. V.; Fabián, M. E. & Menegheti, J. O. 2004. Variações na abundância de roedores (Rodentia, Sigmodontinae) em duas áreas de floresta ombrófila mista, Rio Grande do Sul, Brasil. Revista Brasileira de Zoociências 6(2):147-167.; Paise, 2005Paise, G. 2005. A influência do clima e da disponibilidade de recursos alimentares em uma comunidade de pequenos mamíferos no sul do Brasil. Mastozoología Neotropical 12(1):102-103.), starting from June to August, and which tends to decline at the beginning of September, period when seed fall ceases (Cadermatori et al., 2004Cadermatori, C. V.; Fabián, M. E. & Menegheti, J. O. 2004. Variações na abundância de roedores (Rodentia, Sigmodontinae) em duas áreas de floresta ombrófila mista, Rio Grande do Sul, Brasil. Revista Brasileira de Zoociências 6(2):147-167.). These data overlap with the higher frequencies of felids in the Papagaios-de-Altitude Private Protected Area.

According to Oliveira (1994Oliveira, T. 1994. Neotropical Cats: Ecology and Conservation. São Luiz, EDUFMA. 244p.) and Rocha-Mendes (2010Rocha-Mendes, F.; Mikich, S. B.; Quadros, J. & Pedro, W. A. 2010. Feeding ecology of carnivores (Mammalia, Carnivora) in Atlantic Forest remnants, Southern Brazil. Biota Neotropica 10(4):21-30.), small and medium-sized rodents are prey of great importance in the diet of all species present in our study. The abundance of prey is a factor that can promote convergence in use of habitat among felids (Santos et al., 2019Santos, F.; Carbone, C.; Wearn, O. R.; Rowcliffe, J. M.; Espinosa, S.; Lima, M. G. M.; Ahumada, J. A.; Gonçalves, A. L. S.; Trevelin, L. C.; Alvarez-Loayza, P.; Spironello, W. R.; Jansen, P. A.; Juen, L. & Peres, C. A. 2019. Prey availability and temporal partitioning modulate felid coexistence in Neotropical forests. PLoS One 14(3):e0213671.) and their activity patterns usually overlap with that of their potential prey, maximizing the probability of encounters and minimizing energy expenditure during hunting (Emmons & Feer, 1997Emmons, L. H. & Feer, F. Neotropical Rainforest Mammals: A Field Guide. 1997. Chicago, The University of Chicago Press. 396p.; Foster et al., 2013Foster, V. C.; Sarmento, P.; Sollmann, R.; Tôrres, N.; Jácomo, A. T.; Negrões, N.; Fonseca, C. & Silveira, L. 2013. Jaguar and puma activity patterns and predator-prey interactions in four Brazilian Biomes. Biotropica 45:373-379., Porfirio et al., 2016Porfirio, G.; Foster, V. C.; Fonseca, C. & Sarmento, P. 2016. Activity patterns of ocelots and their potential prey in the Brazilian Pantanal. Mammalian Biology 81(5):511-517.). Thus, it is likely that the peak activity of the felids in the study area has a positive correlation with the Araucaria nut supply, and the presence of small rodents that benefit from it.

The camera trapping method was efficient to elucidate the patterns of daily and seasonal activity of the species in the study area, as well as their similarities. In our study, the species with the lowest capture success was L. pardalis, which is explained by its strong association with the water resource and its surroundings (Wolff et al., 2019Wolff, N. M.; Ferreguetti, A. C.; Tomas, W. M. & Bergallo, H. G. 2019. Population density, activity pattern and habitat use of the ocelot Leopardus pardalis in an Atlantic Forest protected area, Southeastern Brazil. Hystrix, the Italian Journal of Mammalogy 30(2):120-125.), reducing the chance of capture by cameras further away from this location. Furthermore, P. concolor was the species from which we obtained the most records. Studies report that the body mass of animals affects recording success, because larger species have higher probability of triggering the cameras (Tobler et al., 2008Tobler, M. W.; Carrillo-Percastegui, S. E.; Pitman, R. L.; Mares, R. & Powell, G. 2008. An evaluation of camera traps for inventorying large and medium-sized terrestrial rainforest mammals. Animal Conservation 11:169-178.; Lyra-Jorge et al., 2008Lyra-Jorge, M. C.; Ciocheti, G.; Pivello, V. R. & Meirelles, S. T. 2008. Comparing methods for sampling large and medium sized mammals: Camera traps and track plots. European Journal of Wildlife Research 54:739-744.). Therefore, P. concolor may present the higher number of records as a consequence of its larger size, in comparison to the other felids in our study.

Our study elucidated the daily and seasonal activity patterns of felids in a protected area of the Santa Catarina plateau, indicating a high overlap of activity between the species. Our findings corroborate previous knowledge from the daily activity patterns of the species, likely reflecting environmental conditions and the activity of prey. Furthermore, we emphasize the correlation between the seasonal activity peak of the felids and the Araucaria nut harvest in the study area, possibly associated with the increase in the occurrence of small rodents. We did not find evidence of temporal segregation between the felids in the Papagaios-de-Altitude Private Protected Area. Further research, such as for spatial and trophic use, are needed to elucidate the mechanisms of ecological segregation of felids at the site.

Acknowledgments

The authors are thankful to the Universidade de Passo Fundo for providing the physical structure for the research; to the Associação Amigos do Meio Ambiente (AMA) for authorizing the research in the Papagaios-de-Altitude Private Protected Area and for the access to the image database; to the biologists Viviane Telles Gaboardi and Roberto Tomasi Junior, and to the director of management of the area, Idolar Machado, for participating in data collection in the field. The authors are also grateful to the Rainforest Trust (USA), IUCN-NL (Netherlands) and Fundação Grupo Boticário de Conservação da Natureza (Brazil) for their support in the acquisition of research equipment, and to Parque das Aves (Foz do Iguaçu, Brazil) for logistical support during the field stages.

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Martinez, J; Gaboardi, V. T. R.; Prestes, N. P.; Bortoncello, V. L.; Dos Santos, L. E. S.; Tomasi , R.Jr & Perez, A.V. R. 2021. RPPN Papagaios-de-Altitude: reserva estratégica de pinhões para a fauna silvestre. In: Martinez, J. & Prestes, N. P. org. Biologia da Conservação: Programa Nacional para a Conservação do Papagaio-de-peito-roxo e Outras Iniciativas. Tapera, Ed. Lew, p. 317-343.
Martins, R.; Quadros, J. & Mazzolli, M. 2008. Food habits and anthropic interference on the territorial marking activity of Puma concolor and Leopardus pardalis (Carnivora: Felidae) and other carnivores in the Juréia-Itatins Ecological Station, São Paulo, Brazil. Revista Brasileira de Zoologia 25(3):427-435.
Massara, R. L.; Barreto, M. & Chiarello, A. G. 2018. Effect of humans and pumas on the temporal activity of ocelots in protected areas of Atlantic Forest. Mammalian Biology 92:86-93.
Ministério do Meio Ambiente. 2022. Lista Oficial de Espécies da Fauna Brasileira Ameaçadas de Extinção. Brasília, ICMBio/MMA.
Morales, M. M. & Giannini, N. P. 2010. Morphofunctional patterns in Neotropical felids: species co-existence and historical assembly. Biological Journal of the Linnean Society 100(3):711-724.
Nagy-Reis, M. B.; Iwakami, V. H. S.; Estevo, C. A. & Setz, E. Z. F. 2019. Temporal and dietary segregation in a neotropical small-felid assemblage and its relation to prey activity. Mammalian Biology 95:1-8.
Oliveira, T. 1994. Neotropical Cats: Ecology and Conservation. São Luiz, EDUFMA. 244p.
Oliveira, T. G. & Pereira, J. A. 2014. Intraguild predation and interspecific killing as structuring forces of carnivoran communities in South America. Journal of Mammalian Evolution 21(4):427-436.
Oliveira-Santos, L. G. R.; Graipel, M. E.; Tortato, M. A. & Zucco, C. A. 2012. Abundance changes and activity flexibility of the oncilla, Leopardus tigrinus (Carnivora: Felidae), appear to reflect avoidance of conflict. Zoologia 29(2):115-120.
Orland, M. C. & Kelt, D. A. 2007. Responses of a Heteromyid Rodent Community to Large and Small Scale Resource Pulses: Diversity, Abundance, and Home-Range Dynamics. Journal of Mammalogy 88(5):1280-1287.
Paise, G. 2005. A influência do clima e da disponibilidade de recursos alimentares em uma comunidade de pequenos mamíferos no sul do Brasil. Mastozoología Neotropical 12(1):102-103.
Paise, G. & Vieira, E. M. 2005. Produção de frutos e distribuição espacial de angiospermas com frutos zoocóricos em uma Floresta Ombrófila Mista no Rio Grande do Sul, Brasil. Revista Brasileira de Botânica 28(3):615-625.
Penido, G.; Astete, S.; Jácomo, A. T. A.; Sollmann, R.; Tôrres, N.; Silveira, L. & Marinho , JFilho. 2017. Mesocarnivore activity patterns in the semiarid Caatinga: limited by the harsh environment or affected by interspecific interactions? Journal of Mammalogy 98(6):1732-1740.
Pianka, E. R. 1974. Evolutionary Ecology. New York, Harper & Row. 356p.
Porfirio, G.; Foster, V. C.; Fonseca, C. & Sarmento, P. 2016. Activity patterns of ocelots and their potential prey in the Brazilian Pantanal. Mammalian Biology 81(5):511-517.
Prevedello, J. A.; Dickman, C. R.; Vieira, M. V. & Vieira, E. M. 2013. Population responses of small mammals to food supply and predators: A global meta-analysis. Journal of Animal Ecology 82(5):927-936.
R Core Team. 2020. R: A language and environment for statistical computing. R Foundation for Statistical Computing. Available at https://www.R-project.org/ >. Access on 5 June 2021.
» https://www.R-project.org/
Ridout, M. & Linkie, M. 2009. “Estimating overlap of daily activity patterns from camera trap data.” Journal of Agricultural, Biological, and Environmental Statistics 14:322-337.
Rocha-Mendes, F.; Mikich, S. B.; Quadros, J. & Pedro, W. A. 2010. Feeding ecology of carnivores (Mammalia, Carnivora) in Atlantic Forest remnants, Southern Brazil. Biota Neotropica 10(4):21-30.
Roemer, G. W.; Gompper, M. E. & Valkenburgh, B. V. 2009. The ecological role of the mammalian mesocarnivore. BioScience 59(2):165-173.
Romero-Muñoz, A.; Maffei, L.; Cuéllar, E.; Noss, A. J. 2010. Temporal separation between jaguar and puma in the dry forests of southern Bolivia. Journal of Tropical Ecology 26:303-311.
Rosado, R. M.; Ferreira, A. G.; Mariath, J. E. A. & Cocucci, A. E. 1994. Amido no megagametófito de Araucaria angustifolia (Bert.) O. Ktze: degradação durante a germinação e desenvolvimento do esporófito. Acta Botanica Brasilica 8(1):35-43.
Santos, F.; Carbone, C.; Wearn, O. R.; Rowcliffe, J. M.; Espinosa, S.; Lima, M. G. M.; Ahumada, J. A.; Gonçalves, A. L. S.; Trevelin, L. C.; Alvarez-Loayza, P.; Spironello, W. R.; Jansen, P. A.; Juen, L. & Peres, C. A. 2019. Prey availability and temporal partitioning modulate felid coexistence in Neotropical forests. PLoS One 14(3):e0213671.
Schoener, T. W. 1974. Resource partitioning in ecological communities. Science 185:27-39.
Srbek-Araujo, A. C. & Chiarello, A. G. 2007. Armadilhas fotográficas na amostragem de mamíferos: considerações metodológicas e comparação de equipamentos. Revista Brasileira de Zoologia 24(3):647-656.
Sunquist, M. & Sunquist, F. 2002. Wild cats of the world. Chicago, University of Chicago Press. 462p.
Tobler, M. W.; Carrillo-Percastegui, S. E.; Pitman, R. L.; Mares, R. & Powell, G. 2008. An evaluation of camera traps for inventorying large and medium-sized terrestrial rainforest mammals. Animal Conservation 11:169-178.
Vieira, E. M. & Iob, G. 2009. Dispersão e predação de sementes da araucária (Araucaria angustifolia). In: Fonseca, C. R.; Souza, A. F.; Leal-Zanchet, A. M.; Dutra, T.; Backes, A. & Ganade, G. eds. Floresta de Araucária: Ecologia, Conservação e Desenvolvimento Sustentável. Ribeirão Preto, Holos, p. 85-95.
Vieira, E. M. & Paise, G. 2006. Feeding of small rodents on seeds and fruits: A comparative analysis of three species of rodents of the Araucaria forest, southern Brazil. Acta Theriologica 51(3):311-318.
Wolff, N. M.; Ferreguetti, A. C.; Tomas, W. M. & Bergallo, H. G. 2019. Population density, activity pattern and habitat use of the ocelot Leopardus pardalis in an Atlantic Forest protected area, Southeastern Brazil. Hystrix, the Italian Journal of Mammalogy 30(2):120-125.
Zielinski, W. J. 1986. Circadian rhythms of small carnivores and the effect of restricted feeding on daily activity. Physiology & Behavior 38(5):613-620.

Supplementary material

Supplementary Material 1. Results from the Watson’s Two Test of Homogeneity (U²) to assess differences in the daily activity patterns between pairs of species in the Papagaios-de-Altitude Private Protected between pairs of species in the Papagaios-de-Altitude Private Protected Area.

Supplementary Material 2. Results from the Watson’s Two Test of Homogeneity (U²) to assess differences in the seasonal activity patterns of Homogeneity (U²) to assess differences in the seasonal activity patterns between pairs of species in the Papagaios-de-Altitude Private Protected Area

Publication Dates

Publication in this collection
07 Apr 2023
Date of issue
2023

History

Received
02 Aug 2022
Accepted
08 Feb 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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	L. guttulus	L. pardalis	L. wiedii	P. concolor
Day	35.19	16.36	32.47	37.76
Night	64.81	83.64	67.53	62.24

Brasil