The Orinoco basin has a vast richness of fauna and flora, providing multiple ecosystem services such as below-ground carbon storage, feeding resources for domestic and wild animals and habitat for charismatic species (Buisson et al., 2019). The Orinoco region comprises at least 70 species of small mammals including 26 species of marsupials (Ferrer Pérez et al., 2009) that inhabit fire adapted and fire sensible ecosystems such as neotropical savannas and gallery forests, respectively (Armenteras et al., 2021). We conducted this study in the Bojonawi Civil Society Reserve (Fig. 1), a protected area that is located in the second largest savanna system in South America after Brazil (Hernández and Sánchez, 1992; Romero-Ruiz et al., 2012).

Fig. 1.

Location of the sampling sites at the Bojonawi Civil Society Reserve located in the Colombian Orinoco. Each red point corresponds to burned sampling sites, whereas green points correspond to unburned sampling sites.

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The Bojonawi reserve belongs to the Colombian Orinoco llanos, municipality of Puerto Carreño (6°07′ and 6°02′N 67°29′ and 67°34′W), and it encompasses an area of 4680ha (Trujillo et al., 2008). It has a tropical climate, with a uniform temperature throughout the year and a monomodal precipitation regime ranging from 1000mm to 3500mm/year (Correa et al., 2005). The dry season takes place between December and April, during which most of the fires occur; and the wet season occurs between May and November, when gallery forests and most of the savannas are flooded. In 2015, close to 80% of the Reserve was burned as a consequence of an accidental wildfire during the dry season, affecting most of the savannas, and approximately 350ha of the forest.

The sampling of non-volant small mammals was carried out three years after the last fire in the study area. The survey period covered the beginning (November of 2018 and 2019) and end (March–April of 2019 and 2020) of the dry period and included a total of 24 sampling sites randomly distributed across the Bojonawi reserve (Fig. 1). A half of the sites (12) were located at unburned sections (UB) and the other half at burned sections (B). In each treatment (unburned-burned), six sampling sites were located between 80 and 100m from the forest edge, and six sampling sites at the forest's interior (Fig. 2). We chose this arrangement in two different areas (edge-interior) of the gallery forests to encompass the extent of variability in the vegetation structure. Unburned sites were considered as controls since these areas remain unburned for at least the last 20 years. Fire history was reconstructed using satellite imagery, official vegetation cartography, and data on thermal abnormalities seven years before sampling (2010–2017). Data was gathered from the Fire Information for Resource Management System (FIRMS) as well as from MODIS and VIRS sensors and previous vegetation studies (Armenteras et al., 2021).

Fig. 2.

Sampling scheme in the savanna gallery forest landscape of the Bojowani reserve, Colombia (a). L means large size Sherman traps (10×12×38cm), M means a medium size Sherman trap (8×9×30cm), and S means small size Sherman trap (8×9×23cm). Real photographs of unburned – UB (b) and burned areas – B (c).

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Although sampling sites had the same general physiognomy and similar climatic conditions, they can be considered as independent sampling units since they were separated by a considerable distance. The maximum and mean distance between contiguous sampling sites was 1000 and 304m, respectively. Such a distance between contiguous sampling sites is not easily covered by South American Cratidae species, whose home ranges (ranging from 70 to 1000m2, Alho et al., 1986; Giuggioli et al., 2005) and maximum daily movement (around 100m, Maroli et al., 2020) tend to be smaller.

Sampling sites consisted of a set of 10 Sherman live-traps (5 traps of 8×9×23cm, 4 traps of 10×12×38cm, and 1 trap of 8×9×30cm; H.B. Sherman Traps Inc., Tallahassee, Florida, USA). At each sampling site, traps were deployed on the ground following two parallel lines encompassing a total area of 900m2; each line consisted of 5 traps spaced apart by 15m and each line was spaced apart by 15m as well. Each trap was georeferenced, and its location was marked with a green plastic tube that allowed us to place the traps at the same spot during each trapping period. Sherman traps were baited with a mix of peanut butter, oats, sardines, and banana essence. At burned locations, the traps were covered with litter to avoid detection by potential predators and overheating of the captured animals.

At each sampling campaign, the traps were activated at dusk, checked daily at dawn, and rebaited during the day. Each trapping campaign lasted for 11 continuous nights. The total capture effort was 2640 trap nights per trapping period (10,560 traps nights in total).

For each captured individual we registered the date, trap location, genus (or species when possible), weight, sex, age (juvenile or adult) and reproductive stage (inactive, pregnant, inguinal testis or scrotum testis) (Hoffmann et al., 2010). The fur of each captured individual was marked with a unique clipped hair pattern to identify recaptures within each sampling period and then was liberated at the exact place where it was captured. Field identification was carried out following the protocols for morphological characters and distributions established by Emmons and Feer (1997); Cuartas-Calle and Muñoz-Arango (2003); Gardner (2008) and Patton et al. (2015) for most of the captured rodents and marsupials, and Voss (1991) for the rodents that make up the Zygodontomys genus.

Those individuals that could not be identified in the field were sacrificed using an injection of lidocaine in the caudal artery and collected for further identification in the laboratory. These specimens were preserved by preparing their skin and skull that were then deposited in the mammal collection “Alberto Cadena Garcia” from the Natural Science Institute (ICN) of the National University of Colombia – Bogotá. Identification followed protocols suggested for the external and cranial morphological characters in Patton et al. (2015) for South America rodents and by Gardner (2008) for South America marsupials. Specifically, we followed Weksler (2015) to determine the genus from the Oryzomyini tribe. Carleton and Musser (2015) was used to determine species of Oecomys, and Voss (1991, 2015) was used to determine the species of Zygodontomis. We confirmed the specimen's identification by comparing our collected specimens with the deposited material in the mammal collection of the ICN and by consulting with experts.

This study was supported by the research permit No. 0255 of March 14, 2014 of the National Authority of Environmental Licenses (ANLA) and endorsed by the Ethics committee of the Sciences Faculty of the National University of Colombia – Bogotá, certificate 02-2018 and 07-2019. All the field and laboratory methods followed the guidelines established by the American Society of Mammologists for the use of wild mammals for research and education (Sikes, 2016).

To describe the vegetation structure, we estimated plant species diversity and structural diversity at each sampling site. A circular plot of 1m2 was established using each Sherman trap as the center point (Sunyer et al., 2015), so that the vegetation was estimated at a fine-scale in all 240 plots. Moreover, the collected information at the trap scale was averaged from the 10 traps of each sampling site, covering an area of 900m2, to have a measure of vegetation structure at the sampling site level. We followed Rangel and Lozano (1986) to classify vegetation strata according to its height: ground <0.3m, herbaceous (h) range from 0.3 to 1.5m, shrub (ar) from 1.5 to 5m, subarboreal (Ar) from 5 to 12m, low arboreal (Ai) from 12 to 25m, and high arboreal >25m. The cover percentage of the woody debris was also assessed. At every site, we identified and counted the number of plant species that may provide food for small mammals (seed, fruit, leaf, sprout), with support of local botanists and ecologists. Although this measure does not provide an accurate estimation on the actual food resources, given the diversity of small mammals, the different phenology in fruit production, etc., it may represent a proxy of potential food availability for the community of small mammals across the study area.

Plant species diversity was estimated by calculating the first three Hill numbers (q=0,1,2). The Hill numbers represent a mathematically unified family of diversity indices that incorporate the variability in relative abundance and species richness by changing the exponent q (Jost, 2007, 2006). When q=0, the species abundances do not count at all and the species richness is obtained. When q=1, the species are weighed in proportion to their frequencies, and the index value can be interpreted as the effective number of common species in the community. When q=2, abundant species are favored, and rare species are discounted. Thus, index values are equivalent to the inverse Simpson concentration. Differences in plant diversity between burned and unburned sites were tested using t-tests. The structural diversity of vegetation was estimated by means of a principal component analysis (PCA) using information about the coverages (%) of vegetation strata. We retained the first two components (pca1 and pca2) as covariates of hierarchical models.

To determine the mid-term effects of fire, we assessed the changes in the composition, abundance, and detectability of small mammal communities in burned and unburned gallery forests four years after fire. To account for low capture rates (several zeros in datasets), we employed hierarchical occupancy models (MacKenzie et al., 2002). These models allow for more precise estimates of occupancy by accounting for differences in species detectability (i.e., a great number of absences) at different scales. These models have been used for addressing ecological questions such as species presence in response to fire disturbances, providing probabilistic information of the species presence in relationship to predictable variables (Anderson et al., 2016; Kéry and Royle, 2008; MacKenzie et al., 2002).

We did not include recaptures in statistical models because of the low-recapture rates. Hierarchical models consist of one submodel to describe the ecological process (or ‘state’) and another submodel for the observational process, which is conditional by the ecological process (Kéry and Royle, 2016). The ecological process is modeled as a Bernoulli random variable governed by the ‘success probability’ Ψ:

The observational process is modeled as a Bernoulli random variable conditional on the occupancy (z) and the probability of detection (p). The parameter p models the imperfect detectability of species due to trap type, abiotic conditions, or seasonal trends. In this way, the observational process is:

We constructed an a priori set of candidate models to evaluate whether fire or vegetation structure affect the occupation probability. As covariates we used the sites’ treatment or condition (burned or unburned), vegetation structure described by the first two components of the PCA, sampling occasion (1–4), potential food availability (the number of edible plant species), and woody debris (percentage of woody debris at each site). All the covariates, except vegetation structure (pca1 and pca2), were standardized with mean 0 and standard deviation 1. Since we did not find differences between forest edge and forest interior in both treatment transects, we combined this data for analysis of fire effects on occupation probability.

We followed an information-based approach to select the best candidate models. In this way, we used the corrected Akaike information criterion (AICc) to select the models that represented species detection and best occupancy while using the fewest parameters (Burnham and Anderson, 2002). We considered that models with ΔAICc>4 units had low support (Burnham and Anderson, 2002). Additionally, we estimated the goodness-of-fit (GOF) of the best-ranked models throughout parametric bootstrapping (Fiske and Chandler, 2011). Analyses were conducted using functions implemented in ‘ade4’ and ‘unmarked’ R packages (R Core Team, 2017).

The comparison of the Hill numbers revealed that fire has long-term effects on plant diversity at the Bojonawi Civil Society Reserve (Fig. 3A–C). Three years after the last fire event, the average richness of species at burned sites was lower than at unburned sites (Fig. 3A; t-test t=−6.93, p-value<0.0001). The same trend was observed when species abundances were considered to estimate the Hill numbers q=1 (Fig. 3B; t-test t=−5.81, p-value<0.0001) and q=2 (Fig. 3C; t-test t=−3.14, p-value<0.001). Fire also affected the distribution of vegetation strata (Fig. 3D). As indicated in the first component of the PCA (pca1), which explained 62.5% of the variance, fire mainly affected the ground, herbaceous, and arboreal strata. Unburned sites with a high coverage of ground and arboreal strata were on the positive side of the first component axis, while burned sites with high coverage of the herbaceous stratum were on the negative side. The second component (pca2), which explained 18.6% of the variance, described the variability of sites in terms of the shrub and low-arboreal strata. The distribution of sites along this component was not linked to fire effect.

Fig. 3.

Vegetation structure and plant diversity at the Bojonawi Civil Society Reserve. (A–C) The first three Hill Numbers describing plant diversity at burned and unburned sites. Contour of violins plots provide information about the probability density of the data, boxplots within violins show median, quartiles and range. (D) Principal components analysis (PCA) that summarizes the information of the vegetation structure estimated at the study sites. Habitat variables herb=herbaceous, SubArb=subarboreal, Arb=arboreal. The biggest circle and triangle represent the centroid position in the ordination plane of burned and unburned sites.

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A sampling effort of 10,560 trap/nights resulted in the capture of 134 individuals, comprising six species: two rodents and four marsupials. We captured 49 individuals of Zigodontomys brevicauda (cane mouse), 67 of Oecomys sp. (arboreal rice rats), 15 of Didelphis marsupialis (common opossum), 1 of Philander cf. opossum Linnaeus, 1758 (gray four-eyed opossum), 1 of Marmosops cf. noctivagus Tschudi, 1845 (white-bellied slender opossum), and 1 of Marmosa sp. Gray, 1821. We detected the first three species in the four sampling periods, while Marmosops cf. noctivagus, Philander cf. opossum, and Marmosa sp. were detected only once during the sampling of March 2020 in the unburned area. Oecomys sp. and D. maruspialis were detected in both burned and unburned areas, but their abundance peaked in the unburned sites (Fig. 4A and B). Zigodontomys brevicauda was primarily found in burned areas (Fig. 4C). We did not found differences between forest edge and forest interior for these three species in both treatments (Fig. 4). We recorded 31 recaptures of 19 different individuals, mainly of Z. brevicauda, captured during the sampling season of March 2020.

Fig. 4.

Average number of individuals per sampling recorded in burned and unburned areas in Bojonawi Civil Society Reserve. At each sampling, 240 Sherman traps were set in unburned and burned forest and opened for 11 nights in a row. Bars represent 1SD. Results displayed comprise 4 samplings periods.

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Parametric bootstrapping showed that all the best-ranked models fit the data well. The effect of fire was included among the most plausible models for Z. brevicauda and D. marsupialis (Table 1). Model predictions showed that the occupancy probability changed between burned and unburned sites. Z. brevicauda had the broadest distribution across burned sites (Fig. 5a), while D. marsupialis had the broadest distribution across unburned sites (Fig. 5D). The differences in vegetation structure linked to fire (‘pca1’) were also included in some of the most plausible models: both species had a higher probability of occupancy in sites with a greater frequency of the arboreal strata (Fig. 5B and D). For both species, the detection covariates included among the best-ranked models were the sampling occasion and potential food availability (i.e. number of species that potentially provide food) (Table 1). The probability of detection increased during the last sampling periods (Fig. 5E). Meanwhile, the probability of detection for Z. brevicauda and D. marsupialis decreased at sites with higher potential food availability provided by the vegetation (Fig. 5F).

Fig. 5.

Occupancy and detection probability of Z. brevicauda (A–C) and D. marsupialis (D–F) according to the two best-ranked models in Table 1. Values of the multivariate gradient of vegetation structure were extracted from Axis 1 of the principal component analysis. The lowest negative values indicated the highest coverage of the herbaceous stratum, whereas the highest positive values indicated the highest coverage of ground and arboreal strata.

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The occupancy probability of Oecomys sp. did not differ between burned and unburned sites but was mainly explained by the vegetation structure. Both principal components, pca1 and pca2, were included as covariates of the best-ranked models (Table 1). The predicted occupancy probability increased in the positive sides of the pca1 and pca2 (Fig. 6A and B), suggesting that Oecomys sp. distribution increased at sites with greater coverage of shrub and arboreal strata (Fig. 6A and B), accordingly with the biology and ecology of this species (Emmons and Feer, 1997; Hershkovitz, 1960). The best-ranked models did not include a covariable explaining the detection probability of this species.

Fig. 6.

Occupancy and detection probability of Oecomys sp. according to the two best-ranked models in Table 1. Values of the multivariate gradient of vegetation structure were extracted from the first two axes of the principal component analysis. In both axes, the highest positive values indicate the highest coverage of ground and arboreal strata.

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