Study area

Our study was carried out in the Andean arid enclave known as Tatacoa Desert, a natural protected area located in the eastern bank of the Magdalena River in the municipalities of Villavieja and Baraya in the Department of Huila, in Colombia (N 3.278, W-75.156) (Hermelin Reference Hermelin2016) (Figure 1).Tatacoa Desert is a large sub-desertic area that covers about 300 km² with an average annual temperature of 28°C and an average annual precipitation of 1190mm distributed in two rainy periods (February–May/October–December) (Rojas-Marín et al. Reference Rojas-Marín, Pérez-Gómez and Fernández-Méndez2019; Sarmiento Reference Sarmiento1975, Reference Sarmiento1976). The geomorphology of Tatacoa Desert is characterized by a diverse array of landforms, such as alluvial fans, deep cliffs, and sand sheets, mainly shaped by erosion. The main erosional force are occasional heavy downpours that have dissected the landscape into intricate networks of gullies and ravines. Besides water, eolian processes and human activity are ongoing processes contributing to erode and modify the existing landscape (Hermelin Reference Hermelin2016).

Figure 1. Camera trap locations in Tatacoa Desert, a protected area in Huila Department, Colombia, with land cover description.

Camera-trap sampling

The camera-trap sampling was based on protocols developed by the Tropical Ecology Assessment and Monitoring Network (TEAM) (Jansen et al. Reference Jansen, Ahumada, Fegraus and O’Brien2014; TEAM Network 2011). The camera-trap stations array was planned in QGIS version 3.16 (QGIS Development Team 2020), randomly assigning the location of each camera-station on the forest cover map of the Tatacoa Desert. Afterward, in the field, cameras were set up as closely as possible to each one of the planned locations. Throughout the study area, we set up 34 camera-trap stations with one camera-trap per station. To ensure spatial independence between stations and given that there are no records of animals with large movements (e.g., jaguars) in the study area, the distance between camera trap stations varied between 500 and 1500 m. We performed a Moran’s I test (Gittleman and Kot Reference Gittleman and Kot1990) using the richness values of each camera to assess whether there was spatial autocorrelation between cameras. We used three camera trap models: (1) Bushnell TrophyCam HD, (2) Browning Strike Force, and (3) Moultrie D80. Cameras were placed on trees at an average height of 40 cm and were set up to take three photos on each activation event and with a 30 second delay between consecutive events. Cameras were continuously active during periods of 60–90 days between January and August of 2020. Overall, sampling effort accounted for 2883 trap nights, with an average of 84.8 days of activity per camera. The geographical coordinates of each camera-trap were recorded using a handheld GPS unit Garmin GPSMAP 64s. We organized and identified images using the open-access software Wild.ID (Fegraus et al. Reference Fegraus, Lin, Ahumada, Baru, Chandra and Youn2011), and then used the camtrapR package of the statistical software R (Niedballa et al. Reference Niedballa, Sollmann, Courtiol and Wilting2016; R Core Team 2022) to obtain independent records (independence interval of 1440 minutes) and presence–absence tables for statistical modeling. The species taxonomy was checked in three websites: (1) Integrated Taxonomic Information System (National Museum of Natural History and Smithsonian Institution 2023), (2) Mammal Diversity Database (Mammal Diversity Database 2024), and (3) Birdlife International (Birdlife International 2024).

Landscape covariates, body mass and carnivory

We estimated two groups of landscape covariates: (1) covariates related with environmental conditions and (2) covariates related to human activity. Environmental variables included forest cover and solar radiation. In order to estimate the percentage of forest cover, we generated a cover map using the Semi-Automatic Classification Plugin in the software QGIS version 3.16 (Congedo Reference Congedo2021; QGIS Development Team 2020) using three categories: forest, grassland, and bare ground. Then we quantified the percentage of forest using circular buffers at four spatial scales (radii of: 100 m, 300 m, 500 m, and 700 m) to choose the spatial scale at which the variable has a greater influence on the large animals’ assemblage occupancy. To achieve this, we conducted individual occupancy models for each spatial scale of the variable and selected the model with the highest estimated value. In order to estimate solar radiation (a measure of environmental astringency), we used the WorldClim 2 dataset (Fick and Hijmans Reference Fick and Hijmans2017) extracting the values for each of the camera trap locations. Human activity variables included in this study were distance to touristic sites and the spatial human footprint. The former was calculated with QGIS version 3.16 (QGIS Development Team 2020), and the locations of the main touristic sites, such as stores and hotels, the latter was estimated using the legacy-adjusted Human Footprint Index for Colombia (Ayram et al. Reference Ayram, Etter, Díaz-Timoté, Buriticá, Ramírez and Corzo2020). This index measures the level of human intervention on a scale of 0–100 based on information about land use type, rural population density, distance to roads, distance to settlements, the fragmentation index of natural vegetation, the biomass index relative to natural potential, and time of ecosystem intervention in years.

We used two species traits: average body mass and average percentage of carnivory of each species (S1). Both variables were extracted from the EltonTraits 1.0 dataset, a global species-level compilation of birds and mammals attributes (Wilman et al. Reference Wilman, Belmaker, Simpson, de la Rosa, Rivadeneira and Jetz2014). For body mass, we extracted the value registered in the EltonTraits 1.0 dataset for each species, and the percentage of carnivory was calculated by adding the percentage of consumption of items representing a carnivorous diet (endotherm vertebrates such as mammals and birds and ectotherm vertebrates such as reptiles and amphibians, fishes, and carrion) in the EltonTraits 1.0 dataset.

Occupancy modeling

To evaluate the response of the species recorded at Tatacoa Desert to environment and human activity while accounting for imperfect detection, we performed a hierarchical Bayesian multispecies occupancy model (Dorazio and Royle Reference Dorazio and Royle2005; MacKenzie et al. Reference MacKenzie, Nichols, Lachman, Droege, Andrew Royle and Langtimm2002). This kind of model groups two components: (1) a state process, which is related to the ecological dynamic under study and (2) an observation process, related to the sampling method. In this model, the occurrence (z) of a species i at a site j was defined as a Bernoulli process, z _i,j ∼ Bern(ψ _ij ), where ψ _ij is the probability of occurrence of a species i at a camera site j. Then, to incorporate the imperfect detection, detection probability was calculated from temporally replicated data, in our study, we grouped seven consecutive camera-trap nights into one sampling occasion (to avoid zero inflation), resulting in camera-trap sites oscillating between 8 and 17 sampling occasions, known as the detection histories. From this temporal replicate, we estimated the probability of capturing a species i at camera station j on sampling occasion k. Thus, we defined a second Bernoulli process for detection as x _i,j,k ∼ Bern(p _i,j,k × z _i,j ), where x _i,j,k is the group of detection histories, and p _i,j,k represent the detection probability of species i at a site j on a temporal replicate k, that being conditional to species presence (z _i,j = 1) (Boron et al. Reference Boron, Deere, Xofis, Link, Quiñones-Guerrero, Payan and Tzanopoulos2019; Rich et al. Reference Rich, Miller, Robinson, McNutt and Kelly2016).

We included (on a logit scale) the effect of environmental and anthropogenic covariates to the occurrence and detection probabilities. The occurrence was modeled as a function of the percentage of forest on a 300 m radii around each camera-trap site (the spatial scale that showed the greater influence on assemblage occupancy), the solar radiation, the distance to tourist sites, and the human footprint. The detection was modeled as a function of the solar radiation, and the percentage of forest on a 100 m radii around each camera-trap site under the assumption that the amount of forest around each camera influences the probability of detection on a smaller scale. The model includes the estimation of a hyperparameter for the assemblage response to covariates and species-specific responses; therefore, it is possible to compare the responses to covariates at the assemblage level against the species-specific response variations. The models for occurrence and detection are expressed as

$$\begin{gathered} {\text{logit}}\left( {{\psi _{ij}}} \right) = \;{\mu _{\left( i \right)\;}} + \;{\alpha _{1i}}\;\% {\text{Forest}}\;{\text{Cove}}{{\text{r}}_j} + \;{\alpha _{2i}}\;{\text{Distance}}\;{\text{Touris}}{{\text{t}}_j} \\ \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\, + \;{\alpha _{3i}}\;{\text{Solar}}\;{\text{Radiatio}}{{\text{n}}_j} + \;{\alpha _{4i}}\;{\text{Human}}\;{\text{Footprin}}{{\text{t}}_{j\;}} \\ \end{gathered}$$

$${\rm{logit}}\left( {{p_{i,j,k}}} \right) = \;{\upsilon _{\left( i \right)}} + \;{\beta _{1i}}\;\% {\rm{Forest\;Cove}}{{\rm{r}}_j} + \;{\beta _{2i}}\;{\rm{Solar\;Radiatio}}{{\rm{n}}_j}\;$$

Finally, we estimated parameter posterior distributions through Markov Chain Monte Carlo simulations (MCMC) implemented in JAGS (version 4.3.1) using the R packages rjags (Finley Reference Finley2013) and jagsUI (Kellner et al. Reference Kellner, Meredith and Kellner2019). We obtained the posterior distributions of the model parameters with three chains of 500000 iterations and a burn-in sample of 200000. We thinned the chains by retaining every 100 sampled values (Drouilly et al. Reference Drouilly, Clark and O’Riain2018). We used the Gelman-Rubin criteria to assess the model convergence, where values less than 1.1 indicate model convergence (Gelman et al. Reference Gelman, Carlin, Stern, Dunson, Vehtari and Rubin2013).

Relationship between occupancy estimates and species traits

To evaluate if species traits might influence the magnitude of the species responses to the environmental and anthropogenic covariates, we implemented general linear models (GLMs). We used as predictors two traits: the body mass (on a logarithmic scale) and the percentage of carnivory of each species as a proxy of the diet. As response variables, we extracted the mean values of the species responses (estimates) to the covariates in the occupancy model. This analysis was performed in the statistical software R (version 4.2.0) (R Core Team 2022).