Abstract
Density is crucial for understanding large carnivore ecology and conservation, but estimating it has proven methodologically difficult. We conducted 1 year of camera trapping to estimate jaguar (Panthera onca) density and population structure in the Los Llanos region of Venezuela on the Hato Piñero ranch, where hunting is prohibited and livestock are excluded from half of ranch lands. We identified 42 different jaguars and determined their sex, age class, and reproductive status. We estimated adult jaguar densities with spatial capture-recapture models, using sex/reproductive state and session as covariates. Models without temporal variation received more support than models that allowed variation between sessions. Males, reproductive females, and nonreproductive females differed in their density, baseline detectability, and movement. The best estimate of total adult jaguar population density was 4.44 individuals/100 km2. Based on reproductive female density and mean number of offspring per female, we estimated cub density at 3.23 individuals/100 km2 and an overall density of 7.67 jaguars/100 km2. Estimated jaguar population structure was 21% males, 11% nonreproductive females, 26% reproductive females, and 42% cubs. We conclude that extending the sampling period to 1 year increases the detectability of females and cubs and makes density estimates more robust as compared to the more common short studies. Our results demonstrate that the Venezuelan Llanos represent important jaguar habitat, and further, they emphasize the importance of protected areas and hunting restrictions for carnivore conservation.
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Introduction
Population density is central to understanding the ecology, spatial distribution, and abundance of all organisms (Krebs 2001), yet estimating density reliably remains a challenging problem in applied ecology. This issue remains especially persistent for ecologically important large carnivores. Carnivore population density is one of the major components that determines the impacts of predation on prey populations (Holling 1959; Messier 1994; Jędrzejewska and Jędrzejewski 1998). Accurate density estimates are also critical to evaluate population size and trends of large carnivores, an increasingly important aim given worldwide declines of many of these species (Gros et al. 1996; Treves and Karanth 2003; Ripple et al. 2014).
For large carnivores, like other threatened and endangered species, the knowledge of population structure and demography can help predict population trends and long-term persistence (Shaffer 1981; Coulson et al. 2001; Cooley et al. 2009). Demographic parameters may depend upon species biology but also reflect the breeding performance of a population. A high proportion of breeding females and cubs suggests a high reproduction rate and potentially a growing population. Conversely, carnivore populations with few breeding individuals may have a higher extinction risk. Thus, integrating methods to estimate large carnivore population breeding structure with density could improve population trend predictions and promote effective conservation (Woodroffe 2011; Rosenblatt et al. 2014).
As the top predator in the Neotropics, the jaguar (Panthera onca) may have large impacts on prey populations, and an important role in trophic cascades and ecosystem regulation (Terborgh et al. 2001; Cavalcanti and Gese 2010; Estes et al. 2011). Like many large carnivores, the jaguar has experienced a rapid contraction of its natural range due to anthropogenic influences, especially habitat alteration and fragmentation (Quigley and Crawshaw 1992; Nowell and Jackson 1996; Sanderson et al. 2002a; Zeller 2007). Moreover, the reported densities of the jaguar vary substantially across its present distribution, but the factors that shape this variation are poorly understood (see Maffei et al. 2011 and Tobler and Powell 2013 for review).
A variety of field and statistical methods have been used to estimate large carnivore population densities (e.g., Gros et al. 1996; Karanth and Nichols 1998; Stander 1998; Wilson and Delahay 2001). Initial attempts at estimating jaguar density were based on radio-tracking (Schaller and Crawshaw 1980; Crawshaw 1995; Ceballos et al. 2002). In the last decade, camera trapping combined with capture-recapture statistical methods has become common (Maffei et al. 2011). The recent development of spatially explicit capture-recapture (SCR) methods has further improved the quality of density estimates (Borchers and Efford 2008; Noss et al. 2012; Royle et al. 2014). However, application of these methods may still present unresolved issues, such as the large differences among estimates from consecutive seasons within the same study area (e.g., de la Torre and Medellin 2011; Foster and Harmsen 2012; Tobler et al. 2013). This variation among estimates may result not only from study areas of insufficient size but also from low detectability, especially of females and juveniles. The low number of detections may be partially attributable to short study periods (1–3 months), which are commonly used to address the assumption of population closure in capture-recapture models (Karanth and Nichols 1998; Silver et al. 2004; Maffei et al. 2011). In theory, prolonged study periods may allow for immigration, emigration, births, and deaths in the study area and lead to overestimates or underestimates of abundance by the closed population models applied in SCR packages (White et al. 1982; Kendall et al. 1997; Efford and Fewster 2013; Royle et al. 2014). However, extending study duration may bring important benefits, such as an increased number of detections. For example, better detectability of all sex/age groups would allow estimating population breeding structure and would broaden the applicability of camera trapping to an array of other ecological and conservation questions (du Preez et al. 2014). While the open population models are still less established and have been rarely applied to density estimates (e.g., Gardner et al. 2010; Whittington and Sawaya 2015), it would be practical to find solutions for applying the commonly used SCR methods based on closed population models to long-term camera trapping data.
Here, we study a jaguar population in Los Llanos, a region of vast plains interspersed with numerous rivers, marshes, open grasslands, and forests, extending through large parts of Venezuela and Colombia. This unique region constitutes an important habitat for jaguar in northern South America (Hoogesteijn and Mondolfi 1992; Sanderson et al. 2002b; Rabinowitz and Zeller 2010); however, human-jaguar conflicts related to frequent jaguar attacks on cattle threaten populations of this carnivore in the area (Hoogesteijn et al. 1993). Conservation measures implemented on cattle ranches can improve the prospects of jaguar persistence in this region (Hoogesteijn and Chapman 1997).
In this work, we assessed the impact of study design on the estimates of jaguar density and population structure in the partially protected Hato Piñero ranch in the Venezuelan Los Llanos. First, we examined the impact of sampling period on population density estimates with SCR methods. To fulfill the assumptions of the closed population model, we divided our long study to shorter sessions and used these sessions as a covariate in our SCR models. We tested whether increased study duration leads to increased detectability, especially of females and cubs, and if it improves robustness of the density estimates. We further estimated basic reproductive parameters and structure of the jaguar population to assess the status of this species in our study area and the efficacy of the protection measures applied in Hato Piñero. Based upon our findings, we made recommendations for conservation and future studies of jaguars and other large carnivores.
Methods
Study area
Hato Piñero ranch encompasses a total area of 800 km2 in the south-eastern part of Cojedes state of Venezuela. It includes the hills of Macizo de El Baúl and vast plains between the rivers Cojedes, Portuguesa, Chirgua, and Pao. We conducted the study in the north-central portion of Hato Piñero, between 68.0334° W, 8.9827° N and 68.2148° W, 8.8562° N (Fig. A1). The landscape is dominated by a mosaic of open lowland savanna, partially converted to pastures, open marshes, deciduous and dry forests, and chaparral on the hillsides (Huber et al. 2006). Precipitation drives the seasonal climate with most rain occurring between June and November. Average annual rainfall is approximately 1400 mm (Polisar et al. 2003); however, there is profound variation between years (data of the meteorological station of El Baúl). The main rivers are located on the borders of the ranch, but a network of small streams, channels, and artificial ponds and lakes is well developed inside these borders. Between July and October, large parts of the ranch are normally flooded, and in the driest period—between February and May—only the largest rivers and a small number of artificial ponds retain water.
Until 2009, Hato Piñero was a private cattle ranch with approximately 50% of its area maintained as a nature reserve that strived to preserve the jaguar and its prey communities. Hunting was prohibited within ranch boundaries. In 2010, the Venezuelan government expropriated Hato Piñero as a state farm but retained the conservation protections of the ranch. However, after expropriation, the number of cattle increased from about 11,000 in 2009 to approximately 13,000 in 2014. In recent years, the number of domestic buffalo has also increased, reaching approximately 2000 in 2014. In addition to livestock, common prey species include peccaries (Pecari tajacu and Tayassu pecari), capybaras (Hydrochoerus hydrochaeris), white-tailed deer (Odocoileus virginianus), tapir (Tapirus terrestris), caimans (Crocodilus crocodilus), and giant anteater (Myrmecophaga tridactyla) (Polisar et al. 2003; Scognamillo et al. 2003; Jędrzejewski et al. 2014). Sympatric carnivores include puma (Puma concolor), ocelot (Leopardus pardalis), jaguarundi (Puma yagouaroundi), and crab-eating fox (Cerdocyon thous).
Camera trapping
From July 2013 to July 2014 (376 days), we conducted a continuous camera trapping effort in the study area (Table 1, Fig. A1). We used 27–56 camera-traps at any given time, mostly HC 500 (Reconyx Inc., Holmen, WI, USA) and TrophyCam HD Max (Bushnell, Overland Park, MI, USA). We aimed to distribute the cameras in a regular grid of 2 km by 2 km; however, we adjusted camera positions in response to local topography, site accessibility, and the presence of jaguar trails indicated by track records (Fig. A1). Normally, we placed cameras along small dirt roads, animal trails, and water-bodies, one camera per site. The total area of the polygon encompassing all camera stations was 168.1 km2. To improve the quality of imagery for individual identification, we placed a small piece of carpet (10 cm × 10 cm) soaked with a beaver castoreum/catnip oil lure in front of the cameras (usually at a distance of 3–4 m) (Schmidt and Kowalczyk 2006; Schlexer 2008). Placing lures does not bias density estimates but may improve individual identifications or detectability (Gerber et al. 2012; du Preez et al. 2014).
We divided our sampling period into six sessions that corresponded with camera maintenance and data download. Mean session duration was 63 days (range 47–99 days, Table 1). During each site visit, we inspected the cameras to adjust camera settings and, if required, the spatial location of cameras due to landscape changes (i.e., flooding, droughts, fires, etc.), observation of jaguar tracks, or technical problems. We also refreshed the lure when servicing each camera.
We identified individual jaguars based on unique spot patterns (Silver et al. 2004). We distinguished four sex/age groups: males, nonreproductive females, reproductive females, and cubs. Cubs included obviously young and immature individuals recorded with adult females. Sex of adult individuals was determined by the presence/absence of testicles or nipples and other reproductive signs. We classified females as reproductive if they were recorded with cubs at any point during the study year, and as nonreproductive, if they were never recorded with cubs. We treated presence of cubs as an objective criterion for evidence of breeding. Classification of breeding or non was held constant for the entire study period. Although simplified, we believe this classification justified by the long reproductive cycle of female jaguars (i.e., 3 months gestation and 17 months care of cubs) and long (3–4 years) time to first reproduction (Crawshaw and Quigley 1991; De Paula et al. 2013). We make the assumption that reproductive females maintain their territories for long periods (i.e., years) and any short-term event (i.e., losing cubs) would not change their territory size. Furthermore, we generally recorded older cubs (>3 months old), which would have survived the presumed very early peak in juvenile mortality documented in other large carnivores (Jędrzejewska et al. 1996; Palomares et al. 2005). The identification process was performed by two authors independently (MFP and MA) and verified by a third (WJ). Unidentifiable captures were excluded from subsequent analyses. For capture-recapture models, we defined daily sampling occasions such that we considered only one capture per day per trap, i.e., binomial detection histories (Royle et al. 2009; Goldberg et al. 2015).
Population density estimation for adult jaguars
We applied maximum likelihood SCR models within the secr 2.10.3 R package (Efford et al. 2004, 2009; Borchers and Efford 2008; Efford 2016) to estimate jaguar densities. These hierarchical models define (1) a spatial model of the distribution of animal activity centers and (2) a spatial observation model relating the probability of detecting an individual at a particular trap to the distance from the animal’s activity center (Efford 2004). For the observation model, we used a hazard half-normal detection function:
where λ 0 represents the baseline detection probability at an individual’s activity center, σ defines the shape of the decline in detection away from the activity center and can be interpreted in terms of the animal movement distribution, and d specifies the distance between a detector (camera trap) and the activity center (Efford et al. 2009; Efford 2016). This detection model implies a Binomial distribution of detections of an individual at a particular detector (Efford and Fewster 2013; Royle et al. 2014). We used a 15-km buffer around the study area to include the activity centers of any individuals that may have been exposed to sampling. We checked the adequacy of the buffer size by examining likelihoods and estimates from models with larger buffers. We applied full likelihood models with three sex/reproductive status groups (adult males, adult reproductive females, and adult nonreproductive females) and six shorter sessions as covariates (Borchers and Efford 2008). By doing this, we also fulfilled the assumptions of the closed population model in analyzing our long dataset. We fit models with all possible additive combinations of sex/reproductive status groups and sessions as covariates on density (D), λ 0 , and σ. For density, we always used sex/female reproductive state as a covariate to provide an estimate of population structure and did not consider intercept-only models. We assessed how D, λ 0 , and σ differed across sessions and sex/reproductive status groups and how this variation influenced the overall density estimate. We evaluated models with AICc (corrected Akaike information criterion) and AICc weights (Hurvich and Tsai 1989; Wagenmakers and Farrell 2004). To test the effect of study duration on estimates of all parameters, we compared models that included session covariates in the parameters D, λ 0 , and σ (corresponding to the situation when model parameters were estimated based on separate sessions, as in short-term studies) with the best model that did not include any session covariates.
The spatial scale parameter, σ, implies an estimate of individual space use and the scale of movement about an activity center. These estimates provide another means of addressing the reliability of our model results through comparison to telemetry-derived home range sizes. We transformed the σ values for each sex/reproductive state into the radius of an individual activity range, encompassing 95% of animal locations during the observation period. We made this conversion using the hra function in the R package SCRbook (Royle et al. 2013; https://sites.google.com/site/spatialcapturerecapture/scrbook-r-package), since an analytical solution with the hazard half-normal detection function is not readily available. The hra function approximates the 95% activity range of an individual, given parameter values, using a discrete meshwork of points about the activity center. We calculated 95% activity range size for our best model and compared them to home range size estimates from radio-tracking.
To allow comparisons with earlier studies, we also applied nonspatial capture-recapture methods to estimate adult jaguar density (see Appendix B for methods and results).
Estimating cub density and population structure
We estimated densities separately for males, reproductive females, and nonreproductive females. We attempted to fit models directly to observations of cubs, but their sparse capture histories did not provide sufficient data for a maximum likelihood analysis. To estimate cub density, we multiplied the reproductive female density from our best model by mean number of cubs per reproductive female. These estimates allowed calculation of total jaguar density and population structure for males, nonreproductive females, reproductive females, and cubs.
Results
Camera trapping and detection numbers for sex/age groups
Our total sampling effort was 12,302 camera trap-nights. We obtained 1465 captures, including 1369 with identifiable individuals (Table 1). In total, we identified 42 jaguars, including 14 adult males, 14 adult females, and 14 cubs. Of the 14 photographed adult females, 7 were actively reproducing and photographed with cubs (Photos D1, D2). Although we registered equal numbers of males, females, and cubs in the study area, the capture frequency of each group differed: 58% of identified photos were those of males (798 captures), 33% of identifiable captures were those of females (452), and only 9% were those of cubs (119). On average, males were captured 56 times each, females 32 times, and cubs only 9 times. Reproductive females had slightly higher total number of captures than nonreproductive females (257 versus 195, respectively) and higher average number of captures per individual (38 versus 28). Reproductive females were more frequently captured alone (109 times) than accompanied by cubs (69 captures) during the period of known offspring dependency. Conversely, cubs were recorded more frequently with their mothers (83 individual captures) than alone (36 captures).
Density estimates of adult jaguars
Of the 32 models analyzed with the secr package with sex/reproductive status and sessions as covariates, those which did not allow density to vary across sessions obtained the lowest AICc values. In contrast, models assuming density variation across sessions received less support (Tables 2, C1). The top secr model for adult jaguars included an effect of sex/female reproductive status on D, λ 0, and σ and between session variation in λ 0. All three parameters differed significantly between sex/reproductive status groups (Table 3). Baseline detection probability was lowest for reproductive females (0.04 on average), whereas nonreproductive females had the greatest baseline detectability (0.13 on average) and males intermediate (0.08 on average) to the two female reproductive classes. Males had the largest values of estimated movement distribution (σ = 2.97 ± 0.09 km), while reproductive and nonreproductive females obtained smaller σ values (2.04 ± 0.11 and 2.32 ± 0.19 km, respectively). Estimated densities were higher for reproductive females and males (1.97 ± 0.33 and 1.62 ± 0.22 individuals/ 100 km2, respectively) than for nonreproductive females (0.85 ± 0.19 individuals/100 km2). In total, the best model estimated 4.44 ± 1.16 adult jaguars/100 km2 (Table 3).
Cub density and jaguar population structure
From observations of the seven reproductive females with offspring during the study period, we estimated 1.64 cubs per reproductive female on average. Additionally, one cub was recorded alone on a single occasion and had an unknown mother. We excluded this lone observation from further analysis. On the basis of reproductive female density from the top model, we estimated 3.23 cubs/100 km2 in the study area. Thus, we estimated a total density of 7.67 jaguars/100 km2. Jaguar population structure was 21% adult males, 11% nonreproductive females, 26% reproductive females, and 42% cubs (Table 3).
Estimates of home range sizes
Based on the detection and movement parameter values, we estimated 95% home range sizes. Males had the largest ranges (167 km2), while nonreproductive females and reproductive females moved in smaller ranges (103 and 79 km2, respectively, Table 3).
Study duration and density estimates
The best secr model included seasonal variation in the baseline detection probability, but not in density or the movement distribution parameter. The top model that excluded seasonal variation in all parameters had the second overall rank order in our model set (∆AICc = 2.8, w i = 0.17, Table 2) and produced similar overall density estimates (D total = 4.47 ± 1.06 jaguars/100 km2). In contrast, the model assuming between session variation in all three parameters gave highly variable results: from 3.65 to 5.62 jaguars/100 km2 in different sessions (Fig. 1, Table C2). This model received no support from our model selection criterion (∆AICc = 17.2).
Discussion
Our study provides a robust estimate of jaguar density from a large, long-term photographic capture-recapture dataset. This scope allowed us to address the concerns of many previous jaguar studies, including small sample sizes, low detectability of females and cubs, and limited spatial and temporal extent to provide a more complete description of the jaguar population in our study area. We estimate breeding and nonbreeding female density as well as cub density and total population structure for jaguars in Hato Piñero. We record high jaguar densities in the Venezuelan Llanos, providing evidence of the importance of this habitat for conservation. Moreover, our approach to spatial and temporal study design may offer useful guidance for future capture-recapture studies of jaguars and other large carnivores.
Jaguar population density in Hato Piñero and implications for conservation
Our estimates of jaguar density in Hato Piñero of 4.4 adults/100 km2 and 7.6 total jaguars/100 km2 (including cubs) are among the highest documented in South and Central America. Comparable density estimates have been reported only in the tropical forests of Peru, Belize, and Guatemala (Moreira et al. 2008; Harmsen et al. 2010; Tobler et al. 2013; Kelly and Rowe 2014) and in the wetlands of the Brazilian Pantanal (Soisalo and Cavalcanti 2006). This high jaguar density most likely results from high prey availability and productivity in our study area. Karanth et al. (2004) demonstrated a similar relationship for tigers in India. Polisar et al. (2003) estimated that the biomass of potential jaguar prey in Hato Piñero was about 750 kg/km2 of wild prey and about 7700 kg/km2 of livestock. These estimates place Hato Piñero in a class of biomass availability and productivity with Manu National Park, Peru (270 kg/km2 of wild prey), and the Pantanal, Brazil (380 kg/km2), two famous jaguar hotspots (Schaller 1983; Emmons 1987).
The wet parts of Los Llanos, with mosaics of seasonally flooded savannahs, marshes, dry or wet forests, and numerous rivers and streams, may provide exceptionally good conditions for jaguars. However, cattle breeding, human-jaguar conflicts, and hunting likely limit jaguar population growth outside the few protected areas in Los Llanos (Hoogesteijn et al. 1993; González Fernández 1995; Hoogesteijn and Hoogesteijn 2008). Boron et al. (2016) conducted camera-trapping study in an unprotected part of the Colombian Los Llanos and documented much lower adult jaguar density (2.2 jaguars/100 km2) than in Hato Piñero, despite the similarities in primary productivity, forest cover, and human population density between the two study areas. However, in the Colombian study site, hunting of jaguars and its prey is common, as well as retaliatory killing of jaguars due to their attacks on cattle (Boron et al. 2016). This contrast strongly supports the efficacy of the jaguar conservation measures adopted in Hato Piñero, including prohibition of hunting, 50% land excluded from cattle grazing, and development of eco-tourism. Similar protections have benefitted jaguar conservation in the Pantanal of Brazil (Zimmermann et al. 2005b; Greve 2014; Hoogesteijn et al. 2016).
Protected areas and other refuges play a crucial role for maintaining other large carnivore populations in landscapes with large human impacts (Mills 1991; Thapar 1999; Naughton-Treves et al. 2005; Carroll and Miquelle 2006). Our data confirm the importance of protected areas for jaguar conservation. We show that large protected areas, like Hato Piñero, can maintain robust jaguar populations at high density and high reproductive output. As such, they may be a source of dispersing individuals, supporting the persistence of jaguar populations in the surrounding areas.
Differences between sex/reproductive groups
Consistent with previous studies accounting for sex differences, we found higher detection and movement parameter estimates for males than females (Sollmann et al. 2011; Tobler et al. 2013). Our decision to discriminate between reproductive and nonreproductive females further refined the differences among females, based upon whether we observed them caring for cubs. The low detection probability of reproductive females may result from protective maternal behavior. Females with cubs may select the safest areas and reduce use of exposed movement corridors, such as roads and trails, to avoid male jaguars and pumas that may threaten young. Infanticide by unrelated males is common in other felids (e.g., Packer and Pusey 1983; Balme et al. 2013). The higher detectability, larger movement ranges, and lower density of nonreproducing females may result from young individuals using transient territories and moving large distances in search of a territory (Beier 1995; Schmidt 1998; Zimmermann et al. 2005a).
Length of study duration
The capture-recapture literature frequently emphasizes the importance of the closed population (no birth, immigration, death, or emigration) assumption of capture-recapture models (White et al. 1982; Kendall et al. 1997). To address this concern, most researchers have adopted the recommendation that study periods should not exceed 3 months (Karanth and Nichols 1998; Silver et al. 2004). Although the closed population assumption is important, meeting this requirement does not require such stringent limits on study period. In the analysis of our long-term data, we introduced sessions as a covariate to act as a surrogate for the shorter time frames typically employed by camera trapping studies. The best model allowed for seasonal variation in one of the parameters (baseline detection probability), but not in the other two (density and movement distribution). Furthermore, the model that ignored seasonal variation provided similar parameter estimates and received some statistical support. In contrast, the model assuming variation between sessions in all parameters (corresponding to short-term studies) received no statistical support and produced much less precise density estimates.
Seasonal fluctuations in activity and density estimates have been shown in other jaguar studies (de la Torre and Medellin 2011; Harmsen et al. 2011; Kelly and Rowe 2014; Tobler et al. 2013). This variation may be attributable to poor camera site selection, camera failures, stolen cameras, local fires, or due to seasonal changes in jaguar spatial activity patterns. Changes in jaguar distribution may depend upon the availability of water sources. During the dry season, only a few artificial ponds, lakes, and streams persisted in our study area. Alternatively, the spatial distribution of jaguars may depend upon jaguar reproductive cycles. Scognamillo et al. (2002) reported that the two jaguar females they radio-tracked in Hato Piñero drastically reduced their activity ranges for about 2 months after giving birth to cubs. Comparable patterns of seasonal activity changes related to reproductive cycles have been demonstrated for other felids, e.g., for lynx in Białowieża Primeval Forest (Schmidt 1998). Thus, seasonal changes in activity patterns and territory use may have some impact on detection probability and population assessments, as shown by our results. Density estimates from data with a limited temporal extent may have a greater stochastic component and be less precise than those obtained in long-term studies.
The increased sampling duration in our study did not lead to any obvious overestimates of population density and produced several key benefits. Most importantly, the long-term monitoring increased detection numbers and led to better parameter estimates for the most elusive groups within the jaguar population. We could estimate densities separately for each sex, age, and reproductive group to provide a more complete description of jaguar population structure. Our estimate of population structure with reproductive females and cubs comprising 26 and 42%, respectively, of all individuals indicates a healthy, productive jaguar population. Similar high share of reproducing females and cubs has been observed in radio-tracking studies of other large felid populations, e.g., lynx in partially protected Białowieża Forest in Poland (Jędrzejewski et al. 1996).
In sum, the advantages of long-term studies suggest that extended camera trap monitoring in combination with spatial capture-recapture models may offer significant insights into the population biology of target species.
Home range size estimates
Our estimates of year-round home range sizes (79 km2 for reproducing females, 103 km2 for nonreproducing females, and 167 km2 for males) show, in general, a similar pattern to estimates obtained with telemetry studies and further corroborate our density estimates. Previous radio-telemetry research, conducted on two male and two female jaguars in Hato Piñero during 1996–1998, estimated average seasonal home range sizes of 65 km2 for females and 100 km2 for males (Polisar et al. 2003; Scognamillo et al. 2002, 2003). In a GPS telemetry study of jaguars conducted by Cavalcanti and Gese (2009) in Pantanal, Brazil, a habitat similar to Hato Piñero, seasonal female home ranges varied from 34 to 101 km2 (average: 63 km2) and seasonal male home ranges varied from 58 to 263 km2 (average: 156 km2). Slightly higher average estimates obtained with SCR methods may result from the fact that this technique assumes circular home ranges, while telemetry captures actual space use, which is rarely circular (e.g., Cavalcanti and Gese 2009). However, the higher estimates of home range sizes of nonreproductive females can result from their transient character which can cause a bias in movement estimates (Royle et al. 2016).
Conclusions
Our study demonstrates that protected areas in Los Llanos are potentially important jaguar habitat and that jaguar populations in this region may reach some of the highest densities recorded for South America. Jaguar conservation plans and actions should pay more attention to this region and promote increasing the number of protected areas in Los Llanos. Although today, Hato Piñero is an unquestionable jaguar hotspot in northern South America, it needs more international concern to maintain its good state of conservation, especially in the context of the political instability, growing environmental risks, and uncertain future of this region.
Our study also suggests new perspectives on future research. Spatial capture-recapture studies of jaguars and similar species, with camera traps, may benefit from extended monitoring not limited to 3 months. Based upon our experience, we recommend large study areas with dense trap stations to maximize the number of individuals captured and number of detections. Although we did not quantify the effect of lures, we found them to increase picture quality and thus detectability. Long-term camera trapping can provide additional insights into carnivore population biology.
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Acknowledgements
Collecting data for this article was possible due to financial support from the budgets of Instituto Venezolano de Investigaciones Científicas (IVIC) and Mammal Research Institute of the Polish Academy of Sciences and grants from Polish Ministry of Science and Higher Education (grant NN304336339) and Panthera Corporation (2010 Research and Conservation Grant and the Liz Claiborne Art Ortenberg Jaguar Research Grants 2011, 2012, 2014). We are grateful to all the personnel of Hato Piñero who made our work possible. We are grateful to the IVIC Transportation Center, and especially to Argenis Hurtado and all IVIC drivers who participated in our expeditions to Hato Piñero, also to Dinora Sánchez and Giovanni Colmenares from Biodiven IVIC for making their car available for us. Special thanks we direct to coordinators of Ecology Center of IVIC: Dr. Marta Francisco, Dr. Astolfo Mata, Dr. Ascanio Rincón, and administration workers Yugdalia García, Robert Vargas, and all staff of the Ecology Center for their kind support to our work. Dr. Fernando Ruette and Miguel Fernández (IVIC) shared their computers to assist with the analysis.
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Jaguar density estimate with non-spatial capture-recapture methods (DOCX 29 kb)
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Photos D1, D2 (DOCX 1407 kb)
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Jędrzejewski, W., Puerto, M.F., Goldberg, J.F. et al. Density and population structure of the jaguar (Panthera onca) in a protected area of Los Llanos, Venezuela, from 1 year of camera trap monitoring. Mamm Res 62, 9–19 (2017). https://doi.org/10.1007/s13364-016-0300-2
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DOI: https://doi.org/10.1007/s13364-016-0300-2