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The peri-urban leopards of Kathmandu: assessing determinants of presence and predation on domestic animals

Published online by Cambridge University Press:  04 May 2021

Ashish Bista*
Affiliation:
World Wide Fund for Nature, 172-B Lodhi Estate, New Delhi, 110003, India
Pranav Chanchani
Affiliation:
World Wide Fund for Nature, 172-B Lodhi Estate, New Delhi, 110003, India
Naresh Subedi
Affiliation:
National Trust for Nature Conservation, Khumaltar, Lalitpur, Nepal
Siddhartha B. Bajracharya
Affiliation:
National Trust for Nature Conservation, Khumaltar, Lalitpur, Nepal
*
(Corresponding author) E-mail [email protected]

Abstract

The conservation of large carnivores in human-dominated landscapes needs to be reconciled with the safety of humans and domestic animals. This is especially true for the leopard Panthera pardus, which occurs extensively in agricultural landscapes and remnant forest tracts embedded within peri-urban areas such as Kathmandu district in Nepal. We carried out interviews in 321 households in this district to determine the extent of leopard habitat use and predation on domestic animals (dogs and goats) during October 2015–April 2016. We used multi-state occupancy models, and estimated probabilities of leopard habitat use (Ψ1) and predation on domestic animals (Ψ2) as a function of covariates, while accounting for imperfect detection. Our findings indicate that the rapidly urbanizing outskirts of Kathmandu city are used extensively by leopards. The estimated probability of fine-scale habitat use in 2 km2 sample units was 0.96 ± SE 0.05 and the probability of predation on domestic animals was 0.76 ± SE 0.15. Leopard attacks occurred in areas with high vegetation cover and abundant goats. Addressing the problem of leopard attacks on domestic animals will require developing a comprehensive mitigation plan that includes educational activities to raise awareness, measures to address grievances of affected local communities, interventions to prevent attacks on livestock, compensation programmes, and rapid response teams to ensure human and animal welfare in conflict-prone areas. Land-use planning in these peri-urban landscapes needs to facilitate the safe sharing of space between people and leopards.

Type
Article
Creative Commons
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of Fauna & Flora International

Introduction

Humans and large carnivores co-occur extensively where urban areas expand into or surround wildlife habitats (Zérah, Reference Zérah2007). Although large mammals do not always persist in areas with high anthropogenic pressure (Woodroffe, Reference Woodroffe2000; Ripple et al., Reference Ripple, Wofl, Newsome, Galetti, Alamgir and Crist2017), they sometimes adapt to human-modified habitats including the edges of populous towns and farmlands, often sheltering, feeding and breeding in such areas (Gehrt, Reference Gehrt2007; Beckmann & Lackey, Reference Beckmann and Lackey2008; Bateman & Fleming, Reference Bateman and Fleming2012; Athreya et al., Reference Athreya, Odden, Linnell, Krishnaswamy and Karanth2014; Odden et al., Reference Odden, Athreya, Rattan and Linnell2014). The conservation of large carnivores presents a conundrum for wildlife managers and local administrators who are tasked with protecting wildlife and ensuring the safety of local communities (Allendorf, Reference Allendorf2010). This task is especially challenging when carnivores occur on privately owned land (Enserink & Vogel, Reference Enserink and Vogel2006), where there is an elevated risk of negative interactions with people (Nyhus & Tilson, Reference Nyhus and Tilson2004).

The leopard Panthera pardus commonly occurs in close proximity to human settlements (Odden & Wegge, Reference Odden and Wegge2005; Odden et al., Reference Odden, Athreya, Rattan and Linnell2014). There are many drivers for leopard occurrence in human-dominated landscapes, including habitat fragmentation, wild prey depletion, attraction to domestic animals as easy prey and competitive displacement as a result of inter- or intra-species interactions (Seidensticker, Reference Seidensticker1976; Odden et al., Reference Odden, Wegge and Fredriksen2010; Ripple et al., Reference Ripple, Estes, Beschta, Wilmers, Ritchie and Hebblewhite2014). Several studies show that home ranges of leopards sometimes overlap partially or completely with human-use areas (e.g. Odden et al., Reference Odden, Wegge and Fredriksen2010, Reference Odden, Athreya, Rattan and Linnell2014), which is facilitated by the species’ dietary plasticity. Leopards readily adapt to prey on domestic animals, particularly dogs, which may comprise as much as 70% of their diet (Karanth & Sunquist, Reference Karanth and Sunquist2000; Edgaonkar & Chellam, Reference Edgaonkar and Chellam2002; Dickman & Marker, Reference Dickman and Marker2005; Athreya et al., Reference Athreya, Odden, Linnell, Krishnaswamy and Karanth2014; Kumbhojkar et al., Reference Kumbhojkar, Yosef, Kosicki, Kwiatkowska and Tryjanowski2020).

Predation of domestic animals by leopards is common across many Asian and African range countries (Kissui, Reference Kissui2008; Dar et al., Reference Dar, Minhas, Zaman and Linkie2009; Khorozyan et al., Reference Khorozyan, Soffi, Soufi, Hamidi, Ghoddousi and Waltert2017; Kshettry et al., Reference Kshettry, Vaidyanathan and Athreya2017). Such predation, especially on livestock, causes economic losses (Dar et al., Reference Dar, Minhas, Zaman and Linkie2009), can affect the livelihoods and social well-being of people (Barua et al., Reference Barua, Bhagwat and Jadhav2013; Kshettry et al., Reference Kshettry, Vaidyanathan and Athreya2018), engenders negative attitudes of people towards carnivores (Megaze et al., Reference Megaze, Balakrishnan and Belay2017) and may catalyse retaliatory killing by poisoning or other means (Ogada et al., Reference Ogada, Woodroffe, Oguge and Frank2003).

In Nepal, human–leopard conflict is a serious issue (Acharya et al., Reference Acharya, Paudel, Neupane and Köhl2016). Adverse interactions with humans are more likely when leopards occur in densely populated peri-urban areas (Soulsbury & White, Reference Soulsbury and White2016), such as Kathmandu district. Inclusive of Kathmandu, the country's capital city, this district has a population of > 1.7 million people, with a population density of 4,416 people/km2 (25 times higher than the national average; CBS, 2014). The city and its suburbs are surrounded by montane forests, most notably the Shivapuri-Nagarjun National Park and National Forest, which supports a leopard population (Pokharel, Reference Pokharel2015). Leopards sometimes enter human settlements, including the fringes of Kathmandu city, and are subsequently captured and translocated to zoos or released back into the wild. Although leopards are routinely captured in the Kathmandu valley, the extent of their occurrence and predation on domestic animals has hitherto not been thoroughly investigated (Pokharel, Reference Pokharel2015).

Here, we assessed the extent and determinants of leopard habitat use and predation on domestic animals in peri-urban areas within Kathmandu district, with the aim of assisting the Government of Nepal in devising strategies to mitigate future human–leopard conflict.

Study area

We conducted this study in 10 of 11 municipalities in Kathmandu district, Nepal (395 km2; Fig. 1). Kathmandu district is one amongst three districts located within the Kathmandu valley, and is home to > 72,000 households (CBS, 2014). The predominant land-use types are forest (42%), farmland (42%) and built-up areas (14%; Wang et al., Reference Wang, Gebru, Lamchin, Kayastha and Lee2020). Along with a rapid increase in the human population, urban areas expanded by 412% in the Kathmandu valley since 1989, with conversion of 31% of farmlands (Ishtiaque et al., Reference Ishtiaque, Shrestha and Chhetri2017). Most communities in Kathmandu district outside the city are agrarian, with rice, wheat, maize, potato and mustard being the main crops.

Fig. 1 Study area showing Kathmandu district, Kathmandu city and survey locations within 90 2-km2 grid cells. The inset map shows the location of the study area within Nepal.

The forested hills around Kathmandu district (Fig. 1) are managed by the administration of Shivapuri-Nagarjun National Park (159 km2) and the Kathmandu District Forest Office as National Forest, Community Forest and others (132 km2). These forests support diverse mammalian and avian communities. The vegetation is sub-tropical/temperate forest dominated by Pinus spp., Quercus spp. and Castanopsis spp. (Shrestha, Reference Shrestha2001). These forests contribute to the provision of drinking water and clean air for the 1.7 million inhabitants of Kathmandu district, and are valuable for religious and cultural reasons (SSNP, 2017).

Methods

Interview surveys

We divided the study area into 2-km2 grid cells (Fig. 1) and carried out interview surveys in 90 of these cells (sites), to collect information on leopard occurrence and predation on domestic animals. A two-member survey team was trained to undertake the interview surveys. The team interviewed 2–6 households in each grid cell during October 2015–April 2016. Following Athreya et al. (Reference Athreya, Srivathsa, Puri, Karanth, Kumar and Karanth2015) and Zeller et al. (Reference Zeller, Nijhawan, Salom-Perez, Potosme and Hines2011), each household was treated as a discrete sampling occasion. Adult residents in each household were asked whether they had detected leopard presence or knew of leopard predation on domestic animals in the immediate neighbourhood (within c. 500 m of their home) over the past year. We only considered the immediate neighbourhood so that we could reliably assign reported predation events to individual grid cells. To avoid ambiguity regarding the identity of the predator, respondents were asked to provide clear descriptions of the species and its signs, or distinguish these from images of various carnivores and their pugmarks. We only recorded leopard presence and/or predation when respondents provided an accurate description of the species. In the case of reported depredation of domestic animals, the interviewers recorded information on the species of domestic animal, count of events and their locations. All interviews were carried out in Nepali.

Covariates and hypotheses

We collated data for a total of five covariates (Table 1). We determined the relative abundance of dogs and goats (covariates dog and goat, respectively) during field surveys and derived the other three covariates from remotely sensed data: normalized difference vegetation index (NDVI; covariate ndvi), Euclidean distance from the centre of the grid cell to the nearest forest patch (covariate distoforest), and the cumulative length of rivers in each grid cell (covariate river). We used ArcGIS 10.2 (Esri, Redlands, USA) for spatial analyses.

Table 1 List of covariates used to model probabilities of leopard Panthera pardus habitat use (Ψ1) and predation on domestic animals (Ψ2) in Kathmandu district, Nepal.

We hypothesized that dogs were likely to attract leopards to settlements (Table 1), as they are important in the leopard's diet (Edgaonkar & Chellam, Reference Edgaonkar and Chellam2002; Athreya et al., Reference Athreya, Odden, Linnell, Krishnaswamy and Karanth2014). However, in grid cells with high dog numbers (beyond a certain threshold) we speculated that leopard predation on dogs may decline as packs of dogs are known to chase off leopards and alert people to the felids’ presence (Young et al., Reference Young, Olson, Reading, Amgalanbaatar and Berger2011; Potgieter et al., Reference Potgieter, Kerley and Marker2015). We counted all dogs within 150 m of surveyed homes and calculated an encounter rate following Krishna et al. (Reference Krishna, Krishnaswamy and Kumar2008):

$${\rm Index} = \displaystyle{{{\rm No}.{\rm \;of\;dogs}} \over {{\rm No}.{\rm \;of\;households\;surveyed\;in\;grid\;cell}}}$$

Leopards prefer medium-sized prey (Karanth & Sunquist, Reference Karanth and Sunquist1995; Hayward et al., Reference Hayward, Henschel, O'Brien, Hofmeyr, Balme and Kerley2006). During interviews, we therefore recorded the number of goats kept by respondents. We then calculated a goat abundance index as described above for dog abundance. We expected high probabilities of leopard presence and predation on domestic animals in grid cells with higher goat abundance (Hayward et al., Reference Hayward, Henschel, O'Brien, Hofmeyr, Balme and Kerley2006; Sangay & Vernes, Reference Sangay and Vernes2008; Table 1). In addition, we predicted that probabilities of leopard occurrence and predation on domestic animals would both decline as a function of distance to forest edge, because urban and built-up areas provide less suitable cover for leopards (Table 1). The NDVI is an indicator of green vegetation (Krishna et al., Reference Krishna, Krishnaswamy and Kumar2008), which we used as a proxy for cover. We predicted that areas with dense vegetation cover would be more likely to harbour leopards (Kshettry et al., Reference Kshettry, Vaidyanathan and Athreya2017). We also predicted that cells with more vegetation cover would have higher rates of predation on goats and dogs, because leopards can remain concealed while stalking or feeding on prey (Table 1). Carnivores commonly use water courses as movement routes (Smith, Reference Smith1993), and we thus expected the cumulative length of rivers in a grid cell to positively influence habitat use by leopards and predation. We expected higher detection probabilities near forests because people residing there were more likely to encounter and report leopards. We also expected that detectability would be higher in cells with high vegetation cover as leopard presence would be reported more frequently in such grid cells, because we expected greater leopard occurrence in cells with higher NDVI (Table 1).

Habitat use states and model parameters

We used multi-state occupancy models to concurrently test our hypotheses about the predictors of leopard habitat use and predation on domestic animals (Nichols et al., Reference Nichols, Hines, Mackenzie, Seamans and Gutierrez2007; Athreya et al., Reference Athreya, Srivathsa, Puri, Karanth, Kumar and Karanth2015). We interpret the parameter Ψ1 as estimated proportion of habitat use and parameter Ψ2 as probability of depredation in sites with habitat use, rather than occupancy, because the size of the sample unit is small relative to the home range of leopards (MacKenzie et al., Reference MacKenzie, Nichols, Royle, Pollock, Bailey and Hines2006; Zeller et al., Reference Zeller, Nijhawan, Salom-Perez, Potosme and Hines2011). We defined three discrete habitat-use and predation states in our detection matrix: unoccupied (state 0), occupied with no predation on domestic animals (state 1) and occupied with predation on domestic animals (state 2). For each interview survey, we recorded ‘0’ when no leopard presence was reported, and ‘2’ when one or more events of predation on domestic animals were reported. We recorded ‘1’ when leopard presence was reported without mention of depredation. State 1 carries a level of uncertainty: it could either be a correct assignment (leopards present but not preying on domestic animals), or an incorrect assignment (actual situation is state 2, but respondent is unaware of depredation event).

Our multi-state occupancy model included five parameters (following Nichols et al., Reference Nichols, Hines, Mackenzie, Seamans and Gutierrez2007). Ψ1 is the probability of site use by leopards, regardless of whether or not predation on domestic animals occurs. Ψ2 is the probability that depredation occurs, in the event that the site is used by leopards. The parameter p 1 is the probability of leopard presence being reported in cases where the true state is 1, and p 2 is the probability of leopard presence being reported where the true state is 2. The parameters p 1 and p 2 address state uncertainty because depredation events may or may not be reported in sites where leopards are present. We also estimated δ, which is the probability of finding evidence for leopard predation on domestic animals in cells where the true state is 2 (leopards are present and predating on livestock).

Data analysis

Prior to model-building, we tested for collinearity among the covariates, and found they were not correlated (r < 0.5). We adopted a two-step process to model the effects of covariates to estimate model parameters (Athreya et al., Reference Athreya, Srivathsa, Puri, Karanth, Kumar and Karanth2015). Firstly, we sought to explain variation in the detection process by modelling distance to forest and NDVI, by building 15 alternate models (covariates modelled singly, additively and a null model; Table 2). In this step, we used a global model for the parameters habitat use (Ψ1 ndvi+dog+goat+river+distoforest) and predation on domestic animals (Ψ2 ndvi+dog+goat+river+distoforest). We compared models using the Akaike information criterion adjusted for small sample size (AICc), to determine the optimal detection parameterization, which was retained in the next modelling step (Table 2).

Table 2 Model results for detection parameters, p 1 (leopard detection probability) and p 2 (detection probability of predation on domestic animals). Two covariates ndvi and distoforest were modelled with global model Ψ1(dog+goat+ndvi+river+distoforest), Ψ2(dog+goat+ndvi+river+distoforest).

1 Covariates: distoforest, distance to nearest forest patch; dog, relative abundance of dogs; goat, relative abundance of goats; ndvi, normalized difference vegetation index; river, cumulative length of rivers in a grid cell.

2 Akaike information criterion adjusted for small sample size.

3 Difference in AICc to best performing model.

In the second step, we tested our hypotheses about the spatial variation in leopard habitat use and predation on domestic animals. For this, we retained the covariate combination for detection parameters from the best supported model from the previous step, and tested our hypotheses about factors influencing spatial variation on Ψ1 and Ψ2. We used a logit link function to assess model parameters as a function of covariates (Mackenzie et al., Reference MacKenzie, Nichols, Lachman, Droege, Andrew Royle and Langtimm2002). Nineteen alternate models were implemented to test our hypothesis. We included covariates for Ψ1 and Ψ2 singly, or in additive combinations (see Table 3 for a complete list of models). Again we evaluated model support using AICc. Analysis was carried out in MARK 8.0 (White, Reference White2019).

Table 3 Model results for probabilities of leopard habitat use (Ψ1) and predation on domestic animals (Ψ2), based on a priori hypotheses. For all models, covariates ndvi and distoforest were used to explain variation in detection probability.

1 Covariates: distoforest, distance to nearest forest patch; dog, relative abundance of dogs; goat, relative abundance of goats; ndvi, normalized difference vegetation index; river, cumulative length of rivers in a grid cell.

2 Akaike information criterion adjusted for small sample size.

3 Difference in AICc to best performing model.

Results

We conducted interviews in 321 households in 90 grid cells, covering 10 municipalities within Kathmandu district. Sixty per cent of the respondents were farmers primarily dependent on agriculture, and others were engaged in livelihoods such as business and service in government institutions or private enterprises. Mean land holding size of respondents 0.12 ha (range 0–2.1 ha), and 69% of respondents identified themselves as middle class, with a monthly income of USD 100–300. Interviewees were aged 18–80 years, with a mean age of 39 years. Seventy-eight per cent of interviewees were men and 22% women.

The naïve probability of leopard habitat use was 63% and predation on domestic animals was recorded in 34% of the surveyed cells. Respondents reported leopard predation on goats (14% of respondents) and dogs (18%), but no human deaths or injuries. The reported losses resulting from depredation of goats were valued at a total of USD 5,790.

Amongst 15 candidate models to assess the influence of covariates on detection probabilities associated with p 1 (leopard detection probability when true state is 1) and p 2 (detection probability when true state is 2), eight models (with combination of covariates distance to forest and NDVI) accumulated > 95% Akaike weight (Table 2). Because both distance to forest and NDVI covariates appeared in the eight best supported models, the model carried forward into the next step of analysis included these covariates (additively) to address heterogeneity in p 1 and p 2. No single model was particularly well supported (Table 2). The model averaged estimate of p 1 was 0.28 ± SE 0.09 and p 2 was 0.51 ± SE 0.06. The model averaged estimate for δ (probability of finding evidence of leopard predation on domestic animals) was 0.46 ± SE 0.05.

Of 19 candidate models run to estimate leopard habitat use with and without predation on domestic animals (Ψ1 and Ψ2), no single model was particularly well supported. The best model, Ψ1(dog+ndvi), Ψ2(goat+river), had 19% of the overall model weight. The additive covariates relative abundance of dogs and NDVI were associated with Ψ1 in the six best supported models (which cumulatively accounted for > 75% of the overall support). For the parameter Ψ2, the relative abundance of goats was associated with these top six models, in combination with one or more of the other covariates (dog abundance, river length and NDVI; Table 3). The model averaged estimate (across all 19 models) of Ψ1 was 0.96 + SE 0.05, indicating near-ubiquitous leopard presence across the study area. The corresponding estimate for Ψ2 was 0.76 + SE 0.15, indicating that depredation on domestic animals occurs in many cells with leopard use.

Given extensive leopard occurrence, none of the covariates in our models had statistically significant influence on the parameter Ψ1 (MacKenzie et al., Reference MacKenzie, Nichols, Lachman, Droege, Andrew Royle and Langtimm2002; Table 4). The parameter Ψ2 was positively associated with goat abundance β ̂ = 2.28 ± SE 0.92. Probability of habitat use with predation increased when the goat encounter rate was > 4, and fell away steeply at lower values of this covariate (Fig. 2). Relative abundance of dogs and normalized difference vegetation index were positively associated with probability of livestock depredation in cells with leopard site use β̂ = 0.70 ± SE 0.57; β̂ = 0.54 ± SE 0.49, although there was considerable uncertainty in these estimates. River length and distance to forest did not have any discernible effect on the parameters Ψ1 and Ψ2 based on these data.

Fig. 2 Relationship between occurrence of predation (Ψ2) and relative abundance of goats. The black dots and line show the mean value and the grey area represents the 95% CI.

Table 4 Estimates of β-coefficient values (with standard errors) for individual covariates associated with probabilities of leopard presence (Ψ1) and predation on domestic animals (Ψ2) for 19 models. For all models, covariates ndvi and distoforest were fixed with detection probabilities p 1 and p 2.

1 Covariates: distoforest, distance to nearest forest patch; dog, relative abundance of dogs; goat, relative abundance of goats; ndvi, normalized difference vegetation index; river, cumulative length of rivers in a grid cell.

Discussion

Our finding that leopards occur extensively in areas with high human densities in Kathmandu district is of significance for a number of reasons. Firstly, it establishes that this leopard population is well adapted to exploiting farmlands and human settlements in a densely populated landscape, with near-ubiquitous occurrence over the study area. Our findings corroborate those of Athreya et al. (Reference Athreya, Odden, Linnell, Krishnaswamy and Karanth2013) from Maharashtra state in India, where leopards move extensively within an agricultural landscape. We note, however, that the Kathmandu valley is more densely populated than areas such as rural Maharashtra. Secondly, we ascertained that c. 76% of the area around Kathmandu city is subject to varying levels of leopard predation on domestic animals (Fig. 3). Remarkably, despite the widespread distribution of leopards, attacks on people are infrequent. Our findings, however, do suggest that leopards may use both adjacent forests and peri-urban habitats, where they prey upon domestic animals and gain access to additional food resources. This leads us to conjecture that leopards have a predilection to spend longer periods in these peri-urban areas.

Fig. 3 (a) Probability of habitat use of leopard in peri-urban Kathmandu within 2 km2 survey grid cells, and (b) probability of occurrence of predation on domestic animals. These estimates are from the best-ranked model Ψ1 (dog+ndvi), Ψ2 (goat+river).

We found that the relationship between leopard habitat use and relative abundance of dogs is variable. Although dogs attract leopards (Athreya et al., Reference Athreya, Odden, Linnell, Krishnaswamy and Karanth2014), they may also repel leopards. Dogs in Kathmandu occur in a density of 5 animals/ha (Kakati, Reference Kakati2010) and our observations indicate that they generally form packs and live in clusters. An explanation for the possible ambiguity in the relationship between leopard habitat use and relative abundance of dogs could be that dog packs may detect and repel leopards away from human settlements. In addition, reporting of predation on stray dogs may be incomplete. More research is required to obtain robust, spatially explicit estimates of dog and leopard populations in the study area, and examine the interactions of these species in peri-urban areas.

Our research raises an important question: if leopards are widely distributed and frequently predate on dogs and goats, why are encounters between people and leopards rare in the Kathmandu valley? This is in contrast to some other areas of the Himalayas (Naha et al., Reference Naha, Sathyakumar and Rawat2018), where people have frequently been injured or killed by leopards. We posit that most settlements within our study area have amenities such as street lights and toilets within homes, which reduce close interaction between humans and leopards, even in shared spaces. Odden et al. (Reference Odden, Athreya, Rattan and Linnell2014) reported that leopards adapt their behaviour to avoid humans, and predominantly use areas within settlements at night.

Leopard habitat use and predation on domestic animals in Kathmandu district also needs to be understood in the context of the ecology of predators and prey in the forests around the city. Forests in the mid-hills of Nepal generally support sparse populations of wild prey (Acharya et al., Reference Acharya, Paudel, Neupane and Köhl2016), which may push leopards into human-dominated habitats where they can predate upon domestic animals with relative ease (Kabir et al., Reference Kabir, Ghoddousi, Awan and Awan2013). There is no information on the distribution and abundance of wild prey species of leopards in the Shivapuri-Nagarjun National Park and Kathmandu Forest Division. Carrying out a baseline assessment of prey and predator populations in this forest is thus a priority area for future research, to examine the proximate drivers of predation on domestic animals in the Kathmandu valley. Moreover, expansion of human settlements into wilderness areas increases spatial overlap between people and carnivores, and the risk of negative interactions (Woodroffe, Reference Woodroffe2000). Our research calls for urban planners to consider these factors when delineating plans for urban development in the Kathmandu valley, to limit encroachment of human settlements into natural habitats.

A key limitation of our study is that it does not account for false positives in responses (leopard presence and predation on domestic animals may have been reported in areas where the true state was 0 or 1). This is because we do not have independent data sources (e.g. from camera traps or sign surveys) or information to differentiate between more and less reliable observers. False positives in the data can introduce bias in the parameter estimates (Royle & Link, Reference Royle and Link2006; Petracca et al., Reference Petracca, Frair, Cohen, Calderon, Carazo-Salazar and Castaneda2018). We note that our results are therefore preliminary, although it is common for occupancy surveys using interview data to not account for false positives, particularly when these are rapid surveys or studies carried out using modest budgets (Ghoshal et al., Reference Ghoshal, Bhatnagar, Pandav, Sharma, Mishra, Raghunath and Suryawanshi2019; Srivathsa et al., Reference Srivathsa, Puri, Karanth, Patel and Kumar2019). Future studies should build on our initial work by combining sign surveys or camera trapping with interview data, to account for potential false positives. Robust estimates of dog abundance may be derived by rigorous sampling coupled with mark–resight models (Punjabi et al., Reference Punjabi, Athreya and Linnell2012), in lieu of encounter rates.

Management and policy recommendations

Negative human–leopard interactions in Kathmandu district are an increasing problem. During our study period, leopards were captured and removed from three locations within urban areas. We anticipate that conflict may be exacerbated by increasing human and livestock populations and progressive urbanization that may create ecological traps as the landscape is further fragmented. Thus comprehensive strategies are needed to mitigate conflict. We propose a two-pronged approach. Firstly, a framework is required for the systematic monitoring of leopards in the area, for which our study can serve as a template. Secondly, a comprehensive conflict mitigation plan should be created, including education and awareness programmes, control of free-ranging dogs (with monitoring to assess any potential unintended adverse effects such as increased predation on livestock), measures to prevent attacks on livestock (e.g. predator-proof corrals), compensation programmes and rapid response teams to ensure human and animal welfare in conflict-prone areas. These teams must include personnel trained in animal capture and crowd control. Careful deliberation is needed on whether and where captured leopards should be translocated (Athreya et al., Reference Athreya, Odden, Linnell and Karanth2011). Effective conflict mitigation planning and implementation of plans will require the collaboration of various stakeholders including government departments, veterinarians, ecologists and community representatives. Ultimately, plans will need to recognize that a strict separation of people and leopards may not be feasible in the Kathmandu valley, and they must therefore also include measures that enable coexistence in shared spaces.

Acknowledgements

We thank the Department of National Parks and Wildlife Conservation of the Government of Nepal for permission to carry out this study. We acknowledge the financial support provided by National Trust for Nature Conservation under IDA project no. H6660. We acknowledge the contribution of Sujhav Pun and Mr Bishwanath for their support in coordination; and Nirmal Magar, Surendar Magar and Sagar Bhattarai for assistance in field data collection.

Author contributions

Study design and fieldwork: AB; data analysis: AB, PC; writing: AB; revisions: all authors.

Conflicts of interest

None.

Ethical standards

This research abided by the Oryx guidelines on ethical standards. We obtained verbal consent from each respondent before starting the interview.

Footnotes

*

Previously at: National Trust for Nature Conservation, Khumaltar, Lalitpur, Nepal

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Figure 0

Fig. 1 Study area showing Kathmandu district, Kathmandu city and survey locations within 90 2-km2 grid cells. The inset map shows the location of the study area within Nepal.

Figure 1

Table 1 List of covariates used to model probabilities of leopard Panthera pardus habitat use (Ψ1) and predation on domestic animals (Ψ2) in Kathmandu district, Nepal.

Figure 2

Table 2 Model results for detection parameters, p1 (leopard detection probability) and p2 (detection probability of predation on domestic animals). Two covariates ndvi and distoforest were modelled with global model Ψ1(dog+goat+ndvi+river+distoforest), Ψ2(dog+goat+ndvi+river+distoforest).

Figure 3

Table 3 Model results for probabilities of leopard habitat use (Ψ1) and predation on domestic animals (Ψ2), based on a priori hypotheses. For all models, covariates ndvi and distoforest were used to explain variation in detection probability.

Figure 4

Fig. 2 Relationship between occurrence of predation (Ψ2) and relative abundance of goats. The black dots and line show the mean value and the grey area represents the 95% CI.

Figure 5

Table 4 Estimates of β-coefficient values (with standard errors) for individual covariates associated with probabilities of leopard presence (Ψ1) and predation on domestic animals (Ψ2) for 19 models. For all models, covariates ndvi and distoforest were fixed with detection probabilities p1 and p2.

Figure 6

Fig. 3 (a) Probability of habitat use of leopard in peri-urban Kathmandu within 2 km2 survey grid cells, and (b) probability of occurrence of predation on domestic animals. These estimates are from the best-ranked model Ψ1 (dog+ndvi), Ψ2 (goat+river).

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