Introduction
Two major challenges in studying wildlife ecology are the characterization of habitat use and the identification of factors limiting a species’ distribution. Habitat generalists can tolerate a broad spectrum of environmental conditions, whereas specialists are restricted to a limited set of environmental conditions, which restricts their areas of distribution and makes them more vulnerable to disturbance and loss of specific habitat resources (Crown & van Riper, Reference Crown and van Riper2010). Where a species lies along this generalist–specialist continuum affects its population dynamics (Kolasa & Li, Reference Kolasa and Li2003). In the current context of global environmental change (e.g. through climate change, habitat loss and pollution) it is a priority to document habitat use by specialist species, and to consider natural and anthropogenic factors that influence their distribution. Such studies facilitate the identification not only of habitat units within the landscape that could potentially support viable populations, but also of factors that limit the species’ distribution. In particular, this information is fundamental for mitigation measures that encourage habitat occupation, which is a priority for the conservation of threatened species (Edgel et al., Reference Edgel, Pierce and Larson2014).
The volcano rabbit Romerolagus diazi (also known as zacatuche or teporingo) is a mountain habitat specialist endemic to the Sierra Chichinautzin and Sierra Nevada volcanic fields in the Trans-Mexican Volcanic Belt. It is associated with patches containing bunchgrasses (e.g. Muhlenbergia spp. and Festuca spp.) that have a fragmented distribution within forests at elevations of 2,800–4,200 m (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996). There is increasing anthropogenic pressure on volcano rabbit populations. Cattle grazing, logging and land conversion for agriculture lead to habitat modification, fragmentation and loss (Galicia & García-Romero, Reference Galicia and García-Romero2007; Arregoitia et al., Reference Arregoitia, Leach, Reid and Fisher2015). As a result, the volcano rabbit is categorized as Endangered on the IUCN Red List (Velázquez & Guerrero, Reference Velázquez and Guerrero2019), and considered in danger of extinction by Mexican laws (SEMARNAT, 2010).
High abundance of this lagomorph has been recorded in sites covered by grass species with a bunch type growth habit (Festuca tolucensis and Festuca tolucensis–Trisetum altijugum), followed by bunchgrasses associated with pine forests (Muhlenbergia quadridentata and F. tolucensis associated with Pinus hartwegii; Velázquez & Heil, Reference Velázquez and Heil1996). However, the rabbit's preference for biological and structural habitat features varies locally. On the Pelado volcano in the Sierra Chichinautzin, rabbit populations occurred mainly in mixed forests (Pinus spp.–Alnus spp.; Fa et al., Reference Fa, Romero and Lopez-Paniagua1992). On some volcanoes in the southern Sierra Chichinautzin, at elevations of 2,760–3,250 m, the species’ abundance was influenced by the patch size and cover extent of bunchgrasses, and the presence of shrubs (Rizo-Aguilar et al., Reference Rizo-Aguilar, Guerrero, Hidalgo-Mihart and González-Romero2015, Reference Rizo-Aguilar, Delfin-Alonso, Gonzalez-Romero and Guerrero2016; Uriostegui-Velarde et al., Reference Uriostegui-Velarde, Gonzalez-Romero, Pineda, Reyna-Hurtado, Rizo-Aguilar and Guerrero2018). On the Iztaccíhuatl volcano in the Sierra Nevada (3,400–4,000 m), forest cover and cattle grazing correlated negatively with habitat occurrence for this species, whereas population abundance increased with distance from the surveillance facilities of the Izta-Popo National Park (Hunter & Cresswell, Reference Hunter and Creswell2015).
All previous studies were carried out in specific locations at restricted elevation ranges. It is unknown whether the differences observed between sites are a consequence of specific local conditions or constitute a general pattern of habitat use by the volcano rabbit across its range. Therefore, we considered the entire known range of this species, including the two major volcanic ranges, its full elevational range and all suitable habitats in these landscapes. We aimed to answer the following questions: (1) which factors (biotic, abiotic and anthropogenic) influence patch occupancy and relative abundance of the volcano rabbit, and (2) to what extent is cattle grazing a threat to its populations? Given the known association of volcano rabbits with bunchgrasses, we predicted: (1) a positive correlation between both patch occupancy and relative abundance with per cent bunchgrass cover, and (2) reduced patch occupancy and relative abundance in areas grazed by cattle.
Study area
This work was carried out in the Sierra Chichinautzin and Sierra Nevada volcanic fields. These mountains are located in the eastern Trans-Mexican Volcanic Belt, adjacent to Mexico City, one of the world's largest urban centres. Together, these volcanic fields encompass the global range of the species (Hunter & Cresswell, Reference Hunter and Creswell2015). The Sierra Chichinautzin comprises more than 200 volcanoes, whereas the Sierra Nevada consists of only five large volcanoes, including Popocatépetl (5,426 m) and Iztaccíhuatl (5,230 m), the second and third highest in Mexico (Márquez et al., Reference Márquez, Verma, Anguita, Oyarzun and Brandle1999). Vegetation cover is temperate forests (e.g. Quercus spp., Pinus spp. and Abies spp.) and subalpine and alpine grasslands (e.g. Muhlenbergia spp., Festuca spp. and Calamagrostis spp.; Rzedowski, Reference Rzedowski1988). We observed seven species of bunchgrasses that can be used by the volcano rabbit: Muhlenbergia macroura, M. quadridentata, F. tolucensis, Festuca rosaceae, Festuca amplissima, Calamagrostis tolucensis and Stipa ichu. The dominant species were M. macroura and F. tolucensis, which were present in > 90% of the patches occupied by the volcano rabbit. The Sierra Chichinautzin and Sierra Nevada harbour a great diversity of vertebrates, including some micro-endemic high mountain specialists such as the volcano axolotl Ambystoma leorae (Monroy et al., Reference Monroy, Pino, Lozano and García2011). There are numerous human settlements in the area, and associated agricultural and forestry activities (Galicia & García-Romero, Reference Galicia and García-Romero2007). The forest is the main source of income and energy (i.e. fuel for cooking and heating) for local communities (Trejo & Dirzo, Reference Trejo and Dirzo2000). There are four main land-use types in the region: cropland, pastures for livestock grazing, forests (used for timber and firewood extraction) and urban areas. Other activities include hunting and the extraction of fertile soil that is sold for use in gardening (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996; Galicia & García-Romero, Reference Galicia and García-Romero2007).
Despite their geographical proximity, there are profound differences between the two mountain ranges. Habitat patches in the Sierra Chichinautzin are small and isolated by a forest matrix with agricultural fields, with high levels of human disturbance (forest exploitation and cattle grazing; Table 1). Environmental conditions in the Sierra Chichinautzin are warmer and drier than in the Sierra Nevada and thus less favourable for the growth of bunchgrasses. In addition, urban pressure is higher because the Sierra Chichinautzin is near Mexico City and Cuernavaca. In the Sierra Nevada patches of grassland are larger, more connected and less affected by human activities, presenting more favourable conditions for the volcano rabbit.
1 Variable used in presence model.
2 Variable used in relative abundance model.
3 Diameter at breast height > 50 cm.
Methods
Survey design
Based on historical records of the volcano rabbit (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996; Domínguez, Reference Domínguez2007; Osuna et al., Reference Osuna, Gonzalez, Espinosa de los Monteros and Guerreo2020) we delimited the possible range of the species in both volcanic fields as areas at 2,900–4,350 m altitude. During 2016 and 2017 we surveyed a total of 770 km2 in search for patches with dense bunchgrass cover that could be suitable habitat for the volcano rabbit (Velazquez & Heil, Reference Velázquez and Heil1996). In areas with fragmented habitats, we considered bunchgrass patches that were at least 250 m apart as independent sites. We found 165 independent sites of bunchgrass patches adequate for the presence of volcano rabbits. We marked a 20 × 20 m quadrant in each patch (Mueller-Dombois & Ellenberg, Reference Mueller-Dombois and Ellenberg1974), to determine the presence of volcano rabbits and gather data about environmental variables considered to be associated with habitat quality. We placed the sample quadrant near the centre of each patch, avoiding roads or areas that showed clear evidence of human alteration. We placed metal posts at the quadrant corners and marked the perimeter with a rope tied to the corner posts. Using cotton thread tied to the perimeter ropes at 2 m intervals, we divided each quadrant into 4 m2 grid cells, to take fine-scale measurements of environmental variables.
The volcano rabbit is secretive and shy, hiding in burrows at any perceived danger, which means direct observation is rarely possible. We therefore used the indirect method of excreta presence to infer patch occupancy. This is a widely used method for the study of this and other lagomorphs (Krebs et al., Reference Krebs, Gilbert, Boutin and Boonstra1986; Hunter & Creswell, Reference Hunter and Creswell2015). We did not consider individual droppings nor dispersed excreta as evidence for rabbit presence, but searched the entire ground surface of the quadrant for latrines. Latrines are defined as areas with more than 30 fresh faecal pellets grouped together (Santilli et al., Reference Santilli, Bagliacca and Paci2015), are easy to detect and indicate recent occupation by volcano rabbits. Patches with burrows but without latrines could be abandoned sites. We recorded a site as inhabited by volcano rabbits only when both latrines and burrows were present. One latrine is not necessarily equivalent to one individual, but a positive relationship between the number of latrines and the number of individuals has been suggested (Hunter & Creswell, Reference Hunter and Creswell2015; Santilli et al., Reference Santilli, Bagliacca and Paci2015). Therefore, recording the number of latrines is an indirect way of inferring relative abundance.
Variables related to habitat use
We recorded a total of 14 variables related to habitat for analysis (Table 1), based on the known natural history of the species (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996) and previous studies on its habitat use (Fa et al., Reference Fa, Romero and Lopez-Paniagua1992; Hunter & Creswell, Reference Hunter and Creswell2015; Rizo-Aguilar et al., Reference Rizo-Aguilar, Delfin-Alonso, Gonzalez-Romero and Guerrero2016). To analyse vegetation cover we measured the per cent cover of bunchgrasses higher than 50 cm, herbaceous plants and shrubs, and counted the number of adult trees with a diameter at breast height of > 50 cm. We quantified forest cover using a spherical densiometer, estimating the value for each site as the mean of the four measurements corresponding to the different cardinal points from the centre of the quadrant. In some instances, different vegetation types (e.g. grass, shrubs, herbaceous plants) overlapped, so the sum of their cover percentages was > 100% of the quadrant area. We recorded the presence of other rabbits (the Mexican cottontail Sylvilagus cunicularius and eastern cottontail Sylvilagus floridanus) by identifying their excreta, which are easily distinguished from those of the volcano rabbit (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996).
We extracted abiotic variables, including per cent cover of rocks, elevation and slope, from the official Mexican Digital Elevation Model (Mexican Elevation Continuum, CEM 3.0, at 15 m; INEGI, 2013) using QGIS 3.1 (QGIS Development Team, 2009). The identity of the volcanic field (i.e. Sierra Chichinautzin or Sierra Nevada) was included in the analysis as an abiotic factor.
We determined the presence of cattle grazing by livestock sightings, the presence of excreta, and evidence of grazing at or close to the bunchgrass patch. We calculated the distance from the centre of each sample patch to the nearest human settlement using Google Earth Pro (US Department of State Geographer, 2018). This programme accounts for relief and landscape features such as creeks or hills when measuring distances on the Earth's surface. We included in our analysis the human impact index on Mexican biodiversity from MEXBIO (CONABIO, 2018), which is based on the theoretical framework of the Global Biodiversity Model and establishes simple cause–effect relationships between different environmental pressures and threats. We adapted the model for Mexico at a resolution of 1 km2, including factors such as land-use pressure, infrastructure and habitat fragmentation. The distance to human settlements affects local conditions such as habitat quality, whereas the index of human impact mainly influences spatial processes such as species dispersal amongst patches.
Data analysis
We performed statistical analyses in R 3.3.1 (R Development Core Team, 2012). We created two matrices: (1) presence analysis, to detect variables that influenced patch occupancy, and (2) relative abundance analysis, to detect variables that influenced this parameter. For each matrix we constructed generalized linear models. To assess presence, we built a binomial regression model (presence/absence) with the data from all patches, using the logit link function in R. For relative abundance, we constructed a model based only on data from occupied patches, using the gamma distribution and reciprocal link functions in R. Given the models’ complexity (14 variables and their interactions), we followed a series of steps to find the simplest possible model: (1) We explored each variable using a univariate model, to infer its individual contribution. (2) For each matrix we reduced the number of variables depending on the individual contribution of each variable (Table 1). (3) We evaluated models with all paired interactions between their variables. (4) We performed a stepwise bidirectional simplification procedure employing the Akaike information criterion (AIC) value as a criterion for model selection, using the stepAIC function in the MASS package for R. (5) We refined the simplification by comparing models using the difference in variance until we identified the simplest model.
Results
We detected volcano rabbits in 71 of the 165 patches visited (Fig. 1). The model that best explained their presence retained nine variables and 12 interactions, accounting for 47% of the total variance. Bunchgrass cover, rock cover, distance to the nearest human settlement and cattle grazing were the variables with the most significant effects (Table 2). The probability of patch occupancy increased with higher per cent cover of bunchgrasses and rocks (Fig. 2a,b), but decreased in the presence of cattle grazing and in closer proximity to human settlements (Fig. 2c,d). However, the effect of the distance to human settlements was different between the two volcanic fields (Supplementary Fig. 1a). In the Sierra Chichinautzin, the probability of patch occupancy was < 5% when human settlements were < 4 km away (P < 0.05), but increased rapidly as distance increased (P < 0.001). In the Sierra Nevada, we observed no significant effect for this factor (P = 0.342).
In the Sierra Chichinautzin, the presence of cattle grazing reduced the probability of patch occupancy to 3%, whereas without cattle grazing it was up to 70%. However, cattle grazing did not change the probability of patch occupancy in the Sierra Nevada, where it remained at c. 50% (Supplementary Fig. 1f). Nevertheless, the variance of the probability for patch occupancy increased where cattle grazing occurred. The interaction between cattle grazing and distance to human settlements had a negative effect on patch occupancy. Volcano rabbits were nearly absent from cattle-grazed patches located less than 6 km from human settlements, but the probability of patch occupancy increased rapidly with increasing distance from human settlements (Supplementary Fig. 1b). In the absence of cattle grazing, the distance to human settlements did not affect the probability of patch occupancy. The interaction between presence of the Mexican cottontail and per cent shrub cover was significant. When another lagomorph was present, the probability of recording the volcano rabbit increased as shrub cover increased (Supplementary Fig. 1c). An increase in rock cover and forest cover (Supplementary Fig. 1e,f) correlated positively with patch occupancy at elevations < 3,600 m, where these elements are common.
The model that best explained relative abundance retained eight variables and seven interactions, explaining 66% of the total variance (Table 2). The relative abundance of volcano rabbits was significantly higher in patches with > 75% of bunchgrass cover (Fig. 3a), and in those located at altitudes > 3,600 m (Fig. 3b). Relative abundance had a negative relationship with rock cover (Fig. 3c) and cattle grazing (Fig. 3d). Regarding interactions between variables, we detected that volcano rabbits were most abundant in patches with > 75% bunchgrass cover, < 15% shrub cover and > 25% forest cover (Supplementary Fig. 2a,b). We found an increased relative abundance of volcano rabbits as forest cover increased, if rock cover was > 15% (Supplementary Fig. 2c). The effect of bunchgrass cover was greater in the Sierra Nevada than in the Sierra Chichinautzin (Supplementary Fig. 2f). Above 3,600 m, shrub cover had a positive (Supplementary Fig. 2d) and rock cover a negative effect on relative abundance (Supplementary Fig. 2e). In the Sierra Chichinautzin the presence of the Mexican cottontail negatively affected the relative abundance of the volcano rabbit, whereas in the Sierra Nevada the effect of such sympatry was positive (Supplementary Fig. 2g).
Discussion
The probability of recording volcano rabbits and their relative abundance in occupied areas was associated with dense cover of native bunchgrasses and rocky areas at high elevations on the volcanoes surrounding Mexico City. The proximity of these mountains to one of the most populated areas in the world leads to severe habitat modifications (e.g. natural resource extraction, introduction of livestock, accidental and provoked fires) that negatively affect the volcano rabbit and many other wildlife species.
Biotic factors
Bunchgrasses are a primary resource that defines habitat suitability for the volcano rabbit throughout its range; this is consistent with previous local reports (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996; Hunter & Creswell, Reference Hunter and Creswell2015) and can be explained by the species’ ecology. Bunchgrasses represent > 50% of the volcano rabbit's diet (Cervantes et al., Reference Cervantes, Lorenzo, Vargas and Holmes1992; Martínez-García et al., Reference Martínez-García, Mendoza, Alcantara, Tarango, Sánchez, Rodríguez and Hernández2012). As the rabbits move through the habitat, the grasses are bent, forming tunnels and passages that provide cover from predators (Cervantes, Reference Cervantes1981). These runways are marked with latrines to define territories. The rabbits also use bunchgrasses as nest-building material, and the base of well-developed bunches as nests (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996). The model constructed for relative abundance detected that the interactions of bunchgrass cover with shrub cover, forest cover and identity of the volcanic field were significant, but in all cases the relative abundance was greater in those patches that had bunchgrass cover > 75%. This degree of habitat specificity is comparable to that of the pygmy rabbit Brachylagus idahoensis. This species is distributed in the western USA and is associated with plants of the genus Artemisia (Schmalz et al., Reference Schmalz, Wachocki, Wright, Zeveloff and Skopec2014). Volcano and pygmy rabbits are the two smallest leporid species, both with a mean weight < 500 g (Green & Flinder, Reference Green and Flinder1980; Cervantes et al., Reference Cervantes, Lorenzo and Hoffmann1990).
Sympatry between volcano rabbits and other Mexican rabbits seems to be mediated by shrub cover. The presence of shrubs may indicate better habitat quality, and therefore allow the co-occurrence of species sharing similar niches. Another possibility is that competition for bunchgrasses may force volcano rabbits into areas with denser shrub cover. To assess the likelihood of these scenarios, it would be necessary to carry out studies that include experimental manipulation (e.g. shrub removal, shrub cover modification). At elevations > 3,600 m the relative abundance of the volcano rabbit was higher in patches with denser shrub cover. It has been reported that during times of harsh environmental conditions (cold and dry winter months when grasses are scarce), volcano rabbits increase their consumption of shrubs (shrubs comprise 1.3% of their diet in the rainy season and up to 12.8% in the dry season; Cervantes & Martínez, Reference Cervantes and Martínez1992). This increased consumption of shrubs could also occur in the more restrictive environmental conditions near the upper elevation limit of the species’ distribution.
Sympatry with the Mexican cottontail was negatively correlated with the relative abundance of the volcano rabbit in the Sierra Chichnautzin, but positively correlated in the Sierra Nevada. Higher levels of human disturbance (human impact index of 0.7 in the Sierra Chichinautzin vs 0.6 in the Sierra Nevada; Table 1) may indicate lower habitat quality in the Sierra Chichinautzin, which could intensify competition between the volcano rabbit and other lagomorphs (Leach et al., Reference Leach, Montgomery and Reid2015). This finding is consistent with high levels of physiological stress (inferred by the amount of cortisol and its derivatives measured in the excreta) reported for the volcano rabbit in some patches in the Sierra Chichinautzin (Rizo-Aguilar et al., Reference Rizo-Aguilar, Guerrero, Montoya-Lara and Valdespino2014). In the larger areas of grassland away from human influence in the Sierra Nevada the rabbits may experience less pressure on resources such as food and shelter. It is also possible that sympatry with other lagomorphs could be positive for the volcano rabbit in these areas because of reduced predation pressure. However, studies with an experimental design would be required to examine these interspecific interactions more thoroughly.
Abiotic factors
Rock cover was determinant for the presence and relative abundance of the volcano rabbit. The probability of patch occupancy was highest where rock cover was 5–15% but the relative abundance of rabbits in those patches was lower than in occupied patches with rock cover < 5%. For small mammals such as the volcano rabbit, rocks may act as refuges that facilitate predator avoidance (Alves et al., Reference Alves, Ferrand and Hackländer2008). The species exhibits social aggregation and is the only leporid that vocalizes (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996). Sometimes it is possible to observe individuals on rocks, keeping watch and emitting alerts to the group if a threat is detected. However, sites with a rock cover > 15% are characterized by a low relative abundance of volcano rabbits, as a greater per cent of rock cover means less bunchgrass cover.
The effect of elevation on relative abundance reflects the species' habitat preference, considering that bunchgrasses predominate at elevations > 3,600 m (Velázquez & Heil, Reference Velázquez and Heil1996; Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996). Typically, at elevations < 3,000 m habitat patches are small and with substantial tree cover (Abies spp., Alnus spp. and Pinus spp.), isolated by a forest matrix mixed with agricultural fields. Large habitat patches (with high relative abundance of volcano rabbits) can also be found at altitudes of 3,000–3,600 m in grasslands with pine forest, characterized by the predominance of M. macroura–Pinus spp. or F. tolucensis–Pinus spp. At elevations > 3,600 m, there are extensive areas of subalpine and alpine grasslands (e.g. Festuca spp., Muhlenbergia spp. and Calamagrostis spp.), with large habitat patches in a matrix that is permeable to movements of volcano rabbits. Our findings differ from those of Velázquez & Heil (Reference Velázquez and Heil1996), who reported a negative correlation between elevation and the relative abundance of volcano rabbits in the Sierra Chichinautzin. This discrepancy could be attributable to sampling design: the highest elevations of the Sierra Chichinautzin are < 3,700 m, so there may have been few suitable patches for the volcano rabbit at the study site of Velázquez & Heil (Reference Velázquez and Heil1996).
The interactions between rock cover and elevation, and between rock cover and forest cover, appeared to be a result of spatial autocorrelation between these factors. At elevations < 3,600 m, as in the Sierra Chichinautzin, 36% of the patches of suitable habitat have rocks, and the mean rock cover in occupied patches was 5.8%. At elevations > 3,600 m, as in most of the Sierra Nevada, 10% of the patches of suitable habitat have rocks and the occupied patches averaged 1.7% of rock cover. The existence of larger and more connected patches in the Sierra Nevada compared to the Sierra Chichinautzin leads to a greater probability of detecting the presence of volcano rabbits even when the rock cover in some of those patches is < 5%. The positive effect of forest cover on volcano rabbit presence at elevations < 3,600 m can be explained by the fact that forest can be extensive at those elevations, whereas at higher elevations forest cover is naturally lower. In both sierras, large proportions of forest cover may indicate low levels of human disturbance, and thus an increased probability of species detection. In addition, it has been reported that volcano rabbits feed on leaves of Alnus spp. (Cervantes & Martínez, Reference Cervantes and Martínez1992), which is common in both sierras at elevations < 3,600 m and contributes significantly to forest cover.
Anthropogenic factors
We found that cattle grazing and close proximity to human settlements significantly reduced occupancy by volcano rabbits, particularly in the Sierra Chichinautzin. This suggests that this species, like other habitat specialists, is sensitive to human disturbance. Human impact on ecosystems leads to the loss of specific resources, in this case bunchgrasses. A negative effect of anthropogenic disturbances on habitat specialists has been demonstrated in other studies (Pierce et al., Reference Pierce, Larsen, Flinders and Whiting2011; Dendup et al., Reference Dendup, Cheng, Lham and Tenzi2017; Zhao et al., Reference Zhao, Yue, Ran, Moermond, Hou, Yang and Gu2017). We found that the presence of livestock grazing primarily affected patch occupancy, but had little effect on relative abundance. It is possible that this could be the effect of recent cattle introduction to patches that have long been used by rabbits.
Cattle feed mainly on bunchgrasses, and the way in which they graze reduces grass cover and alters its natural structure. High rates of fires are also associated with grazing because of prescribed burning during the dry season to stimulate pasture regrowth (Blanco et al., Reference Blanco, Ceballos, Galindo, Maas, Patrón, Pescador and Suárez1981). Fires are a major threat to lagomorph conservation (Portales et al., Reference Portales, Reyes, Rangel, Velazquez, Miller, Ellis and Smith1997). Burning pasture is a common activity throughout the entire range of the volcano rabbit, causing numerous uncontrolled fires that devastate hundreds of hectares of grasslands per year. Other factors that reduce habitat quality in the vicinity of human settlements (Velázquez et al., Reference Velázquez, Romero and López-Paniagua1996) include agriculture, wood extraction, removal of fertile soil, hunting, road construction, pollution and presence of feral fauna. These factors need to be taken into account when planning and implementing conservation actions.
Implications for conservation
Our findings can contribute to the design and development of effective conservation plans for the volcano rabbit and its habitat. The species’ dependence on bunchgrasses makes the protection of the natural grasslands in the Sierra Chichinautzin and the Sierra Nevada a matter of high importance. We found that the presence of livestock and probably other factors such as fires and agricultural expansion may represent a threat to this key resource, with grazing directly affecting bunchgrass cover and structure. Mitigating the impact of cattle grazing is a priority at both volcanic fields because of its negative effect that can lead to local extirpation of volcano rabbit populations. Furthermore, the lack of trained personel to enforce the current regulations (SEMARNAT, 2012; DOF, 2018) limiting the exploitation of natural resources is a serious problem. In addition to increasing capacity for law enforcement, environmental education programmes should be established. These measures could support the conservation of not only the volcano rabbit, but also other wildlife species in these ecosystems.
An imminent threat that has not been evaluated is afforestation of grassland areas at both sierras. The impact of such artificial creation of forest on the habitat of the volcano rabbit should be evaluated. In addition, a long-term monitoring programme for the volcano rabbit should be established, to examine the effects of both the natural components of the habitat and human disturbances on the dynamics of extinction and recolonization of local populations of the volcano rabbit and other endemic species.
Acknowledgements
We thank C. Osuna, F. Osuna and M. Uriostegui for their support during fieldwork; The Rufford Foundation for financial support (Rufford Small Grant 21227-1); and A. Smith and one anonymous reviewer for their critiques. FO received a Graduate Student Scholarship from CONACyT México (ID: 295207). This manuscript is submitted in partial fulfilment of the requirements for the degree Doctorado en Ciencias of the graduate student programme at the Instituto de Ecologia AC, México.
Author contributions
Project design: all authors; logistic support: AEM; fieldwork: FO; data analyses: FO, RG; writing: FO, RG, AEM.
Conflicts of interest
None.
Ethical standards
This research abided by the Oryx guidelines on ethical standards. No animals were collected or handled, and site surveys had minimal impact on the habitat.