Wild boar battues reduce crop damages in a protected area.
Key words: lethal control, agricultural damages, corn, hunters, dogs
Conflicts between wildlife and human interests are a matter of concern worldwide (Woodroffe et al. 2005) as wildlife populations expand into anthropic environments with increasing human populations. The problems are particularly significant in poor countries, where farmers view agricultural damages caused by wildlife as their worst financial problem (Naughton-Treves & Treves 2005). The wildlife-caused damages to crops in the Ebro Sotos and Galachos Nature Reserve, Spain, have created a significant conflict because of the characteristics of protected areas, which include crops that are highly attractive to wild boar (Neet 1995), the absence of measures by farmers to prevent damages, and a limited capacity to control the wild boar population. Since the beginning of agriculture, wildlife has caused damages to crops and livestock. A variety of techniques (scarecrows, snares, traps, cages, poison, vigilance, battues or drive hunts, waitings, changing crops etc.) have been used to address the problem (Honda et al. 2009, Massei et al. 2011) however, there is little or no scientific evidence of the effectiveness of these techniques (Woodroffe et al. 2005), even though wildlife-caused damages can cause significant economic harm, lead to farm failures, and the emigration of farmers (Treves 2008). Often, farmers spend a significant amount of resources to mitigate agricultural damages, primarily by using phyto-sanitary products that protect crops against fungi, insects, bacteria, viruses and, to a lesser extent, wild ungulates and other wildlife.
The number and distribution of wild boar worldwide has increased substantially (Vassant et al. 1987, Apollonio et al. 2010, Massei et al. 2011). This has made the species an important factor in the ecosystems in which it lives (Barrios-Garcia & Ballari 2012) because of its effects on the economy and the environment (Herrero et al. 2006). Wild boar damage crops (Herrero et al. 2006) and kill livestock (Pavlov & Hone 1982), or are suspected of doing so, which has a social impact (Herrero & Fernandez de Luco 2003). They also influence the natural environment through selective foraging (Gimenez-Anaya et al. 2008) and by altering the soil through rooting (Bueno et al. 2013). They can even contribute to vehicle accidents (Lagos et al. 2012, Thurfjell et al. 2015). Specifically, wild boar damage crops by foraging, creating mud baths, trampling, rooting, resting, body scratching, and destroying irrigation systems. In the Ebro Sotos and Galachos Nature Reserve, wild boar fed on agricultural crops, mainly, corn Zea mays and had no effect on endangered species (e.g. birds) (Herrero et al. 2006). The Ebro Sotos and Galachos Nature Reserve sits within an agricultural landscape, where conflicts between foraging wild boar and agriculture are common. Concerns about the conservation of wildlife and the protection of natural habitats have led to policies such as the designation of protected areas (IUCN 2003), which can be hot spots of agricultural or livestock damages because they have features that make conservation a priority over some human activities (Leader-Williams & Hutton 2005, Treves 2008). Since 1993, when the Ebro Sotos and Galachos Nature Reserve was established, wild boars have caused farmers substantial losses, which have precipitated illegal hunting (e.g. snaring, night shooting, and diesel baiting). Those factors, coupled with the existing important damages, lead to an increase in research, monitoring, control, and financial compensation to farmers (Nyhus et al. 2005, Osborne & Hill 2005, Treves & Naughton-Treves 2005, Herrero et al. 2006).
Hunter records are the basis of most of the studies on wild boar control and monitoring in Europe (Vassant et al. 1987, Rosell 1998, Sodeikat & Pohlmeyer 2003, Geisser & Reyer 2004, Schley et al. 2008, Keuling et al. 2010, Scillitani et al. 2010, Amici et al. 2012, Thurfjell et al. 2013). Information on hunting efficiency is useful for identifying trends in wild boar populations and aids in the design and evaluation of management measures (Keuling et al. 2008). Attempts to reduce the damages to crops have led to the development of research programs and the dispensation of significant amounts of money, as a means of reconciling hunting and agricultural interests (Vassant et al. 1987). Furthermore, wild boar hunting data are used to quantify population demographics (Zwickel 1980, Saez-Royuela & Telleria 1988, Rosell 1998, Herrero et al. 2008, Keuling et al. 2013) and evaluate population control measures (Hone 1994), even though the effectiveness and the factors that affect its development have not been evaluated thoroughly (Keuling et al. 2010).
The aim of our study was to assess the relationship between lethal population control based on battues and its effectiveness in reducing the damage caused to crops by wild boar. In several Mediterranean countries, battues are the main technique used to hunt wild boars (Spain, Portugal and Italy), which entails using dogs to drive the animals toward stationary shooters. Although the efficiency of lethal control methods has seldom been assessed, we hypothesized that wild boar battues are efficient to reduce damages.
The core of the study area was the Ebro Sotos and Galachos Nature Reserve, a protected area along the River Ebro near Saragossa, Aragon, Spain (Fig. 1). Battues were conducted in the relict riverine habitats within a portion (approximately 100 km) of the River Ebro, which included the Ebro Sotos and Galachos Nature Reserve and adjacent areas. Most of the area is an intensively irrigated agroecosystem dedicated to corn, alfalfa Medicago sativa, winter cereals (wheat Triticum aestivum, barley Hordeum vulgare) and, to a lesser extent, fruit trees and vegetables. The irrigated land is surrounded by semi-arid habitats that have clay and gypsum soils and limited vegetation. The climate is sub-arid, with an average annual precipitation of 302 mm (range = 188-452 mm, 1994-2011), most of which falls in May-June and October-November. Between 1994 and 2011, average annual minimum and maximum temperatures were -9 [degrees]C and 43.1 [degrees]C, respectively. Reed Phragmites australis, tamarisk Tamarix africana, poplar Populus spp., willow Salix spp., and ash Fraxinus spp. predominate the small, isolated, relict riverine habitats. The largest riverine fragment is within the Ebro Sotos and Galachos Nature Reserve 1537 ha, a Special Protection Area for Birds because it is important for sedentary, migrant, and breeding birds such as the night heron Nycticorax nycticorax. In addition, it is a part of two European Sites of Community Importance. The Ebro Sotos and Galachos Nature Reserve is 40% riverine habitat, 35% agricultural land, and the remainder is water bodies, gravel, and roads.
Wild boars have been in the area since at least the 1960s and there are no physical barriers to prevent them from moving freely through the Ebro Sotos and Galachos Nature Reserve. The population has not received supplementary feeding. Crops are not fenced and farmers do not invest in wildlife damage prevention, except for agricultural pesticides, and mostly do not have insurance against damages caused by wildlife. The regional government is responsible for the management of the Ebro Sotos and Galachos Nature Reserve and has a legal obligation to pay compensation to farmers for damages that occur within the protected area. Since 2001 some roe deer Capreolus capreolus appeared in the reserve. Their density can be considered very low during the whole study period.
Material and Methods
From 1994 to 2011, we quantified crops surface and the damages surface caused by wild boar, as well as the other habitats surface in the Ebro Sotos and Galachos Nature Reserve, Spain. In that time, some artificial reforestations of non-cultivated crops and natural re-vegetation of stony areas occurred in the area, which were included in the analysis of annual habitat availability. Each year, over a two-day period in May, all field crops were quantified visually, which provided an estimate of the area covered by each crop. Farmers reported agricultural damages caused by wild boar, which were quantified by an agricultural technical engineer hired by the regional government. Those data allowed an assessment of the crop species and the areas affected. The damage reports reflected an unknown number of crop damage events caused by wild boar.
From July to February (which avoided the bird breeding period), local, volunteer, non-professional hunters performed hunting battues with dogs to cull wild boar that had been observed in an earlier tracking survey, which increased hunting success. The study area was open to the public; therefore, hunters used shotguns, only. The dogs were scent (e.g. hounds, griffons) or grip (e.g. alano) breeds. Hunters completed a questionnaire about each battue. Hunting efficiency was the number of animals culled per the number of wild boar seen during each battue.
During each battue, hunters covered 30-50 ha of natural vegetation, which provided the only persistent refuge for wild boar within the area; consequently, the culling of wild boar in those refuges had a large effective area, most of which was foraging rather than refuge habitat (Herrero et al. 2006). Battues were performed inside and in the surroundings of the protected area.
To assess the factors that influenced the number of wild boar culled, we quantified the following 16 variables: month, municipality, inside or outside the Ebro Sotos and Galachos Nature Reserve, the area that was covered during the battue, tracking or not, weather (sunny, cloudy, rain, snow), number of hunters, number of dogs, number of wild boar seen, number of wild boar seen and not killed, number of male boar, number of female boar, number of yearlings, number of piglets, number of boar of unknown age and sex, number of foxes seen, which were included in a Principal Components Analysis (PCA). The statistical analyses included non-parametric tests (Mann-Whitney, Kruskal-Wallis, and Spearman) (Zar 1996) and multivariate principal components (R Core Team 2012).
We recorded annual crop availability as the percentage of the protected area surface occupied by each crop species between 1994 and 2011. In the Ebro Sotos and Galachos Nature Reserve, during this period, the areas of corn (r2 = 0.31) and alfalfa (r2 = 0.31) crops decreased (p = 0.01), and winter cereals increased (r2 = 0.51, p < 0.001; Spearman correlation test). In almost all years, alfalfa was the main crop; in one year, sorghum Sorghum bicolor, soya Glycine max, and fescue Festuca sp. were planted in one field each. Orchards and fruit trees occupied a small proportion of the area. After three years, areas that had been revegetated artificially were considered riverine habitats.
The damages produced by wild boar in the protected area crops were quantified between 1994 and 2011. During this period, the average number of reports of damages per year was four (SD = 3.1), which affected four (SD = 2.3) farmers, 12.5 ha (SD = 7.1), 3.3% (SD = 4.2) of crops, and 1.1% (SD = 1.4) of the Ebro Sotos and Galachos Nature Reserve.
Complete information was available for 411 of the 476 battues and 200 wild boars were culled. Within the Ebro Sotos and Galachos Nature Reserve, on average, 4.6 (SD = 2) wild boar were culled during 11.6 (SD = 5.4) battues per year. Hunting efficiency was 39% and, on average, 1.5 wild boar (SD = 2) were seen per battue. At least one wild boar was seen or culled during 56% (maximum 13) and 31% (maximum 6) of the battues, respectively. On average, battues involved six hunters (SD = 2.3) and 10 (SD = 2.3) dogs.
The number of wild boar seen did not differ significantly (Mann-Whitney U test = -1.71, p = 0.087) between within (n = 161) and outside (n = 250) the Ebro Sotos and Galachos Nature Reserve. Culling pressure (number of hunters per battue) was higher (Mann-Whitney U test = -8.6, p < 0.001), but hunting efficiency was lower (Mann-Whitney U test = -3.5, p = 0.001) within than they were outside the reserve. Culling efficiency did not differ significantly among years (Kruskal-Wallis = 11.7, df = 11, p = 0.39), between the inside and outside of the protected area (Kruskal-Wallisoutside = 0, df = 11, p = 0.52; Kruskal-Wallisinside x = 5.1, df = 11, p = 0.92), or among months (Kruskal-Wallis = 15, df = 11, p = 0.17). Between 1994 and 1995 (6.7-1.4 wild boar per battue), the number of wild boar seen decreased substantially (-79%); thereafter, abundance fluctuated somewhat and, on average, the number of wild boar seen per battue was 1.4 (1.3-1.5 per battue).
Efficiency of battues that used dogs
In the PCA, number of wild boar seen during a battue, number of wild boar seen but not culled, number of dogs used in a battue, number of hunters, and number of foxes seen explained the most of the variance in the number of wild boar culled. The two principal components (MC1 and MC2) explained 84.2% of variance in the number of wild boar culled per battue (Table 1). The number of hunters and dogs that participated in the battues and the number of wild boar that were seen (and potentially, culled) was positively correlated. In addition, the number of wild boar seem was higher when the numbers of hunters and dogs per battue were higher too (Table 2).
Culling and damages
Between 1994 and 2011, we observed a positive relation between damages (ha), number of battues, and wild boar seen per battue in the Ebro Sotos and Galachos Nature Reserve. The number of battues and the area of damaged crops (Table 3) were inversely correlated (Spearman correlation coefficient: r = -0.683, p = 0.002, n = 18), which suggests that an increase in battues led to a reduction in agricultural damages.
Battues are reliable for estimating wild boar abundance (Saez-Royuela & Telleria 1988), particularly, if trained dogs are used (Zwickel 1980). The culling efficiency of the battues in the Ebro Sotos and Galachos Nature Reserve was within the range of those reported in similar studies elsewhere in Iberia, even though the number of hunters per battue in our study was much lower than the number in other studies (Rosell 1998, Keulin et al. 2008). The dense vegetation in the Ebro Sotos and Galachos Nature Reserve, which existed because the restriction on the use of riparian habitats by livestock is most strongly enforced within the protected area, might have constrained culling efficiency. Dense vegetation reduces shooting accuracy and, because of the ban against the use of rifles, hunters cannot shoot from long distances, which increase the difficulty for hunters to cull wild boar within the reserve. Battues with dogs were efficient in reducing wild boar populations and the crop damages that they can cause. Typically, wild boars abandon beaten areas, temporally (Sodeikat & Pohlmeyer 2003, Thurfjell et al. 2013) or permanently, if hunting pressure is high (Scillitani et al. 2010). The number of hunters and dogs is crucial to the success of the cull (Sodeikat & Pohlmeyer 2003), as previously demonstrated by Rosell (1998). Although the Ebro Sotos and Galachos Nature Reserve has characteristics that made it highly vulnerable to agricultural damages caused by wildlife, damages were limited in the first part of the control period, but increased after the control was relaxed, which underscores the benefits of systematic control of the wild boar population. The overall impact of the damages was highest in the relaxed periods, which had a significant impact because of a delay in the disbursement of financial compensation. In the region, agricultural damages are persistent, inevitable, and require close attention because of their economic impact and the perceptions of the affected farmers, even if, in this case, they can be classified as high risk, but with a low vulnerability of farmers (Naughton-Treves & Treves 2005). Despite changes in the annual crop composition and specific trends of some crops, battues succeeded in reducing the wild boar population and damages caused to crops.
Several interrelated factors underlie the conflict in the Ebro Sotos and Galachos Nature Reserve. The abundance of agricultural land inside the protected area, particularly, the availability of corn, which is a preferred food for wild boar (Herrero et al. 2006), makes the area highly attractive to wild boar. An increase in the amount of corn grown is a factor in the expansion of wild boar populations in some areas of Europe (Neet 1995). In addition, at the beginning of the control program in the Ebro Sotos and Galachos Nature Reserve, financial compensation for damages was paid quickly, however, in some years, compensation was delayed, which increased the dissatisfaction of the farmers. Crop damages caused by wildlife contribute to a negative perception of wildlife and protected areas among farmers, and financial compensation helps to mitigate this perception (Osborne & Hill 2005). Wildlife population control, which reduces the tensions on farmers, has been less common, and has been followed by increases in the wild boar population and agricultural damages. Lethal population control improves the perceptions and attitudes of farmers and others towards the protected area and its wildlife, and lessens the conflict between humans and the species that causes the damage (Leader-Williams & Hutton 2005), even if there is limited evidence that lethal or non-lethal population control reduces significantly the damages caused by wildlife to livestock (depredation) or crops (Osborne & Hill 2005, Treves & Naughton-Treves 2005, Woodroffe et al. 2005). The conditions in the Ebro Sotos and Galachos Nature Reserve make it highly vulnerable to damages by wild boar: following extirpation, wild boar repopulate the area; battues are the only active measure to prevent damage, crops provide an unlimited supply of high-quality food (Herrero et al. 2006) and a large refuge area, which was the largest along the river within at least 100 km. Nyhus et al. (2005) suggested that financial compensation to farmers, along with proactive measures such as population control and incentives to change management are the only means of mitigating the conflict between man and wildlife. Thus, the problem is best addressed by the timely distribution of financial compensation, implementing effective population control; e.g. culling using battues (Geisser & Reyer 2004) and stalking and improving agricultural management practices; e.g. using electric fences to protect crops (Geisser & Reyer 2004, Honda et al. 2009) and growing alternative crops (Schley et al. 2008). This letal control experience decreases the conflict of wild boar damage to crops and supports the existence of the protected area and its environmental values.
This research was part of a long-term culling program in the Ebro Sotos and Galachos Nature Reserve that was implemented by the Regional Government of Aragon, which provided financial support. In addition, we thank the hunters, rangers, and technicians for their contributions to this study. Bruce MacWhirter improved the English.
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(1) Ega Wildlife Consultants, Sierra de Vicort 31 1[degrees]A, E-50003 Zaragoza, Spain; e-mail: email@example.com
(2) Area of Ecology, Department of Agricultural and Environmental Sciences, Technical School, University of Zaragoza, E-22071 Huesca, Spain; e-mail: firstname.lastname@example.org
(3) Pyrenean Institute for Ecology, Consejo Superior de Investigaciones Cientificas, Avda, Nuestra Senora de la Victoria, s/n, E-22700 Jaca, Spain; e-mail: email@example.com
Received 11 February 2016; Accepted 14 June 2016
Table 1. The PCA, variance and the importance of the culling success of wild boar battues (n = 453) conducted by volunteer hunters with dogs in the Ebro Sotos and Galachos Nature Reserve, Aragon, Spain, between 1994-2011. Main components MC1 MC2 MC3 MC4 Component variances 1.9372 1.4318 0.5322 0.0988 Standard deviation 1.3918 1.1966 0.7295 0.3173 Variance proportion 0.4843 0.3579 0.1330 0.0247 Accumulated proportion 0.4843 0.8422 0.9753 1.0000 Table 2. Correlations between variables in the PCA of the culling success of wild boar battues (n = 453) conducted by volunteer hunters with dogs in the Ebro Sotos and Galachos Nature Reserve, Aragon, Spain, between 1994-2011. Main components MC1 MC2 MC3 MC4 Total wild boar seen 0.6841 0.1734 0.0435 0.7071 Wild boar seen and not culled 0.6803 0.1942 0.0142 -0.7065 Number of dogs 0.2109 -0.6712 -0.7106 0.0043 Number of hunters 0.1573 -0.6940 0.7021 -0.0252 Table 3. Damages, number of battues, and wild boar seen per battue in the Ebro Sotos and Galachos Nature Reserve, Aragon, Spain, between 1994 and 2011. Year Battues Wild boar per battue Damages (ha) 1994 6 6.7 3.6 1995 40 1.4 6.5 1996 20 1.1 8.2 1997 28 1.6 1.3 1998 36 1.3 1.1 1999 32 1.6 0.5 2000 28 1.7 0.5 2001 22 1.0 0.7 2002 28 1.3 0.4 2003 14 3.3 2.2 2004 26 1.1 1.9 2005 8 1.5 0 2006 0 0 14.1 2007 2 1.5 19.0 2008 1 1.0 43.3 2009 0 0 18.2 2010 4 5.7 25.3 2011 4 9.2 19.0
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|Author:||Gimenez-Anaya, Alberto; Herrero, Juan; Garcia-Serrano, Alicia; Garcia-Gonzalez, Ricardo; Prada, Carl|
|Date:||Nov 1, 2016|
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