Successful Deer Management in Scotland Requires Less Conflict Not More

Deer Management: A Conservation Conflict

Scotland's thriving wild deer populations, like those elsewhere in Europe and North America, are at the center of a persistent conservation conflict. This conflict centers mostly around red deer (Cervus elaphus), Scotland's most ecologically, economically, and culturally important deer species, but also concerns roe deer (Capreolus capreolus) (MacMillan and Phillip, 2010; Pepper et al., 2019). In the absence of native large carnivores, Scotland's deer populations have steadily expanded for decades as disease, starvation, road kills, and stalking (shooting) have failed to keep numbers in check. Expanding deer populations are associated with ecological and socio-economic costs, and conservationists are calling for a drastic increase in the number of deer culled (shot) to address associated negative impacts (Scottish Environment, 2020).

Deer can bring environmental and social benefits to rural Scotland through seed dispersal, creation of microsites for seed germination, job creation, income from hunting and tourism, and their aesthetic and cultural appeal (Gill and Beardall, 2001; PACEC, 2006; Dandy et al., 2009; Shaw et al., 2010). However, large deer populations can negatively affect vegetation dynamics, community composition, biodiversity and ecosystem process, and threaten human health and the economy (Gill and Beardall, 2001; Côté et al., 2004; MacMillan and Phillip, 2008; Glenn et al., 2019). Under high deer densities, many of Scotland's native tree species, such as Scots pine (Pinus sylvestris), rowan (Sorbus aucuparia), juniper (Juniperus communis), and dwarf birch (Betula nana) are failing to regenerate (Miller et al., 1982; Scott, 2001; Tanentzap et al., 2013; Rao, 2017). Understory shrubs, such as blaeberry (Vaccinium myrtillus), are consistently cropped, generating knock-on effects for the species that rely on them (Baines et al., 1994). Deer impacts extend beyond direct consumption of primary producers. Deer browsing on downy birch (Betula pubescens) impacts nutrient cycling by slowing decomposition of leaf litter (Harrison and Bardgett, 2003). Deer also affect carbon cycles by reducing plant biomass available for photosynthesis and influencing litter decomposition (Hirst, 2021).

There is strong evidence that increases in deer populations are facilitating the spread of ticks, such as Ixodes ricinus, the most important vector for zoonotic pathogens in Europe, including Lyme disease (Kirby et al., 2004; Scharlemann et al., 2008; Gilbert et al., 2012). Expanding deer numbers are also associated with an increase in deer-vehicle collisions, costing millions of pounds a year in Scotland, and causing serious injuries and fatalities to both humans and deer (Putman, 2012). Deer can significantly damage grasses, cereal crops, and orchards and the forestry sector must spend millions of pounds annually on deer management, including culling and fencing, to enable forest regeneration (Pepper et al., 2019).

Despite known socio-ecological costs associated with high deer densities, attempts to create a sustainable system of deer management in Scotland have largely been unsuccessful. At the heart of this problem are competing values and objectives among those responsible for deer management, as landowners, deer stalkers, conservationists, and government officials have, for decades, been unable to reach consensus over what successful deer management in Scotland should look like. Although the Scottish Government has legislative responsibility for ensuring the sustainable management of deer, landowners, who own and control hunting rights, often have objectives that can be in tension with broader public interests (MacMillan and Leitch, 2008; Pepper et al., 2019). NatureScot, the government agency responsible for enforcing deer legislation, has legal powers to enforce deer culling, but relies largely on voluntary cooperation from landowners to engage in deer culls. Individual landowners set their own cull targets, but if they fail to meet targets, NatureScot does not sanction them. With extensive areas of the Scottish countryside managed as private deer stalking estates, many landowners have economic and cultural incentives to maximize deer abundance, particularly of red deer stags (males) for trophy hunting (MacMillan and Leitch, 2008; Glass et al., 2013, 2019). Consequently, many landowners set cull targets too low to achieve sustainable deer numbers and impacts (Albon et al., 2017; Pepper et al., 2019). Those who voluntary increase cull levels to address the socio-ecological impacts of deer often fail to impact deer at the landscape level where neighboring properties pursue alternative objectives (Albon et al., 2017; Pepper et al., 2019).

In the absence of clear and agreed socio-ecological benchmarks for success, those involved in deer management lack effective and reliable evaluation metrics. At present, management outcomes are evaluated largely based on deer data, such as density and cull numbers, at the individual property level. However, cull numbers and population density alone are often poor predictors of the impacts of deer at a landscape level because of feedbacks among deer populations, altered vegetation communities, ecosystem properties, and the presence of other stressors (Putman et al., 2011; Tanentzap et al., 2012, 2013; Blossey et al., 2017). Some landowners do assess ecological impacts of deer on their properties, but assessment protocols often vary, making it difficult to make meaningful comparisons and conclusions at landscape scales (Campbell and Marchbank, 2013; Armstrong and Holl, 2015). Furthermore, assessment data are often not made publicly available, with evidence of deer impacts on rare and sensitive species and ecosystems, such as aspen, peatlands, and montane woodlands, particularly scarce. Evidence of deer impacts therefore fails to provide an effective tool for guiding management and policy decisions beyond the very local scale.

A Vision for the Future: Co-Producing a Definition of Success

In recent years, the Scottish Government has tried to encourage landowners to increase the number of deer culled each year. However, despite an increase in the number of deer culled in recent years, deer densities continue to be too high to achieve positive socio-ecological outcomes across much of Scotland (Albon et al., 2017; Pepper et al., 2019). Incentive based policies, such as culling or venison subsidies, taxing landowners who do not meet targets, “tradeable obligations” that would oblige landowners to shoot deer but allow them to trade their “obligations” with other estates, or a “cull approval system,” requiring landowners to obtain approval for their planned cull prior to being given hunting permits, could encourage landowners to shoot more deer (MacMillan, 2004; MacMillan et al., 2010; Pepper et al., 2019). However, policy changes that fail to address the underlying conflicting values and agendas of affected stakeholders and power relations between them could exacerbate tensions between these groups and undermine potential for cooperation over deer, particularly among some landowners and deer stalking communities (MacMillan, 2004; Hill, 2021). In the past, reluctance to create political fall-out has prevented successive public agencies responsible for deer management from exercising existing powers to enter properties and cull deer in order to protect Scotland's natural heritage (MacMillan, 2004).

Sustainable solutions to the deer crisis must account for deep histories of stakeholder conflict over deer (Hobbs, 2009; Phillip et al., 2009; MacMillan et al., 2010; Davies and White, 2012). This will require greater clarity and, where possible, consensus among relevant stakeholder groups regarding desirable ecological and social outcomes from deer management (Ceauşu et al., 2018). Here we refrain from making specific recommendations on how to solve the deer crisis in Scotland, because such recommendations should emerge from a deliberative process through which a broad range of stakeholders, including stalkers, landowners, scientists, conservationists, and government officials, can co-produce a definition of successful deer management (Redpath et al., 2015). To be effective, this definition should include objectives for ecological, socioeconomic, and human health outcomes that are clearly articulated, informed by best available evidence, and perceived to be legitimate by affected stakeholders (Forstchen and Smith, 2014; Hare et al., 2017; Bennett and Satterfield, 2018; Pomeranz et al., 2021). Although objectives are unlikely to fully satisfy all affected stakeholders all of the time, they will be more legitimate, and therefore acceptable, if stakeholders and the public more generally, perceive the process of identifying them to be fair, and can accept that objectives reflect trade-offs between multiple competing perspectives, interests, and values (Forstchen and Smith, 2014; Ceauşu et al., 2018; Pomeranz and Stedman, 2020). When subsequent deer management activities make demonstrable progress toward these objectives, those activities can be considered successful.

Adaptive, evidence-based deer management will require consistent, reliable metrics, and protocols for evaluating whether management options have successfully achieved articulated objectives. Repeated and systematic collection of socio-ecological deer impacts (e.g., incidences of Lyme disease and deer-vehicle collision, browse rates, etc.) will need to complement data collected on deer abundance and cull numbers as metrics for evaluating success. These metrics will enable decision-makers to review and adjust, where necessary, deer management and policy decisions based on deer impacts. Data collected across ecological and management contexts will need to be properly collated and synthesized at a regional and national scale to serve as an effective tool for informing management and policy-decisions across the wider landscape.

Lynx Reintroduction: Solution or Illusion?

Some environmental groups argue for reintroduction of extirpated native large carnivores, particularly Eurasian lynx (Lynx lynx) (hereafter “lynx”), claiming that they would help reduce deer numbers and negative impacts of deer (Amos, 2021). Although lynx might be the least controversial of Scotland's native but extirpated large carnivores, lynx reintroduction could exacerbate stakeholder conflicts, particularly among sheep farmers, and those involved in deer hunting (Odden et al., 2008; Breitenmoser et al., 2010; van Eeden et al., 2018). While there are many ecological and economic arguments for and against reintroducing lynx to Scotland, some pro-lynx interests emphasize the capacity of lynx to help solve Scotland's deer crisis through directly consuming deer and indirectly benefiting plant species that deer eat or trample. Whether lynx reintroduction to Scotland would help achieve positive socio-ecological objectives for deer management would depend on the impact of lynx on deer numbers, deer impacts, and enduring social conflicts over deer. Arguments that overstate potential impacts of lynx on deer could generate unrealistic and unachievable expectations.

Evidence from elsewhere in Europe suggest that lynx would do little to reduce red deer numbers in Scotland. Across their European range, lynx have a strong association to woodland habitat, making it unlikely that they would predate on red deer in Scotland, which frequently occupy open hill habitats (Breitenmoser et al., 2000; Jȩdrzejewski et al., 2002; Albon et al., 2017). However, although lynx predation on red deer is usually focused on calves, Scottish red deer are smaller than those in mainland Europe and might therefore be more manageable prey for lynx where they occupy woodland habitat (Mitchell et al., 1977). Nevertheless, throughout their European range, lynx display a strong preference for hunting roe deer (Nowicki, 1997). Lynx can effectively limit roe deer populations, particularly in harsh climates, and can significantly increase kill rates and concentration of kills when encountering abundant and potentially naïve prey (Breitenmoser and Haller, 1993; Jȩdrzejewski et al., 1993; Okarma et al., 1997; Melis et al., 2009, 2010; Andrén and Liberg, 2015; Dula and Krofel, 2020). However, this does not necessarily predict lynx-roe deer dynamics in Scotland. The extent to which a lynx reintroduction could reduce Scotland's roe deer populations in the long term is not well-understood.

Lynx ability to bring about a vegetation response through consumptive and non-consumptive impacts on deer has been poorly studied. Existing evidence of the behavioral responses of roe deer to the presence of lynx suggests lynx may have some non-consumptive effects on deer behavior, particularly when in immediate risk of predation, but whether this can translate to a vegetation response requires further study (Samelius et al., 2013; Dupke et al., 2017; Eccard et al., 2017; Gehr et al., 2018; van Beeck Calkoen et al., 2021). Detailed monitoring of ungulate population densities, behavior and their impact on vegetation throughout all phases of a potential reintroduction to Scotland would be essential for setting realistic objectives and evaluating progress toward them. This holds true for anywhere that carnivore reintroductions are being explored as a mechanism for reducing or controlling ungulate populations.

Although we cannot fully predict the potential impacts of lynx in Scotland, on the strength of existing evidence, it does not appear that lynx reintroduction would provide a silver bullet for overcoming Scotland's deer crisis, though it may be helpful. We are concerned that outsized expectations and promises that lynx reintroduction would suffice to solve the deer crisis could undermine, rather than support, progress toward identifying, and meeting broader conservation objectives, including those associated with deer. With many of the stakeholders involved in deer management likely to be those also most affected by lynx reintroduction (e.g., hunters, conservationists, and rural landowners), any eventual reintroduction predicated on promises of positive ecological impacts could exacerbate fragile cooperation among deer stakeholders if such impacts do not materialize. Such an overpromising but underachieving scenario could also undermine trust in conservation institutions (Crowley et al., 2017). Conflict with hunters over the perceived threat posed to roe deer by lynx is a significant driver of illegal killing of lynx in Europe, and with a large amount of privately-owned land in Scotland, poaching could be a significant threat to any reintroduced population of lynx (Breitenmoser et al., 2010). Though predation on game birds by lynx is relatively uncommon in areas of high ungulate availability, populations of game birds are maintained at high densities across much of Scotland for sport hunting, and perceived impacts among hunters could be another source of tension (Nowicki, 1997; Aebischer, 2019).

There are other arguments for the reintroduction of lynx to Scotland beyond their impacts on deer. Restoring an extirpated native species could be considered a worthwhile conservation endeavor in its own right, as long as it is socially acceptable and ecologically viable. Through selective hunting of deer in poor condition, lynx could maintain healthy deer populations, they could help limit numbers of mesopredators such as foxes, and provide economic benefits to rural areas through ecotourism (Helldin et al., 2006; Hetherington, 2006; Krofel et al., 2014). Any eventual lynx reintroduction would need to consider the likelihood of these impacts as part of a larger effort to identify appropriate ecological and social objectives for defining and evaluating success. Just as with the deer crisis, we recommend a deliberative process to identify relevant ecological and social benchmarks, clear indicators of success and accurate assessment tools. This process would help gauge the overall acceptability of lynx reintroduction to Scotland and identify social conflicts that may arise and how to mitigate them.

A Way Forward

Conservation conflicts often arise when stakeholders perceive conservation objectives to threaten other objectives, such as livelihood objectives (Redpath et al., 2015). They can also arise when stakeholders perceive such objectives to be based on external values imposed upon them. In Scotland, perceptions, values, and expectations regarding deer management are multi-faceted, deep rooted, and reflect cultures, traditions, and preferences that extend far beyond deer (Hobbs, 2009; MacMillan et al., 2010; Hare et al., 2021). We anticipate that overcoming Scotland's deer crisis will require a substantial increase in the number of deer culled as part of a broader solution that could include lynx reintroduction. However, opposition to these changes, and conservation and rewilding more generally, might have more to do with perceptions of illegitimacy and distrust toward conservationists, rather than any specific conservation aims and objectives (MacMillan and Leitch, 2008). Attempts to establish a sustainable system of deer management in Scotland that fail to address these underlying tensions seem unlikely to succeed. We envision a process for co-producing definitions of success and associated objectives and metrics that respects and sensitively accounts for these differences. We hope this process will pave the way toward more sustainable deer management institutions in Scotland, which are grounded in evidence and prioritize positive impacts on Scotland's ecosystems and the people who depend on them.

Data Availability Statement

The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding author/s.

Author Contributions

HK, DH, BB, and MD conceived the manuscript. HK led the writing. All authors contributed to formulating the arguments, writing, and reviewing drafts.

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's Note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

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