Introduction

Limited resources available to fund action toward society's numerous development and conservation goals can lead to conflict when investment is seen as a zero-sum game in which supporting one set of goals detracts from the other (Chen and Pensini 2024; Baker et al. 2017; Galvani et al. 2016). The misperception that investing in conservation detracts from society's other goals is particularly pervasive. However, the targets of conservation efforts are integral components of socioenvironmental systems in which the fates of populations, species, ecosystems, and global systems that include human society are intertwined. Consequently, implementing conservation actions targeting any biological level can yield multiple co-benefits to all parts of these systems, including human society. Identifying and articulating these conservation co-benefits for economic growth, public health, education, and culture can amplify and sustain support for conservation actions while also potentially creating additional co-benefits that align with society's development goals. Biodiversity serves as the central focus of several multilateral environmental agreements (MEAs), which delineate targets towards globally shared conservation goals (Ferraro and Failler 2024). Given that species are the currency of biodiversity, species-level conservation provides an effective way to make clear, measurable contributions to established shared goals. Here, we map how species-level conservation actions focused on bats align with the Global Biodiversity Framework (GBF) targets (CBD 2022) and contribute to the United Nations Sustainable Development Goals (UNSDGs) (UN 2015) in the form of co-benefits.

Bat conservation initiatives are typically designed to protect bat species and their habitats, with any additional benefits resulting from these initiatives considered positive externalities of bat conservation goals. These externalities, instead, can be intentionally managed as co-benefits spanning ecological, social, economic, and health sectors. For instance, protecting bats and their habitats supports ecosystem service provision (Ramírez-Fráncel et al. 2022; Kunz et al. 2011) and reduces contact and conflict between bats and humans, thereby reducing the risk of pathogen spillover events (Plowright et al. 2024). Conservation initiatives often foster partnerships with local stakeholders, leading to knowledge transfer, increased technical capacity, and mobilization of financial resources (Pretty and Smith 2004). Explicitly identifying how bat conservation efforts contribute to socioenvironmental systems could enhance the success of conservation initiatives and render conservation actions more effective at supporting society's economic and social needs.

Bats are an ecologically diverse taxonomic group composed of over 1470 recognized species (Simmons and Cirranello 2024) that have varying conservation needs, yet all require access to high-quality resources to meet their needs during foraging, roosting, commuting, and for some species, migrating (Frick et al. 2024; Frick, Kingston, and Flanders 2020). Of the 1390 bat species currently assessed by the International Union for Conservation of Nature (IUCN), 35% are ranked as vulnerable, endangered, critically endangered, or data-deficient. Of the species assessed, 77% have unknown or declining population trends driven by habitat loss, climate change, invasive species and disease, wind turbine collisions, pollution, and hunting, among other threats (Frick, Kingston, and Flanders 2020; IUCN 2023). Meeting the conservation needs of bats through targeted threat reduction actions or broad-scale habitat protection and restoration efforts confers an umbrella species-type of protection to the ecosystems that bats inhabit and the species they co-occur with, ultimately extending these contributions to people who interact with bats and share their ecosystems (Plowright et al. 2024, IUCN SSC 2014).

Bats provide benefits to people through their contribution to three main categories of ecosystem services (Kachler et al. 2023). Regulating services result from bats supporting healthy ecosystem functioning and enhancing social and economic well-being through processes such as pest consumption, pollination, seed dispersal, and nutrient cycling (Ramírez-Fráncel et al. 2022; Tuneu-Corral et al. 2023). Material services provided by bats include products such as guano and meat. Guano can be used as an agricultural fertilizer, while bat meat is consumed in some regions as a protein source when access to other sources is limited or as a luxury food (Sakoui et al. 2020; Latinne et al. 2020; Mildenstein, Tanshi, and Racey 2016). However, unsustainable guano harvesting can disrupt bat colonies and increase the risk of pathogen spillover, and hunting bats for consumption poses significant threats to several bat species and can also lead to pathogen transmission (Osofsky et al. 2023). Nonmaterial services contribute to human well-being in the form of nature enjoyment, which can also be monetized, for example, with bat-emergence tourism (Osofsky et al. 2023; Bagstad and Wiederholt 2013).

Bat conservation initiatives can yield additional co-benefits for people through a broad range of actions that manage bat–human contact, coordinate societal change, and foster understanding and awareness of bats. These benefits are especially relevant to local communities that live near bats. Often, identifying measures that increase safety for bats can have a positive impact on public health, such as raising awareness about how extracting guano sustainably can reduce human exposure to pathogens (IUCN SSC 2014; Mildenstein, Tanshi, and Racey 2016). Effective bat conservation programs often engage with community members, facilitating skills transfer and work experience (Frick et al. 2024). Protecting bat-foraging habitats can increase ecosystem resilience, directly impacting local economic opportunities and well-being, and minimize risk for future pathogen transmission (Plowright et al. 2024). For example, sustainable agricultural practices that protect agave flowers for nectarivorous bats conserve the genetic diversity and survival of agaves, reduce erosion and inefficient water use, and promote sustainability within the agave industry (Lear et al. 2024).

The economic, social, and environmental benefits stemming from healthy bat populations and the actions used to protect them already make meaningful contributions to MEAs that address environmental challenges while contributing to sustainable development. Our goal is to delineate how bat conservation contributes to global biodiversity and sustainability efforts, thereby increasing support for bats and our shared socioenvironmental systems. Thus, we draw from both the GBF and the UNSDGs to measure bat conservation's impact on these systems by using goals, targets, and language already resonating with stakeholders across global, national, and community-level scales. Specifically, we examine how bat ecosystem services and conservation actions align with the GBF and contribute to UNSDG targets.

Mapping the Connectivity Between Bat Conservation, GBF Targets, and UNSDGs Targets

Mapping the connectivity between bat conservation, the GBF targets, and the UNSDG targets can help identify how conservation efforts contribute to broader sustainability goals. The GBF includes 23 specific targets developed to transform society's relationship with biodiversity by drawing from UNSDG targets related to ending poverty, hunger, and inequity, protecting the world's natural capital, and fostering health, peace, education, and technological innovation (GBF Section A.3). Similarly, the UNSDGs include 17 goals that broadly address society's sustainable development, addressing food security, public health, education, equity, governance, and biodiversity, with 169 specific targets contributing to these goals.

We defined four comprehensive bat conservation goals aimed at protecting bats and their habitats (Supporting Information, Table S1). These goals encompass protecting bat populations, reducing anthropogenic threats to bats, strengthening research and technical capacity for bat conservation, and raising awareness of the conservation importance of bats (Table 1).

TABLE 1 Goals and targets of bat conservation efforts. Targets are representative of the type of conservation actions implemented under each goal. Table S2 outlines the ecosystem services that result from achieving the goal of “Protect bat populations.”Table S3 outlines examples of bat conservation actions grouped under the goals of “Reduce anthropogenic threats to bat populations,” “Strengthen research and technical capacity for bat conservation,” and “Raise awareness on conservation importance of bats.”

To represent these goals and illustrate their alignment with GBF targets, we used five types of ecosystem services derived from bats and 36 examples of bat conservation actions (Supporting Information,Tables S2 and S3). While protecting bat populations is a broad goal, we assume that the outcomes of this goal ensure the provision of ecosystem services derived from bats (Table S2). Bat conservation actions were compiled by Bat Conservation International experts based on past, present, or prospective projects as representative of actions that are implementable by conservation organizations as part of nature-based solutions. Although this list is not comprehensive, it provides a conservative representation of how bat conservation could contribute to MEA targets (Table S2 and S3). We defined co-benefits as the contributions to specific UNSDG targets that result from ecosystem services and bat conservation actions (Table S2 and S3).

To ensure effective biodiversity conservation strategies, it is essential to measure the outcomes of actions and progress toward meeting targets. As of March 2024, the GBF is still developing indicators for use at national levels and at more localized levels of action. The UNSDGs have clear target-specific indicators, but these indicators are not relevant to assessing bat conservation's impact on targets. Here, we identified alternative indicators relevant to the scale of bat conservation that can be used to assess how bat conservation actions contribute to UNSDG targets (Tables S2 and S3).

The bat conservation actions and ecosystem services we identified contribute to at least one GBF target and one UNSDG target, enabling us to map pathways that illustrate how bat conservation aligns with both frameworks (Figure 1). Ensuring the provision of ecosystem services derived from bats through the protection of bat populations directly aligns with GBF targets 4, 7, 11, and 12, which emphasize protecting biodiversity, reducing pollution, restoring, maintaining, and enhancing nature's contributions to people, and enhancing green spaces for people and biodiversity (Figure 1). These ecosystem services further contribute to 12 UNSDG targets focused on reducing hunger, improving human well-being, promoting sustainable communities, and protecting biodiversity (Figure 1; Table S2).

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Bat conservation actions representing the goals of reducing threats, strengthening capacity, and raising conservation awareness align with 17 GBF targets categorized under the GBF's three overarching themes: reducing threats to biodiversity, meeting people's needs through sustainable use and benefit-sharing, and tools and solutions for implementation and mainstreaming. These bat conservation actions could generate co-benefits that contribute to 46 targets spanning 14 UNSDGs (Figure 1; Table S3). Specifically, reducing anthropogenic threats to bats could contribute to targets addressing improved human health and sanitation (UNSDGs 2, 3, 6), economic growth (UNSDG 1, 4, 8, 9), sustainable communities, consumption, and production (UNSDGs 11, 12), climate change mitigation (UNSDG 7, 13), and biodiversity protection (UNSDGs 14, 15). Similarly, strengthening research and technical capacity for bat conservation could contribute to targets focused on improving human health and sanitation (UNSDGs 2, 3, 6), economic growth (UNSDG 1, 4, 8, 9), climate change mitigation (UNSDG 7), sustainable consumption and production (UNSDG 12), biodiversity protection (UNSDG 15), and global partnerships (UNSDG 17). Finally, raising awareness of the conservation importance of bats could contribute to targets centered on promoting sustainable communities, consumption, and production (UNSDGs 11, 12).

Application to Special Areas of Bat Conservation

Mapping the connectivity between bat conservation goals, biodiversity targets, and sustainability targets allows a more concrete understanding of consistent relationships and processes that occur within socioenvironmental systems, including bats, people, and ecosystems (Figure 1). By focusing on specific species, habitats, or resources used by bats, conservation initiatives can contribute to a consistent set of targets. Conservation managers can leverage this mapping to identify collaboration opportunities, leading to shared resources, skills, and knowledge. Cave ecosystems and bat-foraging habitats are examples of habitats for which bat conservation is highly dependent on the outcomes of interactions with people. Initiatives focusing on these systems, particularly those fostering collaborations across sectors, can explicitly identify targets in their project design and facilitate beneficial conservation outcomes supporting economic and social needs. We illustrate this connectivity by outlining relevant GBF and UNSDG targets for cave ecosystems (Box 1) and bat-foraging habitats (Box 2).

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Harnessing Co-Benefits to Offset Costs

Far from being at odds, the protection of biodiversity and the achievement of sustainable development objectives can be harmoniously aligned, and indeed, protecting biodiversity creates added value for diverse societal goals. Yet, there are some contexts in which conflict with other conservation or sustainable development objectives appears to occur. Balancing these potentially conflicting goals and outcomes is feasible, and identifying the co-benefits of conservation actions offers valuable perspective when these situations arise. For example, while slowing climate change and mitigating biodiversity loss are internationally recognized conservation goals (CBD 2022; UN 2015), bat collisions with wind energy turbines cause hundreds of thousands of bat fatalities globally each year and cannot be ignored (Voigt et al. 2024). Working with the wind energy industry and its financial lenders on identifying and implementing measures that effectively reduce bat fatalities at wind turbines is crucial for bat conservation globally (IFC 2023). This may initially appear contradictory to wind energy success, but minimizing bat fatalities at wind turbines while maximizing energy production would help wind energy become a more sustainable and scalable form of renewable energy, contributing to nine UNSDG targets (Table S2).

Although conservation measures can spark a cascade of socioeconomic benefits, sometimes short-term costs can occur in the process of achieving long-term goals. In some cases, communities reliant on hunting bats for consumption or income may experience short-term costs when transitioning away from this practice to ensure sustainable long-term benefits. Responding to this conflict is crucial to conservation success and sustainability, and doing so also ensures that costs and benefits are not inequitably distributed across all parties (de Wit et al. 2022). Such responses involve co-creating integrative solutions with local communities by practicing active listening, trust-building, and bidirectional learning (Staddon et al. 2023). The co-benefits identified within the intricate linkages in a socioeconomic system can highlight valid ways to compensate those stakeholders facing short-term costs, transforming a potential conflict into a multi-faceted opportunity. For instance, transitioning to alternative sources of protein or income can mitigate conservation conflicts and reduce the risk of pathogen spillover (Plowright et al. 2024). Introducing initiatives like preserving natural heritage sites, developing ecotourism activities, and employing community members as stewards could help offset costs. In addition, raising awareness about public health risks and implementing ecological countermeasures to prevent spillover, such as protecting bat foraging sites and reducing human encroachment into bat habitats, offers a proactive approach to conservation that resonates with broader societal objectives (Plowright et al. 2024).

Conclusion: A Species-Level Conservation Strategy

Understanding the intricate connections between bats, people, and their shared ecosystems is critical for effective conservation efforts. Bat populations, communities, and ecosystems each face serious challenges, and due to the abundant interactions and processes that connect their fates, species- or location-specific threats and challenges become shared concerns for the entire system. The processes that link these system components can be harnessed for sharing the positive impact of actions to overcome threats and meet challenging goals.

Bat conservation initiatives that align with MEAs, such as the GBF and the UNSDGs, can increase global awareness of bats' importance, increasing support for bat conservation and benefiting society at large. By explicitly articulating these connections, conservation programs can better address biodiversity and sustainability targets, amplifying their impact. This approach can be applied to any species-level conservation program. Species are the currency of biodiversity, and thus, pathways between species conservation goals, biodiversity targets, and sustainability targets are easily recognized, connected, and measurable. As species are part of socioenvironmental biological systems, the shared benefits span all levels of biological organization, including human society.

Acknowledgments

We thank Michael Daulton and Kevin Pierson for fruitful discussion and input on these ideas.

Data Availability Statement

The data that supports the findings of this study are available in the Supporting Information of this article.