key: cord-0718964-yx3wtn67 authors: Gillespie, Thomas R.; Jones, Kate E.; Dobson, Andrew P.; Clennon, Julie A.; Pascual, Mercedes title: COVID‐Clarity demands unification of health and environmental policy date: 2021-01-28 journal: Glob Chang Biol DOI: 10.1111/gcb.15508 sha: 6019b875d3218589f021d6abf2bf96c372789494 doc_id: 718964 cord_uid: yx3wtn67 Spillover of novel pathogens from wildlife to people, such as the virus responsible for the COVID‐19 pandemic, is increasing and this trend is most strongly associated with tropical deforestation driven by agricultural expansion. This same process is eroding natural capital, reducing forest‐associated health co‐benefits, and accelerating climate change. Protecting and promoting tropical forests is one of the most immediate steps we can take to simultaneously mitigate climate change while reducing the risk of future pandemics; however, success in this undertaking will require greater connectivity of policy initiatives from local to global, as well as unification of health and environmental policy.[Image: see text] rural to predominantly urban living. Despite this concentration of human populations into cities, our activities now impact 75% of the planet's terrestrial land surface (Venter et al., 2016) . Agriculture dominates this impact, with crop and livestock production now covering over one-third of the globe, with projections of beyond half the Earth being used for agriculture if current trends continue unabated (Mehrabi et al., 2018) . In light of this, what urban dwellers choose to eat and how their needs are supplied will largely shape food and land-use systems. We must ensure that these choices will not further degrade natural systems in ways that promote natural and economic disasters by accelerating climate change and zoonotic disease spillover. Protecting and promoting tropical forests is one of the most immediate steps we can take to simultaneously mitigate climate change while reducing the risk of future pandemics. Pathogen spillover is increasing and this trend is most strongly associated with agricultural drivers (Rohr et al., 2019) . Agricultural expansion leads to shrinking and fragmentation of wildlife habitat, facilitating pathogen spillover by (1) altering community composition in ways that may amplify pathogen hosts and vectors, (2) increasing the interface between wildlife habitat and human habitation, and (3) promoting novel wildlife behaviors often related to seeking new food sources as their longstanding natural sources disappear or become less dependable (Faust et al., 2018; Gibb et al., 2020; Gillespie & Chapman, 2006) . Destruction of tropical forests hits both columns of the climate change ledger: burning forests adds CO 2 to the atmosphere, while concomitantly reducing the planet's potential to remove the excess of CO 2 currently circulating in the atmosphere (Bonnie et al., 2000; Kremen et al., 2000) . As the most biodiverse of ecosystems, these forests are also the place where anthropogenic disturbance has the greatest potential to unleash novel pathogens (Jones et al., 2008 ; Figure 1 ). Further, mitigating climate variability has precautionary value, as anomalous climate events can act synergistically with, and facilitate, pathogen emergence (Shaman & Lipsitch, 2013) . A recent cost-benefit analysis of pandemic prevention found that reducing deforestation by half would be a cost-effective way to substantially reduce spillover risks, with an ancillary benefit of close to $4 billion per year in reduced greenhouse gas emissions (Dobson et al., 2020) . Unfortunately, current policies and agricultural industry norms often provide incentives for encroachment of forested areas. Consequently, the society must address demand and incentive structures for the production and trade of forest-risk commodities (i.e., products such as palm oil, soya, and beef that result in the loss, conversion and degradation of native forest). Solutions may be found by incorporating sustainability commitments into upfront financing for such activities. This could then be combined with reforms to risk assessments that incorporate the valuation of spillover and loss of forest-associated health co-benefits for forest conversion agricultural proposals (IPBES, 2020). Success in this undertaking will require truly transformative change with unification of health and environmental policy and greater connectivity of policy initiatives from local to global. The COVID-19 pandemic has forced us to recognize the linkages between our health, the environment, and financial and agricultural systems. Catastrophe can be the mother of invention! The global disaster of the COVID pandemic must facilitate the re-organization of agriculture and wealth distribution in ways that maximize environmental protection and reduce and reverse climate change. We must capitalize on this moment of global clarity; our collective future depends on it. 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