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1. Natural Enemies and the Maintenance of Tropical Tree Diversity: Recent Insights and Implications for the Future of Biodiversity in a Changing World

   https://doi.org/10.3417/2020591  

   Comita, Liza S.; Stump, Simon M. (September 2020, Annals of the Missouri Botanical Garden)

   null (Ed.)

   Over the past five decades, many studies have examined the Janzen-Connell hypothesis, which posits that host-specific natural enemies, such as insect herbivores and fungal pathogens, promote plant species coexistence by providing a recruitment advantage to rare plant species. Recently, researchers have been exploring new and exciting angles on plant-enemy interactions that have yielded novel insights into this long-standing hypothesis. Here, we highlight some empirical advances in our understanding of plant-enemy interactions in tropical forests, including improved understanding of variation in plant species’ susceptibility to enemy effects, as well as insect and pathogen host ranges. We then review recent advances in related ecological theory. These theoretical studies have confirmed that specialist natural enemies can promote tree diversity. However, they have also shown that the impact of natural enemies may be weakened, or that natural enemies could even cause species exclusion, depending on enemy host range, the spatial extent of enemy effects, and variation among plant species in seed dispersal or enemy susceptibility. Finally, we end by discussing how human impacts on tropical forests, such as fragmentation, hunting, and climate change, may alter the plant-enemy interactions that contribute to tropical forest diversity. 

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2. How deregulation, drought and increasing fire impact Amazonian biodiversity

   https://doi.org/10.1038/s41586-021-03876-7  

   Feng, Xiao; Merow, Cory; Liu, Zhihua; Park, Daniel S.; Roehrdanz, Patrick R.; Maitner, Brian; Newman, Erica A.; Boyle, Brad L.; Lien, Aaron; Burger, Joseph R.; et al (September 2021, Nature)

   null (Ed.)

   Biodiversity contributes to the ecological and climatic stability of the Amazon Basin1,2, but is increasingly threatened by deforestation and fire3,4. Here we quantify these impacts over the past two decades using remote-sensing estimates of fire and deforestation and comprehensive range estimates of 11,514 plant species and 3,079 vertebrate species in the Amazon. Deforestation has led to large amounts of habitat loss, and fires further exacerbate this already substantial impact on Amazonian biodiversity. Since 2001, 103,079–189,755 km2 of Amazon rainforest has been impacted by fires, potentially impacting the ranges of 77.3–85.2% of species that are listed as threatened in this region5. The impacts of fire on the ranges of species in Amazonia could be as high as 64%, and greater impacts are typically associated with species that have restricted ranges. We find close associations between forest policy, fire-impacted forest area and their potential impacts on biodiversity. In Brazil, forest policies that were initiated in the mid-2000s corresponded to reduced rates of burning. However, relaxed enforcement of these policies in 2019 has seemingly begun to reverse this trend: approximately 4,253–10,343 km2 of forest has been impacted by fire, leading to some of the most severe potential impacts on biodiversity since 2009. These results highlight the critical role of policy enforcement in the preservation of biodiversity in the Amazon. 

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3. Potential Impacts of Insect-Induced Harvests in the Mixed Forests of New England

   https://doi.org/10.3390/f11050498  

   MacLean, Meghan Graham; Holt, Jonathan; Borsuk, Mark; Markowski-Lindsay, Marla; Butler, Brett J.; Kittredge, David B.; Duveneck, Matthew J.; Laflower, Danelle; Orwig, David A.; Foster, David R.; et al (May 2020, Forests)

   Forest insects and pathogens have significant impacts on U.S. forests, annually affecting an area nearly three times that of wildfires and timber harvesting combined. However, coupled with these direct effects of forest insects and pathogens are the indirect impacts through influencing forest management practices, such as harvesting. In an earlier study, we surveyed private woodland owners in the northeastern U.S. and 84% of respondents indicated they intended to harvest in at least one of the presented insect invasion scenarios. This harvest response to insects represents a potentially significant shift in the timing, extent, and species selection of harvesting. Here we used the results from the landowner survey, regional forest inventory data, and characteristics of the emerald ash borer (Species: Agrilus planipennis Fairmaire, 1888) invasion to examine the potential for a rapidly spreading invasive insect to alter harvest regimes and affect regional forest conditions. Our analysis suggests that 25% of the woodland parcels in the Connecticut River Watershed in New England may intend to harvest in response to emerald ash borer. If the emerald ash borer continues to spread at its current rate within the region, and therefore the associated management response occurs in the next decade, this could result in an increase in harvest frequencies, from 2.6% year−1 (historically) to 3.7% year−1 through to approximately 2030. If harvest intensities remain at levels found in remeasured Forest Inventory and Analysis plots, this insect-initiated harvesting would result in the removal of 12%–13% of the total aboveground biomass. Eighty-one percent of the removed biomass would be from species other than ash, creating a forest disturbance that is over twice the magnitude than that created by emerald ash borer alone, with the most valuable co-occurring species most vulnerable to biomass loss. 

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4. Speed breeding transgenic American chestnut trees toward restoration

   https://doi.org/10.1101/2025.05.19.654928  

   Klak, Thomas; Pilkey, Hannah; May, Virginia G; Matthews, Dakota; Oakes, Allison D; Tan, Ek Han; Newhouse, Andrew E (May 2025, bioRxiv)

   Abstract The American chestnut (Castanea dentata) was a dominant, foundational forest canopy tree in eastern North America until an imported chestnut blight (caused byCryphonectria parasitica) rendered it functionally extinct across its native range. Biotechnological approaches have the potential to help restore the species, but field-based breeding advances are hampered by long generation times, ≤50% transgene inheritance, and regulatory restrictions on outdoor breeding of transgenic trees. Self-incompatibility and flowering phenology further limit generational advances and field testing of chestnuts. Our work here demonstrates that long generational times and field constraints can be circumvented by producing both male and receptive female flowers in controlled indoor environments. Additionally, we developed an embryo rescue protocol for both indoor and field conditions, in which developing embryos can be extracted and micropropagated from immature seeds between 6- and 8-weeks post pollination. These advances have enabled production of the first homozygous transgenic American chestnuts, which have produced pollen that was used for outdoor controlled pollinations and yielded nearly 100% transgene inheritance by offspring. This work also provides event-specific DNA markers to differentiate transgenic chestnut lines and identify homozygous individuals. We demonstrate that an obligate outcrossing forest tree can reach sexual maturity rapidly in controlled, indoor environments. When coupled with genomic analyses and other biotechnological advances, this procedure could facilitate the reintroduction of this iconic species. 

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5. A Subcontinental Analysis of Forest Fragmentation Effects on Insect and Disease Invasion

   https://doi.org/10.3390/f9120744  

   Guo, Qinfeng; Riitters, Kurt; Potter, Kevin (December 2018, Forests)

   The influences of human and physical factors on species invasions have been extensively examined by ecologists across many regions. However, how habitat fragmentation per se may affect forest insect and disease invasion has not been well studied, especially the related patterns over regional or subcontinental scales. Here, using national survey data on forest pest richness and fragmentation data across United States forest ecosystems, we examine how forest fragmentation and edge types (neighboring land cover) may affect pest richness at the county level. Our results show that habitat fragmentation and edge types both affected pest richness. In general, specialist insects and pathogens were more sensitive to fragmentation and edge types than generalists, while pathogens were much less sensitive to fragmentation and edge types than insect pests. Most importantly, the developed land edge type contributed the most to the richness of nonnative insects and diseases, whether measured by the combination of all pest species or by separate guilds or species groups (i.e., generalists vs. specialists, insects vs. pathogens). This observation may largely reflect anthropogenic effects, including propagule pressure associated with human activities. These results shed new insights into the patterns of forest pest invasions, and it may have significant implications for forest restoration and management. 

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