New research led by scientists at the University of California, Los Angeles (UCLA) reveals that Marine Protected Areas (MPAs) can significantly aid the recovery of kelp forests following severe marine heatwaves. Published in the Journal of Applied Ecology, this extensive observational study draws upon over four decades of satellite data to assess the resilience of these vital underwater ecosystems along California’s coastline. The findings suggest that while MPAs provide modest benefits under normal conditions, their protective role becomes markedly evident after extreme climatic disturbances.
Kelp forests are complex marine ecosystems found worldwide, particularly thriving in temperate coastal waters such as those off the Pacific coast of North America, the United Kingdom, South Africa, and Australia. These underwater forests serve as crucial habitats for numerous marine species, supporting biodiversity and providing economic value through fisheries. Additionally, kelp forests play an essential role in carbon sequestration, absorbing CO2 and helping mitigate global climate change. Acting as natural coastal buffers, they also protect shorelines from erosion by dissipating wave energy, underscoring their ecological and socioeconomic importance.
However, escalating marine heatwaves—exacerbated by anthropogenic climate change—have inflicted catastrophic damage on kelp forests, especially along the West Coast of North America. The 2014–2016 North Pacific marine heatwave, dubbed “the Blob,” caused unprecedented warming of ocean waters, resulting in widespread kelp mortality. Compounding this thermal stress is the surge in sea urchin populations, which have proliferated following sharp declines in predatory sea stars. These overgrazing urchins effectively devastate kelp habitats, hindering natural recovery processes and threatening the long-term stability of these ecosystems.
In this context, MPAs have emerged as a promising tool to enhance ecological resilience. MPAs are designated sections of the ocean where human activity, particularly fishing, is regulated or restricted to protect habitats and marine biodiversity. However, the level of protection varies widely among MPAs, ranging from fully no-take reserves to areas permitting considerable extractive activities, including destructive fishing practices like bottom trawling. The UCLA study has focused on MPAs with explicit restrictions on fishing, providing a clearer understanding of how such regulatory measures impact kelp forest dynamics.
By analyzing 54 MPAs and their corresponding reference sites along California’s coast, researchers compared kelp forest cover from 1984 to 2022 using satellite imagery. This rigorous comparative approach allowed them to isolate the effects of MPAs on kelp resilience to heat stress, distinguishing between resistance (avoiding loss) and recovery (regaining cover) after marine heatwaves. The study confirms that kelp within MPAs demonstrated greater post-heatwave recovery relative to unprotected sites, especially notable in southern California, where heat stress and ecological pressures are often more severe.
The mechanisms behind this enhanced recovery appear linked to the protection of key predator species within MPAs. Species such as lobsters and sheephead fish, which prey upon herbivorous invertebrates like sea urchins, help control urchin populations and reduce overgrazing. In the absence of these predators, unchecked urchin populations can decimate kelp stands. Thus, MPAs indirectly support kelp regeneration by maintaining the integrity of trophic interactions critical to ecosystem balance. This trophic cascade demonstrates the intricate connections between species that underlie ecosystem resilience.
Despite these encouraging findings, the researchers caution that the protective effect of MPAs is not uniform across all sites. Variability in environmental conditions, MPA management quality, enforcement efficacy, and local oceanographic features influence outcomes. For example, areas characterized by localized upwelling tend to be cooler and nutrient-rich, fostering kelp populations with greater thermal tolerance, thereby naturally enhancing resilience. Strategically situating MPAs in such dynamic environments could maximize conservation effectiveness.
Moreover, the study highlights the importance of integrating kelp forest monitoring into long-term conservation strategies and global biodiversity frameworks. The Kunming-Montreal Global Biodiversity Framework, adopted at COP15 in 2022, sets ambitious targets to safeguard at least 30% of marine and terrestrial habitats by 2030. This research underscores the utility of kelp forests as bioindicators that reflect ecological health and climate resilience in marine protected systems, thereby providing valuable feedback for adaptive management and policy formulation.
Co-author Emelly Ortiz-Villa, a PhD researcher at UCLA’s Department of Geography, emphasizes that MPAs help buffer kelp against climate-induced disturbances, offering ecosystem services beyond just conservation. The study’s evidence suggests that MPAs not only support biodiversity preservation but also bolster ecosystem functions critical to human well-being, such as carbon sequestration and coastal protection. This multifaceted benefit strengthens the case for expanding and effectively managing MPAs in a warming world.
Senior author Professor Kyle Cavanaugh adds that the results have significant implications for conservation planning. MPAs should be prioritized in regions poised to exhibit natural resilience—such as areas with frequent upwelling events or kelp populations adapted to warmer temperatures—to optimize the return on investment in ocean conservation. Understanding spatial and ecological nuances will be critical to designing MPAs that can withstand escalating climate threats and foster robust marine ecosystems.
The study also draws attention to the pitfalls of designating MPAs without enforcing adequate protections. Many so-called MPAs globally permit activities detrimental to ecosystem health, diminishing their potential to contribute to resilience. Robust enforcement, clearly defined management regulations, and community engagement are necessary components of successful MPAs that can mitigate the increasing frequency and intensity of marine heatwaves.
Looking ahead, the research team advocates for further investigation into the drivers of uneven MPA effectiveness. Identifying the interplay of biological, physical, and managerial factors will equip stakeholders with knowledge to tailor conservation efforts adapted to local environmental realities. Such adaptive management is essential as climate change accelerates and marine ecosystems face unprecedented threats.
This landmark study vividly illustrates the critical role of spatial management in safeguarding the future of kelp forests, ecosystems integral to marine biodiversity and carbon cycling. As the ocean continues to warm, strategies that integrate MPAs with broader climate mitigation efforts offer a beacon of hope for protecting these vibrant underwater forests and the myriad species and communities that depend on them.
Subject of Research: Not applicable
Article Title: Marine protected areas enhance climate resilience to severe marine heatwaves for kelp forests
News Publication Date: 19-Aug-2025
Web References: http://dx.doi.org/10.1111/1365-2664.70112
Image Credits: Ortiz-Villa et al.
Keywords: Marine ecology, Marine conservation, Marine ecosystems, Climate change
