Impacts of Climate Change on Marine Foundation Species

Wernberg, Thomas; Thomsen, Mads S.; Baum, Julia K.; Bishop, Melanie J.; Bruno, John F.; Coleman, Melinda A.; Filbee-Dexter, Karen; Gagnon, Karine; He, Qiang; Murdiyarso, Daniel; Rogers, Kerrylee; Silliman, Brian R.; Smale, Dan A.; Starko, Samuel; Vanderklift, Mathew A.

doi:10.1146/annurev-marine-042023-093037

Cited by 31 publications

(5 citation statements)

References 264 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…By integrating data analyses across these scales and methods (Table 1), we gain a better understanding of the possible mechanisms that may drive ecosystem dynamics and biodiversity, and that can be monitored—and ultimately also managed—efficiently. Finally, our scale‐integrated approach can also be transferred to address other research, monitoring, or conservation purposes, and support recent calls for better monitoring of aquatic foundation species in the face of global climate change (Wernberg et al, 2023).…”

Section: Discussionsupporting

confidence: 53%

Facilitation cascades across space: Monitoring estuarine foundation species from satellites to the microscope

Clemente,

Thomsen

2024

Ecosphere

Self Cite

View full text Add to dashboard Cite

Estuaries are productive ecosystems that are vulnerable to human impacts and environmental disturbances. Estuaries are often inhabited by foundation species that facilitate other organisms by creating and modifying habitats. However, spatiotemporal variability and underpinning drivers of facilitation from estuarine foundation species are poorly studied, especially in the context of monitoring and conservation. Here, we combined the analyses of satellite, drone, and camera images, close‐up field sampling of quadrats and individuals, and laboratory microscopy, to quantify co‐occurrences between the cockle Austrovenus stutchburyi and green macroalga Ulva spp., and their associated invertebrate communities, across spatial resolutions and environmental gradients in a New Zealand estuary. We found higher abundance of Ulva in winter and higher abundance of Austrovenus at a site near the ocean. Furthermore, Ulva was, across space and time, often attached to Austrovenus, either live or dead shells, suggesting a hierarchy between a primary (cockle) and secondary (macroalgae) foundation species. Finally, Ulva provided a better habitat for mobile invertebrates than Austrovenus, and thereby increased estuarine diversity through a density‐dependent facilitation cascade, which also was consistent in space and time. Overall, our study showed that facilitation cascades can be indirectly inferred and monitored through remote sensing of foundation species using supplementary imaging methods, and that integration of data across scales allows researchers to better understand the drivers and consequences of facilitation from foundation species. These insights may aid in the development of efficient monitoring strategies and ultimately improve the management of estuarine ecosystems.

show abstract

Section: Discussionsupporting

confidence: 53%

Facilitation cascades across space: Monitoring estuarine foundation species from satellites to the microscope

Clemente,

Thomsen

2024

Ecosphere

Self Cite

View full text Add to dashboard Cite

show abstract

“…Intertidal stands of mussels, however, are increasingly being lost in relation to the ongoing climatic and oceanographic change ( Sorte et al, 2017 ; Seuront et al, 2019 ; Mendez et al, 2021 ; Fields & Silbiger, 2022 ; Raymond et al, 2022 ; Cameron & Scrosati, 2023 ; Scrosati, 2023 ). This is, in fact, a trend seen also in other marine foundation species such as corals, seaweeds, seagrasses, salt marsh plants, mangroves, and other bivalves ( Wernberg et al, 2024 ). For these reasons, knowledge that can be applicable to the conservation and restoration of these systems ( e.g.…”

Section: Discussionmentioning

confidence: 80%

Changes in the composition of invertebrate assemblages from wave-exposed intertidal mussel stands along the Nova Scotia coast, Canada

Scrosati,

Ellrich

2024

PeerJ

View full text Add to dashboard Cite

Rocky intertidal habitats occur worldwide and are mainly characterized by primary space holders such as seaweeds and sessile invertebrates. Some of these organisms are foundation species, as they can form structurally complex stands that host many small invertebrates. The abundance of primary space holders is known to vary along coastlines driven directly or indirectly by environmental variation. However, it is less clear if the invertebrate assemblages associated to a foundation species may remain relatively unchanged along coastlines, as similar stands of a foundation species can generate similar microclimates. We examined this question using abundance data for invertebrate species found in mussel stands of a similar structure in wave-exposed rocky habitats at mid-intertidal elevations along the Atlantic coast of Nova Scotia (Canada). While the most abundant invertebrate species were found at three locations spanning 315 km of coastline, species composition (a combined measure of species identity and their relative abundance) differed significantly among the locations. One of the species explaining the highest amount of variation among locations (a barnacle) exhibited potential signs of bottom-up regulation involving pelagic food supply, suggesting benthic–pelagic coupling. The abundance of the species that explained the highest amount of variation (an oligochaete) was positively related to the abundance of their predators (mites), further suggesting bottom-up forcing in these communities. Overall, we conclude that species assemblages associated to structurally similar stands of a foundation species can show clear changes in species composition at a regional scale.

show abstract

“…Climate change is perhaps one of the greatest threats to algal persistence and distribution, with warming and marine heatwaves precipitating some of the largest declines and ecosystem changes in algal communities (Figure 1a). While climate change presents some algal species opportunities to expand or proliferate, other species are being rapidly lost (Wernberg et al., 2024), creating a need for novel and proactive management and conservation strategies (Coleman et al., 2020; Coleman & Goold, 2019). Recent recognition of algae in blue carbon pathways presents new opportunities for conservation and restoration of algal habitats, but there is still much science to be done to confirm when and where algae play a significant role in carbon cycles and climate mitigation (Figure 1b).…”

Section: Figurementioning

confidence: 99%

Algae in the Anthropocene: Managing, conserving, and utilizing algae in an era of rapid environmental change

Coleman

2023

Journal of Phycology

Self Cite

View full text Add to dashboard Cite

The Anthropocene is defined as the current period in which humans have had a large influence over the status and trajectory of earth's climate and environment. Human‐induced climate change, pollution, and coastal development have caused major changes to algal persistence, distribution, diversity, and function. This has not only brought new challenges for managing and conserving algae, but also new opportunities. This series of perspective pieces will touch on some of these challenges, potential solutions, and knowledge gaps that we must consider in supporting and understanding algae in the Anthropocene.

show abstract

Impacts of Climate Change on Marine Foundation Species

Cited by 31 publications

References 264 publications

Facilitation cascades across space: Monitoring estuarine foundation species from satellites to the microscope

Facilitation cascades across space: Monitoring estuarine foundation species from satellites to the microscope

Changes in the composition of invertebrate assemblages from wave-exposed intertidal mussel stands along the Nova Scotia coast, Canada

Algae in the Anthropocene: Managing, conserving, and utilizing algae in an era of rapid environmental change

Contact Info

Product

Resources

About