Your search keyword '"Merolla, Sarah"' showing total 7 results

1. Commentary: Overstated Potential for Seagrass Meadows to Mitigate Coastal Ocean Acidification

Author

Ricart, Aurora M, Ward, Melissa, Hill, Tessa M, Sanford, Eric, Kroeker, Kristy J, Takeshita, Yuihiro, Merolla, Sarah, Shukla, Priya, Ninokawa, Aaron T, Elsmore, Kristen, and Gaylord, Brian

Subjects

ocean acidification, seagrass, carbonate chemistry, CO2 system calculations, commentary articles, Oceanography, Ecology

Published

2022

2. Coast-wide evidence of low pH amelioration by seagrass ecosystems.

Author

Ricart, Aurora M, Ward, Melissa, Hill, Tessa M, Sanford, Eric, Kroeker, Kristy J, Takeshita, Yuichiro, Merolla, Sarah, Shukla, Priya, Ninokawa, Aaron T, Elsmore, Kristen, and Gaylord, Brian

Subjects

Zosteraceae, Carbon, Ecosystem, Seawater, Hydrogen-Ion Concentration, Zostera marina, buffer, carbon cycling, carbonate chemistry, mitigation, ocean acidification, photosynthesis, submerged aquatic vegetation, Zostera marina, Life Below Water, Environmental Sciences, Biological Sciences, Ecology

Abstract

Global-scale ocean acidification has spurred interest in the capacity of seagrass ecosystems to increase seawater pH within crucial shoreline habitats through photosynthetic activity. However, the dynamic variability of the coastal carbonate system has impeded generalization into whether seagrass aerobic metabolism ameliorates low pH on physiologically and ecologically relevant timescales. Here we present results of the most extensive study to date of pH modulation by seagrasses, spanning seven meadows (Zostera marina) and 1000 km of U.S. west coast over 6 years. Amelioration by seagrass ecosystems compared to non-vegetated areas occurred 65% of the time (mean increase 0.07 ± 0.008 SE). Events of continuous elevation in pH within seagrass ecosystems, indicating amelioration of low pH, were longer and of greater magnitude than opposing cases of reduced pH or exacerbation. Sustained elevations in pH of >0.1, comparable to a 30% decrease in [H+ ], were not restricted only to daylight hours but instead persisted for up to 21 days. Maximal pH elevations occurred in spring and summer during the seagrass growth season, with a tendency for stronger effects in higher latitude meadows. These results indicate that seagrass meadows can locally alleviate low pH conditions for extended periods of time with important implications for the conservation and management of coastal ecosystems.

Published

2021

3. Blue carbon stocks and exchanges along the California coast

Author

Ward, Melissa A, Hill, Tessa M, Souza, Chelsey, Filipczyk, Tessa, Ricart, Aurora M, Merolla, Sarah, Capece, Lena R, O'Donnell, Brady C, Elsmore, Kristen, Oechel, Walter C, and Beheshti, Kathryn M

Subjects

Climate Change Impacts and Adaptation, Environmental Sciences, Life Below Water, Earth Sciences, Biological Sciences, Meteorology & Atmospheric Sciences, Ecology, Physical geography and environmental geoscience, Environmental management

Abstract

Salt marshes and seagrass meadows can sequester and store high quantities of organic carbon (OC) in their sediments relative to other marine and terrestrial habitats. Assessing carbon stocks, carbon sources, and the transfer of carbon between habitats within coastal seascapes are each integral in identifying the role of blue carbon habitats in coastal carbon cycling. Here, we quantified carbon stocks, sources, and exchanges in seagrass meadows, salt marshes, and unvegetated sediments in six bays along the California coast. In the top 20ĝ€¯cm of sediment, the salt marshes contained approximately twice as much OC as seagrass meadows did, 4.92ĝ€¯±ĝ€¯0.36ĝ€¯kgĝ€¯OCĝ€¯m-2 compared to 2.20ĝ€¯±ĝ€¯0.24ĝ€¯kgĝ€¯OCĝ€¯m-2, respectively. Both salt marsh and seagrass sediment carbon stocks were higher than previous estimates from this region but lower than global and US-wide averages, respectively. Seagrass-derived carbon was deposited annually into adjacent marshes during fall seagrass senescence. However, isotope mixing models estimate that negligible amounts of this seagrass material were ultimately buried in underlying sediment. Rather, the vast majority of OC in sediment across sites was likely derived from planktonic/benthic diatoms and/or C3 salt marsh plants.

Published

2021

4. Commentary: Overstated Potential for Seagrass Meadows to Mitigate Coastal Ocean Acidification

Author

Ricart, Aurora M., primary, Ward, Melissa, additional, Hill, Tessa M., additional, Sanford, Eric, additional, Kroeker, Kristy J., additional, Takeshita, Yuihiro, additional, Merolla, Sarah, additional, Shukla, Priya, additional, Ninokawa, Aaron T., additional, Elsmore, Kristen, additional, and Gaylord, Brian, additional

Published

2022

5. Thermal Stress Interacts With Surgeonfish Feces to Increase Coral Susceptibility to Dysbiosis and Reduce Tissue Regeneration

Author

Ezzat, Leïla, primary, Merolla, Sarah, additional, Clements, Cody S., additional, Munsterman, Katrina S., additional, Landfield, Kaitlyn, additional, Stensrud, Colton, additional, Schmeltzer, Emily R., additional, Burkepile, Deron E., additional, and Vega Thurber, Rebecca, additional

Published

2021

6. Blue Carbon Stocks and Exchanges Along the Pacific West Coast.

Author

Ward, Melissa A., Hill, Tessa M., Souza, Chelsey, Filipczyk, Tessa, Ricart, Aurora M., Merolla, Sarah, Capece, Lena R., O'Donnell, Brady C., Elsmore, Kristen, Oechel, Walter C., and Beheshti, Kathryn M.

Subjects

STOCK exchanges, SALT marsh plants, FREIGHT trucking, SALT marshes, SEAGRASSES, MARINE habitats

Abstract

Salt marshes and seagrass meadows can sequester and store high quantities of organic carbon (OC) in their sediments relative to other marine and terrestrial habitats. Assessing carbon stocks, carbon sources, and the transfer of carbon between habitats within coastal seascapes are each integral in identifying the role of blue carbon habitats in coastal carbon cycling. Here, we quantified carbon stocks, sources, and exchanges in seagrass meadows, salt marshes, and unvegetated sediments in six bays along the Pacific coast of California. The salt marshes studied here contained approximately twice as much OC as did seagrass meadows, 23.51 ± 1.77 kg OC m-3 compared to 11.01 ± 1.18 kg OC m-3, respectively. Both seagrass and salt marsh sediment carbon stocks were higher than previous estimates from this region but lower than global and U.S.-wide averages, respectively. Seagrass-derived carbon was deposited annually into adjacent marshes during fall seagrass senescence. However, isotope mixing models estimate that negligible amounts of this seagrass material were ultimately buried in underlying sediment. Rather, the vast majority of OC in sediment across sites was likely derived from planktonic/benthic diatoms and C3 salt marsh plants. [ABSTRACT FROM AUTHOR]

Published

2021

7. Thermal Stress Interacts With Surgeonfish Feces to Increase Coral Susceptibility to Dysbiosis and Reduce Tissue Regeneration

Author

Ezzat, Leïla, Merolla, Sarah, Clements, Cody S., Munsterman, Katrina S., Landfield, Kaitlyn, Stensrud, Colton, Schmeltzer, Emily R., Burkepile, Deron E., and Vega Thurber, Rebecca

Subjects

Microbiology (medical), feces, fungi, technology, industry, and agriculture, dysbiosis, vibrio, Microbiology, coral, thermal stress, global change, surgeonfish, 16s rrna

Abstract

Dysbiosis of coral microbiomes results from various biotic and environmental stressors, including interactions with important reef fishes which may act as vectors of opportunistic microbes via deposition of fecal material. Additionally, elevated sea surface temperatures have direct effects on coral microbiomes by promoting growth and virulence of opportunists and putative pathogens, thereby altering host immunity and health. However, interactions between these biotic and abiotic factors have yet to be evaluated. Here, we used a factorial experiment to investigate the combined effects of fecal pellet deposition by the widely distributed surgeonfish Ctenochaetus striatus and elevated sea surface temperatures on microbiomes associated with the reef-building coral Porites lobata. Our results showed that regardless of temperature, exposure of P. lobata to C. striatus feces increased alpha diversity, dispersion, and lead to a shift in microbial community composition - all indicative of microbial dysbiosis. Although elevated temperature did not result in significant changes in alpha and beta diversity, we noted an increasing number of differentially abundant taxa in corals exposed to both feces and thermal stress within the first 48h of the experiment. These included opportunistic microbial lineages and taxa closely related to potential coral pathogens (i.e., Vibrio vulnificus, Photobacterium rosenbergii). Some of these taxa were absent in controls but present in surgeonfish feces under both temperature regimes, suggesting mechanisms of microbial transmission and/or enrichment from fish feces to corals. Importantly, the impact to coral microbiomes by fish feces under higher temperatures appeared to inhibit wound healing in corals, as percentages of tissue recovery at the site of feces deposition were lower at 30 degrees C compared to 26 degrees C. Lower percentages of tissue recovery were associated with greater relative abundance of several bacterial lineages, with some of them found in surgeonfish feces (i.e., Rhodobacteraceae, Bdellovibrionaceae, Crocinitomicaceae). Our findings suggest that fish feces interact with elevated sea surface temperatures to favor microbial opportunism and enhance dysbiosis susceptibility in P. lobata. As the frequency and duration of thermal stress related events increase, the ability of coral microbiomes to recover from biotic stressors such as deposition of fish feces may be greatly affected, ultimately compromising coral health and resilience.