The ability of macroalgae to mitigate the negative effects of ocean acidification on four species of North Atlantic bivalve

Young, Craig S.; Gobler, Christopher J.

doi:10.5194/bg-2018-115

Cited by 5 publications

(9 citation statements)

References 76 publications

(118 reference statements)

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“…Resistance to acidification due to an abundance of food has been documented in other calcifying organisms (Pansch et al, 2014) and in forage fish (Gobler et al, 2018), bivalves (Melzner et al, 2011;Thomsen et al, 2013). Additionally, given that L. vincta utilizes macroalgae as both a habitat and a food source (Martel and Chia, 1991;Chavanich and Harris, 2002), the buffering capacity of macroalgae may minimize the harmful effects of exposure to acidification (Young and Gobler, 2018). In the present study, however, feeding did not provide a refuge from the negative effects of hypoxia, suggesting that the protection food offers against acidification may not occur in an ecosystem setting since hypoxia and acidification commonly coincide in space and time (Wallace et al, 2014;Baumann et al, 2015;Cai et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

“…Initial and final water samples were taken at the beginning and conclusion of experiments to directly measure dissolved inorganic carbon (DIC) within experimental vessels. Samples were preserved using a saturated mercuric chloride solution and stored at ∼4 • C until analysis on a VINDTA 3D delivery system coupled with a UIC Inc. coulometer (model CM5017O) as per Young and Gobler (2018). CO 2 levels ( Table 1) were calculated from measured levels of DIC, pH, temperature, and salinity as well as the first and second dissociation constants of carbonic acid in seawater (Millero, 2010) using the program CO2SYS 1 .…”

Section: Preparation Of Experimentsmentioning

confidence: 99%

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Hypoxia and Acidification, Individually and in Combination, Disrupt Herbivory and Reduce Survivorship of the Gastropod, Lacuna vincta

Young

Gobler

2020

Front. Mar. Sci.

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Acidification and deoxygenation are two consequences of climate change that also co-occur in eutrophied coastal zones and can have deleterious effects on marine life. While the effects of hypoxia on marine herbivores have been well-studied, how ocean acidification combined with hypoxia affects herbivory is poorly understood. This study examined how herbivory and survival by the gastropod Lacuna vincta grazing on the macroalgae Ulva rigida was influenced by hypoxia and ocean acidification, alone and in combination, with and without food limitation. Experiments exposed L. vincta to a range of environmentally realistic dissolved oxygen (0.7-8 mg L −1) and pH (7.3-8.0 total scale) conditions for 3-72 h, with and without a starvation period and quantified herbivory and survival. While acidified conditions (pH < 7.4) reduced herbivory when combined with food limitation, low oxygen conditions (< 4 mg L −1) reduced herbivory and survival regardless of food supply. When L. vincta were starved and grazed in acidified conditions herbivory was additively reduced, whereas starvation and hypoxia synergistically reduced grazing rates. Overall, low oxygen had a more inhibitory effect on herbivory than low pH. Shorter exposure times (9, 6, and 3 h) were required to reduce grazing at lower DO levels (∼2.4, ∼1.6, and ∼0.7 mg L −1 , respectively). Herbivory ceased entirely following a three-hour exposure to DO of 0.7 mg L −1 suggesting that episodes of diurnal hypoxia disrupt grazing by these gastropods. The suppression of herbivory in response to acidified and hypoxic conditions could create a positive feedback loop that promotes 'green tides' whereby reduced grazing facilitates the overgrowth of macroalgae that cause nocturnal acidification and hypoxia, further disrupting herbivory and promoting the growth of macroalgae. Such feedback loops could have broad implications for estuarine ecosystems where L. vincta is a dominant macroalgal grazer and will intensify as climate change accelerates.

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Section: Discussionmentioning

confidence: 99%

Section: Preparation Of Experimentsmentioning

confidence: 99%

Hypoxia and Acidification, Individually and in Combination, Disrupt Herbivory and Reduce Survivorship of the Gastropod, Lacuna vincta

Young

Gobler

2020

Front. Mar. Sci.

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“…Purposeful modification of seawater CO 2 chemistry will be most feasible in easily accessible coastal locations and for target economic purposes, such as aquaculture or small‐scale reef management (Mongin, Baird, Hadley, & Lenton, ). Phytoremediation, or modification of seawater CO 2 chemistry by seagrass, kelp, or algae cultivated alongside ocean acidification‐sensitive organisms, is an active area of research (Young & Gobler, ). However, its effectiveness in the field has significant limitations (Greiner et al, ; Mongin et al, ), and additional bubble stripping of high nighttime CO 2 levels in macrophyte beds may be necessary to ensure that the overall mean pH is significantly elevated when compared to that of surrounding waters (Koweek, Mucciarone, & Dunbar, ).…”

Section: Ocean Acidification Refugia Managementmentioning

confidence: 99%

“…For example, daytime photosynthesis by seagrass meadows can radically elevate seawater pH across spatial scales of a few millimeters to hundreds of meters (Guilini et al, ; Hendriks et al, ; Manzello et al, ). For this reason, the idea of seagrass ecosystems, and phytoremediation in general, acting as OAR has garnered considerable attention within the scientific community (Hendriks et al, ; Manzello et al, ; Young & Gobler, ), governments (Nielsen et al, ; Washington State Blue Ribbon Panel on Ocean Acidification, ), and the media (OA‐ICC, ). One issue with the concept of seagrass ecosystems acting as OAR is that times of net photosynthesis are accompanied by periods of net respiration on daily and seasonal timescales (Duarte et al, ; Unsworth et al, ).…”

Section: Defining Ocean Acidification Refugiamentioning

confidence: 99%

“…The presence of spatial and temporal variability in CO 2 chemistry across marine ecosystems has raised the idea that ocean acidification refugia (OAR), or locations where ocean acidification impacts could be less intense, exist naturally (Manzello, Enochs, Melo, Gledhill, & Johns, ). Proposed OAR include seagrass meadows and dense algal beds (Hendriks et al, ; Krause‐Jensen et al, ; Manzello et al, ; Unsworth, Collier, Henderson, & Mckenzie, ; Wahl et al, ; Young & Gobler, ), algal boundary layers (Cornwall et al, ; Hendriks, Duarte, Marbà, & Krause‐Jensen, ; Noisette & Hurd, ), mangroves (Sippo, Maher, Tait, Holloway, & Santos, ; Yates et al, ), slow‐flow habitats (Hurd, ), deep‐sea mounts (Tittensor, Baco, Hall‐Spencer, Orr, & Rogers, ), areas isolated from upwelling (Chan et al, ; Kapsenberg & Hofmann, ), and productive high‐latitude environments (Hendriks et al, ; Krause‐Jensen et al, ). These examples vary dramatically across spatial scales (e.g., a few millimeters in an algal boundary layer to a 100 m 2 seagrass bed), with no clear criteria as to what makes each area a potential OAR other than observed transient increases in seawater pH relative to surrounding waters.…”

Section: Introductionmentioning

confidence: 99%

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Ocean acidification refugia in variable environments

Kapsenberg

Cyronak

2019

Global Change Biology

109

105

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Climate change refugia in the terrestrial biosphere are areas where species are protected from global environmental change and arise from natural heterogeneity in landscapes and climate. Within the marine realm, ocean acidification, or the global decline in seawater pH, remains a pervasive threat to organisms and ecosystems. Natural variability in seawater carbon dioxide (CO2) chemistry, however, presents an opportunity to identify ocean acidification refugia (OAR) for marine species. Here, we review the literature to examine the impacts of variable CO2 chemistry on biological responses to ocean acidification and develop a framework of definitions and criteria that connects current OAR research to management goals. Under the concept of managing vulnerability, the most likely mechanisms by which OAR can mitigate ocean acidification impacts are by reducing exposure to harmful conditions or enhancing adaptive capacity. While local management options, such as OAR, show some promise, they present unique challenges, and reducing global anthropogenic CO2 emissions must remain a priority.

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Role of hydrodynamics in shaping chemical habitats and modulating the responses of coastal benthic systems to ocean global change

Noisette

Pansch

Wall

et al. 2022

Global Change Biology

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The ability of macroalgae to mitigate the negative effects of ocean acidification on four species of North Atlantic bivalve

Cited by 5 publications

References 76 publications

Hypoxia and Acidification, Individually and in Combination, Disrupt Herbivory and Reduce Survivorship of the Gastropod, Lacuna vincta

Hypoxia and Acidification, Individually and in Combination, Disrupt Herbivory and Reduce Survivorship of the Gastropod, Lacuna vincta

Ocean acidification refugia in variable environments

Role of hydrodynamics in shaping chemical habitats and modulating the responses of coastal benthic systems to ocean global change

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