Ocean Acidification and the Loss of Phenolic Substances in Marine Plants

Arnold, Thomas M.; Mealey, Christopher; Leahey, Hannah; Miller, A. Whitman; Hall‐Spencer, Jason M.; Milazzo, Marco; Maers, Kelly

doi:10.1371/journal.pone.0035107

Cited by 160 publications

(138 citation statements)

References 54 publications

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“…We found that upper photic zone coccolithophore communities in southern Tyrrhenian Sea water and Levante Bay were very similar in areas unaffected by elevated CO 2 . Future studies could combine in situ mesocosm-type experiments to constrain the movement of plankton at the seeps or use Free Ocean Carbon Experiments to control the CO 2 dose (Arnold et al, 2012). Given the shallow nature of the seeps, such work could also incorporate investigations of the possible effects of ultraviolet radiation.…”

Section: Discussionmentioning

confidence: 99%

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO₂ Gradient

Ziveri

Passaro

Incarbona

et al. 2014

The Biological Bulletin

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Abstract.A natural pH gradient caused by marine CO 2 seeps off Vulcano Island (Italy) was used to assess the effects of ocean acidification on coccolithophores, which are abundant planktonic unicellular calcifiers. Such seeps are used as natural laboratories to study the effects of ocean acidification on marine ecosystems, since they cause longterm changes in seawater carbonate chemistry and pH, exposing the organisms to elevated CO 2 concentrations and therefore mimicking future scenarios. Previous work at CO 2 seeps has focused exclusively on benthic organisms. Here we show progressive depletion of 27 coccolithophore species, in terms of cell concentrations and diversity, along a calcite saturation gradient from ⍀ calcite 6.4 to Ͻ1. Water collected close to the main CO 2 seeps had the highest concentrations of malformed Emiliania huxleyi. These observations add to a growing body of evidence that ocean acidification may benefit some algae but will likely cause marine biodiversity loss, especially by impacting calcifying species, which are affected as carbonate saturation falls.

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Section: Discussionmentioning

confidence: 99%

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO₂ Gradient

Ziveri

Passaro

Incarbona

et al. 2014

The Biological Bulletin

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“…To date, in situ responses of marine organism to dissolved CO 2 increase are based on observations made near volcanic vents (Hall-Spencer et al 2008, Martin et al 2008, Porzio et al 2011, Johnson et al 2012. Recently, different techniques of in situ CO 2 manipulation, such as the Coral−Proto Free Ocean Carbon Enrichment System (Kline et al 2012), the Free Ocean Carbon Enrichment System (Arnold et al 2012), and the Carbon-Enriched Open Chamber System (Campbell & Fourqurean 2011) have been proposed. The development of new CO 2 in situ experiments can provide new insights and give straightforward answers or at least provide a piece of the puzzle about the effect of OA on macroalgae.…”

Section: Introductionmentioning

confidence: 99%

A novel in situ system to evaluate the effect of high CO2 on photosynthesis and biochemistry of seaweeds

Korbee¹,

Navarro²,

García-Sánchez³

et al. 2014

Aquat. Biol.

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Previous studies of the impact of increased CO 2 on macroalgae have mainly been done in laboratories or mesocosm systems, placing organisms under both artificial light and seawater conditions. In this study, macroalgae were incubated in situ in UV-transparent cylinders under conditions similar to the external environment. This system was tested in a short-term study (5.5 h incubation) on the effect of 2 partial pressures of CO 2 (pCO 2 ): air (ambient CO 2 ) and the pCO 2 predicted by the end of the 21st century (700 µatm, high CO 2 ), on photosynthesis, photosynthetic pigments and photoprotection in calcifying (Ellisolandia elongata and Padina pavonica) and non-calcifying (Cystoseira tamariscifolia) macroalgae. The calcifying P. pavonica showed higher net photosynthesis under high CO 2 than under ambient CO 2 conditions, whereas the opposite occurred in C. tamariscifolia. Both brown algae (P. pavonica and C. tamariscifolia) showed activation of non-photochemical quenching mechanisms under high CO 2 conditions. However, in P. pavonica the phenol content was reduced after CO 2 enrichment. In contrast to phenols, in E. elongata other photoprotectors such as zeaxanthin and palythine (mycosporine-like amino acid) tended to increase in the high CO 2 treatment. The different responses of these species to elevated pCO 2 may be due to anatomical and physiological differences and could represent a shift in their relative dominance as key species in the face of ocean acidification (OA). More in situ studies could be carried out to evaluate how macroalgae will respond to increases in pCO 2 in a future OA scenario. The in situ incubator system proposed in this work may contribute towards increasing this knowledge.

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“…High CO 2 /low pH conditions cause the loss of antimicrobial phenolics in many seagrass species (Arnold et al 2012;Arnold et al 2014; but see Martínez-Crego et al 2014; Figure 1 sites (i), (j)). Phenolic acids known to inhibit the growth of the seagrass wasting disease pathogen, Layrinthula spp., were reduced by as much as~95% under "acidified" conditions.…”

Section: Coastal Zone Acidificationmentioning

confidence: 99%

Twenty-first century climate change and submerged aquatic vegetation in a temperate estuary: the case of Chesapeake Bay

Arnold

Zimmerman

Engelhardt

et al. 2017

Ecosyst Health Sustain

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Introduction: The Chesapeake Bay was once renowned for expansive meadows of submerged aquatic vegetation (SAV). However, only 10% of the original meadows survive. Future restoration efforts will be complicated by accelerating climate change, including physiological stressors such as a predicted mean temperature increase of 2-6°C and a 50-160% increase in CO 2 concentrations. Outcomes: As the Chesapeake Bay begins to exhibit characteristics of a subtropical estuary, summer heat waves will become more frequent and severe. Warming alone would eventually eliminate eelgrass (Zostera marina) from the region. It will favor native heat-tolerant species such as widgeon grass (Ruppia maritima) while facilitating colonization by non-native seagrasses (e.g., Halodule spp.). Intensifying human activity will also fuel coastal zone acidification and the resulting high CO 2 /low pH conditions may benefit SAV via a "CO 2 fertilization effect." Discussion: Acidification is known to offset the effects of thermal stress and may have similar effects in estuaries, assuming water clarity is sufficient to support CO 2 -stimulated photosynthesis and plants are not overgrown by epiphytes. However, coastal zone acidification is variable, driven mostly by local biological processes that may or may not always counterbalance the effects of regional warming. This precarious equipoise between two forcesthermal stress and acidification -will be critically important because it may ultimately determine the fate of cool-water plants such as Zostera marina in the Chesapeake Bay. Conclusion: The combined impacts of warming, coastal zone acidification, water clarity, and overgrowth of competing algae will determine the fate of SAV communities in rapidly changing temperate estuaries.

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Ocean Acidification and the Loss of Phenolic Substances in Marine Plants

Cited by 160 publications

References 54 publications

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO₂ Gradient

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO₂ Gradient

A novel in situ system to evaluate the effect of high CO2 on photosynthesis and biochemistry of seaweeds

Twenty-first century climate change and submerged aquatic vegetation in a temperate estuary: the case of Chesapeake Bay

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Ocean Acidification and the Loss of Phenolic Substances in Marine Plants

Cited by 160 publications

References 54 publications

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO2 Gradient

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO2 Gradient

A novel in situ system to evaluate the effect of high CO2 on photosynthesis and biochemistry of seaweeds

Twenty-first century climate change and submerged aquatic vegetation in a temperate estuary: the case of Chesapeake Bay

Contact Info

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Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO₂ Gradient

Decline in Coccolithophore Diversity and Impact on Coccolith Morphogenesis Along a Natural CO₂ Gradient