Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa

Corals and their photosymbionts experience inherent changes in light along depth gradients, leading them to have evolved several well-investigated photoacclimation strategies. As coral calcification is influenced by light (a process described as LEC—‘light-enhanced calcification’), studies have soug...

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Main Authors: Gal Eyal, Itay Cohen, Lee Eyal-Shaham, Or Ben-Zvi, Yaron Tikochinski, Yossi Loya
Format: Article
Language:English
Published: The Royal Society 2019-02-01
Series:Royal Society Open Science
Subjects:
Online Access:https://royalsocietypublishing.org/doi/pdf/10.1098/rsos.180527
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spelling doaj-0884bf0085c5425493621ce3ee25164e2020-11-25T04:02:08ZengThe Royal SocietyRoyal Society Open Science2054-57032019-02-016210.1098/rsos.180527180527Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisaGal EyalItay CohenLee Eyal-ShahamOr Ben-ZviYaron TikochinskiYossi LoyaCorals and their photosymbionts experience inherent changes in light along depth gradients, leading them to have evolved several well-investigated photoacclimation strategies. As coral calcification is influenced by light (a process described as LEC—‘light-enhanced calcification’), studies have sought to determine the link between photosynthesis and calcification, but many puzzling aspects still persist. Here, we examine the physiology of Euphyllia paradivisa, a coral species found at a wide range of depths but that is strictly mesophotic in the Red Sea; and also examines the coupling between photosynthesis and LEC by investigating the response of the coral under several controlled light regimes during a long-term experiment. E. paradivisa specimens were collected from 40 to 50 m depth and incubated under three light conditions for a period of 1 year: full-spectrum shallow-water light (approx. 3 m, e.g. shallow-light treatment); blue deep-water light (approx. 40 m, e.g. mesophotic-light treatment) or total darkness (e.g. dark treatment). Net photosynthesis remained similar in the shallow-light-treated corals compared to the mesophotic-light-treated corals, under both low and high light. However, calcification increased dramatically with increasing light intensity in the shallow-light-treated corals, suggesting a decoupling between these processes. Photoacclimation to shallow-water conditions was indicated by enhanced respiration, a higher density of zooxanthellae per polyp and lower chlorophyll a content per cell. The dark-treated corals became completely bleached but did not lower their metabolism below that of the mesophotic-light-treated corals. No Symbiodinium clade shift was found following the year-long light treatments. We conclude that E. paradivisa, and its original symbiont clade, can adapt to various light conditions by controlling its metabolic rate and growth energy investment, and consequently induce LEC.https://royalsocietypublishing.org/doi/pdf/10.1098/rsos.180527coral reefsmesophotic coral ecosystemsred seaphotosynthesislight-enhanced calcificationtwilight zone
collection DOAJ
language English
format Article
sources DOAJ
author Gal Eyal
Itay Cohen
Lee Eyal-Shaham
Or Ben-Zvi
Yaron Tikochinski
Yossi Loya
spellingShingle Gal Eyal
Itay Cohen
Lee Eyal-Shaham
Or Ben-Zvi
Yaron Tikochinski
Yossi Loya
Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa
Royal Society Open Science
coral reefs
mesophotic coral ecosystems
red sea
photosynthesis
light-enhanced calcification
twilight zone
author_facet Gal Eyal
Itay Cohen
Lee Eyal-Shaham
Or Ben-Zvi
Yaron Tikochinski
Yossi Loya
author_sort Gal Eyal
title Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa
title_short Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa
title_full Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa
title_fullStr Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa
title_full_unstemmed Photoacclimation and induction of light-enhanced calcification in the mesophotic coral Euphyllia paradivisa
title_sort photoacclimation and induction of light-enhanced calcification in the mesophotic coral euphyllia paradivisa
publisher The Royal Society
series Royal Society Open Science
issn 2054-5703
publishDate 2019-02-01
description Corals and their photosymbionts experience inherent changes in light along depth gradients, leading them to have evolved several well-investigated photoacclimation strategies. As coral calcification is influenced by light (a process described as LEC—‘light-enhanced calcification’), studies have sought to determine the link between photosynthesis and calcification, but many puzzling aspects still persist. Here, we examine the physiology of Euphyllia paradivisa, a coral species found at a wide range of depths but that is strictly mesophotic in the Red Sea; and also examines the coupling between photosynthesis and LEC by investigating the response of the coral under several controlled light regimes during a long-term experiment. E. paradivisa specimens were collected from 40 to 50 m depth and incubated under three light conditions for a period of 1 year: full-spectrum shallow-water light (approx. 3 m, e.g. shallow-light treatment); blue deep-water light (approx. 40 m, e.g. mesophotic-light treatment) or total darkness (e.g. dark treatment). Net photosynthesis remained similar in the shallow-light-treated corals compared to the mesophotic-light-treated corals, under both low and high light. However, calcification increased dramatically with increasing light intensity in the shallow-light-treated corals, suggesting a decoupling between these processes. Photoacclimation to shallow-water conditions was indicated by enhanced respiration, a higher density of zooxanthellae per polyp and lower chlorophyll a content per cell. The dark-treated corals became completely bleached but did not lower their metabolism below that of the mesophotic-light-treated corals. No Symbiodinium clade shift was found following the year-long light treatments. We conclude that E. paradivisa, and its original symbiont clade, can adapt to various light conditions by controlling its metabolic rate and growth energy investment, and consequently induce LEC.
topic coral reefs
mesophotic coral ecosystems
red sea
photosynthesis
light-enhanced calcification
twilight zone
url https://royalsocietypublishing.org/doi/pdf/10.1098/rsos.180527
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