A microsensor study of light enhanced Ca2+ uptake and photosynthesis in the reef-building hermatypic coral Favia sp.

Beer, Dirk de; Kühl, Michael; Stambler, Noga; Vaki, Lior

doi:10.3354/meps194075

Cited by 118 publications

(89 citation statements)

References 22 publications

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“…Temperature and pH (total scale) in the bulk seawater were measured using a micro-thermometer and a handheld pH meter (WTW pH 330i), respectively. pH LIX (precision 0.005), Ca 2+ LIX (precision 5 μM), and glass pH microelectrodes (precision 0.001) were prepared, calibrated and used as previously described (Ammann et al, 1987;De Beer, 2000;De Beer et al, 2000;Revsbech and Jorgensen, 1986). A detailed description of the measurement setup can be found in Polerecky et al (2007).…”

Section: Methodsmentioning

confidence: 99%

Calcification acidifies the microenvironment of a benthic foraminifer (Ammonia sp.)

Glas

Langer

Keul

2012

Journal of Experimental Marine Biology and Ecology

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Calcareous foraminifera are well known for their CaCO 3 shells. Yet, CaCO 3 precipitation acidifies the calcifying fluid. Calcification without pH regulation would therefore rapidly create a negative feedback for CaCO 3 precipitation. In unicellular organisms, like foraminifera, an effective mechanism to counteract this acidification could be the externalization of H + from the site of calcification. In this study we show that a benthic symbiont-free foraminifer Ammonia sp. actively decreases pH within its extracellular microenvironment only while precipitating calcite. During chamber formation events the strongest pH decreases occurred in the vicinity of a newly forming chamber (range of gradient~100 μm) with a recorded minimum of 6.31 (b 10 μm from the shell) and a maximum duration of 7 h. The acidification was actively regulated by the foraminifera and correlated with shell diameters, indicating that the amount of protons removed during calcification is directly related to the volume of calcite precipitated. The here presented findings imply that H + expulsion as a result of calcification may be a wider strategy for maintaining pH homeostasis in unicellular calcifying organisms.

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Section: Methodsmentioning

confidence: 99%

Calcification acidifies the microenvironment of a benthic foraminifer (Ammonia sp.)

Glas

Langer

Keul

2012

Journal of Experimental Marine Biology and Ecology

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“…Oxygen profiles were run at three positions in a random order along an axis perpendicular to the interaction boundary (i) apparently healthy Porites tissue 1 cm away from the interaction boundary ('coral'), (ii) the interface between Porites and the competitor ('interface'), and (iii) apparently healthy tissue of the competitor 1 cm away from the interface ('competitor'; electronic supplementary material, figure S1a). Measurements on coral tissue were exclusively conducted on the coenosarc (tissue between polyps) in order to minimize the influence of tissue movement [36] and the spatial heterogeneity of coral photosynthesis [25]. The microsensor was oriented vertically.…”

Section: (Iii) Microsensor Measurementsmentioning

confidence: 99%

Evidence for water-mediated mechanisms in coral–algal interactions

et al. 2016

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Although many coral reefs have shifted from coral-to-algal dominance, the consequence of such a transition for coral -algal interactions and their underlying mechanisms remain poorly understood. At the microscale, it is unclear how diffusive boundary layers (DBLs) and surface oxygen concentrations at the coral -algal interface vary with algal competitors and competitiveness. Using field observations and microsensor measurements in a flow chamber, we show that coral (massive Porites) interfaces with thick turf algae, macroalgae, and cyanobacteria, which are successful competitors against coral in the field, are characterized by a thick DBL and hypoxia at night. In contrast, coral interfaces with crustose coralline algae, conspecifics, and thin turf algae, which are poorer competitors, have a thin DBL and low hypoxia at night. Furthermore, DBL thickness and hypoxia at the interface with turf decreased with increasing flow speed, but not when thick turf was upstream. Our results support the importance of water-mediated transport mechanisms in coral-algal interactions. Shifts towards algal dominance, particularly dense assemblages, may lead to thicker DBLs, higher hypoxia, and higher concentrations of harmful metabolites and pathogens along coral borders, which in turn may facilitate algal overgrowth of live corals. These effects may be mediated by flow speed and orientation.

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“…A better comparison of experiments became possible through the use of microcolonies originating from the same parent colony (Al-Moghrabi et al, 1993). The new application of microsensors permitted the measurement of many parameters at a µm scale and with high spatial and temporal resolution (De Beer et al, 2000;Kühl et al, 1995;Al-Horani et al, 2003a;Al-Horani et al, 2003b;Al-Horani et al, 2005). In this study, the two advancements were combined to investigate the impact of temperature on the physiology of the scleractinian coral Galaxea fascicularis.…”

Section: Introductionmentioning

confidence: 99%

Effects of changing seawater temperature on photosynthesis and calcification in the scleractinian coral Galaxea fascicularis, measured with O2, Ca2+ and pH microsensors

Al‐Horani¹

2005

Sci. Mar.

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SUMMARY: Single polyps of Galaxea fascicularis were fixed to glass vials with underwater epoxy resin. After regeneration into microcolonies they were used for microsensor measurements of photosynthesis and calcification under different incubating temperatures. Gross photosynthesis was found highest at temperatures of 23 and 26ºC (ca. 0.022 mole O 2 m -3 s -1 ), close to the ambient temperature (i.e. 26ºC). At 35°C, gross photosynthesis was irreversibly inhibited as the microcolonies bleached. The net photosynthesis rapidly decreased with temperature and became negative at temperatures higher than 29ºC. Profiles of O 2 and Ca 2+ showed a strong effect of temperature on them. The concentrations of Ca 2+ measured on the polyp surface also showed temperature dependence of Ca 2+ uptake. In the dark and below 29ºC, the surface Ca 2+ concentration was temperature independent. During illumination, the surface Ca 2+ concentration showed a dip at 26 ºC (ca. 8.7 mM), indicating maximum uptake rates at ambient temperature. However, at 32ºC and higher, Ca 2+ was slightly higher at the tissue surface than in the seawater, in both light and dark, resulting from calcium dissolution. The surface pH in light increased gradually from 8.3 to 8.6 with increasing temperature to 23ºC, and thereafter remained constant to 29ºC. At 32 ºC, the pH became slightly acidic compared with the water phase, probably due to a decrease in the uptake of CO 2 by photosynthesis. The largest difference in pH between light and dark incubations was at temperatures between 23 and 29ºC (7.5-7.7 in dark versus 8.6-8.7 in light), which indicate high rates of photosynthesis and respiration in this temperature range . It is concluded that photosynthetic activity in the coral is maintained up to rather high temperatures (32ºC), but corals at super-optimum temperatures (above 26ºC) consume more O 2 than they produce, decalcify and produce CO 2 .Keywords: temperature, coral, gross photosynthesis, net photosynthesis, calcification, Galaxea fascicularis, microsensors.. RESUMEN: EFECTOS DEL CAMBIO EN LA TEMPERATURA DEL AGUA EN LA FOTOSÍNTESIS Y LA CALCIFICACIÓN DEL CORAL ESCLE-RACTINIARIO GALAXEA FASCICULARIS MEDIDOS CON MICROSENSORES DEO 2 , Ca 2+ Y pH. -Se fijaron pólipos de Galaxea fascicularis sobre viales de cristal con resina epoxy. Una vez generaron pequeñas colonias se utilizaron como sensores para medir los cambios en la fotosíntesis y calsificación a diferentes temperaturas. Los valores de fotosíntesis total (bruta) fueron más elevados a temperaturas entre 23 y 26°C (ca. 0,022 mole O 2 m -3 s -1 ), similares a los del ambiente (26°C). A valores de 35°C, la fotosíntesis total se inhibió irreversiblemente y las pequeñas colonias se blanquearon. La fotosíntesis neta disminuyó rápi-damente con la temperatura hasta llegar a valores negativos en temperaturas mayores de 29°C. Los perfiles de O 2 y Ca 2+ mostraron un elevado efecto de la temperatura. Las concentraciones de Ca 2+ medidas en la superficie de los pólipos también mostraron una influencia en la incorpo...

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A microsensor study of light enhanced Ca2+ uptake and photosynthesis in the reef-building hermatypic coral Favia sp.

Cited by 118 publications

References 22 publications

Calcification acidifies the microenvironment of a benthic foraminifer (Ammonia sp.)

Calcification acidifies the microenvironment of a benthic foraminifer (Ammonia sp.)

Evidence for water-mediated mechanisms in coral–algal interactions

Effects of changing seawater temperature on photosynthesis and calcification in the scleractinian coral <i>Galaxea fascicularis</i>, measured with O<sub>2</sub>, Ca<sup>2+</sup> and pH microsensors

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