Occurrence, distribution, and localisation of metals in cnidarians

Marshall, A.T.

doi:10.1002/jemt.10035

Cited by 26 publications

(12 citation statements)

References 93 publications

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“…The tissue enrichment of Fe in all these species may be attributed to the biological role of Fe in various enzymatic functions. Iron is an essential element required by certain enzymes and proteins that carry electron during photosynthesis and (Marshall, 2002). High concentrations of Fe observed in the skeletal phase of P. andrewsi, compared to relatively less concentrations within its tissue, may be pointed towards the usefulness of this species as an indicator organism to monitor anthropogenic loads of iron in coral ecosystems.…”

Section: Resultsmentioning

confidence: 96%

Monitoring of heavy metal partitioning in reef corals of Lakshadweep Archipelago, Indian Ocean

Gopinath¹,

Kumar

Jayalakshmi

et al. 2006

Environ Monit Assess

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This paper focuses on the partitioning of trace metals in five selected coral species from Lakshadweep Archipelago, which remains as one of the least studied areas in the Indian Ocean. Based on the morphological features, selected coral species are classified as massive (Porites andrewsi), ramose or branching (Lobophyllia corymbosa, Acropora formosa and Psammocora contigua) and foliaceous (Montipora digitata). Relating trace metal concentrations with morphological features in skeleton, highest concentrations of all the trace metals (except Zn) were reported for the ramose type corals. In tissue, all the metals (essential as well as non essential) showed highest concentrations within the branching type corals. Irrespective of their growth characteristics/pattern, all species except P. contigua displayed higher concentrations of Pb, Ni, Mn and Cd within their skeleton compared to tissue which may exemplify a regulatory mechanism to avoid the build up of the concentrations of these metals in their bio-part, strikingly toxic metals like Cd and Pb. The concentrations of trace metals in the skeleton and tissues of these coral species were subjected to 3 way ANOVA based on non standardized original data and the results showed significant differences between metals and between species leading to high skeleton/ tissue - species interaction as well as skeleton/tissue - metal interaction. The significant values of student's t calculated are depicted in the form of Trellis diagrams.

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Section: Resultsmentioning

confidence: 96%

Monitoring of heavy metal partitioning in reef corals of Lakshadweep Archipelago, Indian Ocean

Gopinath¹,

Kumar

Jayalakshmi

et al. 2006

Environ Monit Assess

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“…Corrège (2006) calculated similar results in an up-to-date summary of published Sr/Ca vs SST calibrations for Porites. Some of the 'noise' in analyses may reflect vital effects wherein trace-element distributions correlate directly to microstructural patterns (e.g., Cohen et al 2001;Marshall 2002;Rollion-Bard et al 2003;Allison and Finch 2004;Meibom et al 2004;2006), but other noise could be produced by sampling non-sequential or inappropriately time-averaged data. Confidence in paleoclimate reconstruction requires a better understanding of all factors that may contribute to measured chemical signatures and to their spatial heterogeneity, and such understanding is particularly important as technology allows increasingly finer sampling resolutions.…”

Section: Introductionmentioning

confidence: 99%

Microstructure of common reef-building coral genera Acropora, Pocillopora, Goniastrea and Porites: constraints on spatial resolution in geochemical sampling

Nothdurft

Webb

2006

Facies

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Scleractinian corals are increasingly used as recorders of modern and paleoclimates. The microstructure of four common reef-building coral genera is documented here: Acropora, Pocillopora, Goniastrea, and Porites. This study highlights the complexity and spatial variability of skeletal growth in different coral genera and suggests that a single growth model is too generalized to allow the accurate depiction of the variability observed in the four genera studied. New models must be introduced in order for coral skeletogenesis to be understood adequately to allow coral skeletons to serve as repositories of temporally constrained geochemical data. Owing to differences in microstructural patterns in different genera, direct observation of microstructural elements and growth lines may be necessary to allow microsamples to be placed into series that represent temporal sequences with known degrees of time averaging. Such data are critical for constraining microsampling strategies aimed at developing true time series geochemical data at very fine spatial and temporal scales.

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“…Individual aragonite 'crystals' are precipitated in a 'hydro-organic gel' Cuif and Dauphin 2005) and are arranged into macroscopic skeletal elements, such as walls, septa, and dissepiments as controlled by the distribution of the ectoderm and organic molecules at various scales of interaction down to nanometer-scale organization within individual 'crystals' Cuif and Dauphin 2005;Stolarski and Mazur 2005;Przenioslo et al 2008). Trace elements within coral skeletons that are of interest as palaeoenvironmental proxies are thought to be derived primarily from ambient seawater, but with acknowledged vital eVects of the polyp and/or symbiotic algae (e.g., Marshall 2002). Regardless, the experimental correlation of stable isotopes and elemental ratios such as Sr/Ca, Mg/Ca, and U/Ca between coral skeletons and the temperature of ambient seawater forms the basis for sea surface temperature (SST) proxies (e.g., Beck et al 1992;de Villiers et al 1995;Mitsuguchi et al 1996;Grottoli and Eakin 2007).…”

Section: Introductionmentioning

confidence: 99%

“…Although evidence increasingly suggests that trace-element distributions in coral skeletons are heterogeneous at very Wne scales, possibly reXecting poorly understood vital eVects in part (Cohen et al 2002;Marshall 2002;Meibom et al 2003Meibom et al , 2004Meibom et al , 2006Meibom et al , 2008Allison et al 2005;Shirai et al 2005;Sinclair 2005; Stolarski and Mazur 2005;Gaetani and Cohen 2006;Sinclair and Risk 2006;, coral skeletons can provide useful palaeoenvironmental proxies provided: (1) original trace-element and stable-isotope inventories have not been altered by diagenesis; and (2) sample sizes and spatial resolution are adequately understood (e.g., . Hence, coral skeletons are routinely vetted prior to analysis to check for diagenetic alteration, such as recrystallization of skeletal aragonite to calcite (e.g., Enmar et al 2000;McGregor and Gagan 2003;Quinn and Taylor 2006), on the general assumption that coral skeleton that has not been exposed to freshwater (meteoric) diagenesis should retain reliable marine trace-element inventories.…”

Section: Introductionmentioning

confidence: 99%

Earliest diagenesis in scleractinian coral skeletons: implications for palaeoclimate-sensitive geochemical archives

Nothdurft

Webb

2008

Facies

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Live-collected samples of four common reefbuilding coral genera (Acropora, Pocillopora, Goniastrea, Porites) from subtidal and intertidal settings of Heron Reef, Great Barrier Reef, show extensive early marine diagenesis where parts of the coralla less than 3 years old contain abundant macro-and microborings and aragonite, high-Mg calcite, low-Mg calcite, and brucite cements. Many types of cement are associated directly with microendoliths and endobionts that inhabit parts of the corallum recently abandoned by coral polyps. The occurrence of cements that generally do not precipitate in normal shallow seawater (e.g., brucite, low-Mg calcite) highlights the importance of microenvironments in coral diagenesis. Cements precipitated in microenvironments may not reXect ambient seawater chemistry. Hence, geochemical sampling of these cements will contaminate trace-element and stable-isotope inventories used for palaeoclimate and dating analysis. Thus, great care must be taken in vetting samples for both bulk and microanalysis of geochemistry. Visual inspection using scanning electron microscopy may be required for vetting in many cases.

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Occurrence, distribution, and localisation of metals in cnidarians

Cited by 26 publications

References 93 publications

Monitoring of heavy metal partitioning in reef corals of Lakshadweep Archipelago, Indian Ocean

Monitoring of heavy metal partitioning in reef corals of Lakshadweep Archipelago, Indian Ocean

Microstructure of common reef-building coral genera Acropora, Pocillopora, Goniastrea and Porites: constraints on spatial resolution in geochemical sampling

Earliest diagenesis in scleractinian coral skeletons: implications for palaeoclimate-sensitive geochemical archives

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