Depth specialization in mesophotic corals (
            <i>Leptoseris</i>
            spp.) and associated algal symbionts in Hawai'i

Pochon, Xavier; Forsman, ZH; Spalding, Heather L.; Padilla-Gamiño, JL; Smith, Christopher J.; Gates, RD

doi:10.1098/rsos.140351

Cited by 61 publications

(81 citation statements)

References 83 publications

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“…These include amplifications of the Pax-C intron (van Oppen et al 2001(van Oppen et al , 2004Márquez et al 2002;Richards et al 2008Richards et al , 2013, β-tubulin (Fukami et al 2004b;Stefani et al 2008a), ITS (Medina et al 1999;van Oppen et al 2000Diekmann et al 2001;Rodriguez-Lanetty and Hoegh-Guldberg 2002;Márquez et al 2003;Chen et al 2004;Vollmer and Palumbi 2004;Forsman et al 2005Forsman et al , 2006Forsman et al , 2009Forsman et al , 2010Forsman et al , 2015Wei et al 2006;Stefani et al 2011;Kitano et al 2013Kitano et al , 2014, and 28S rDNA Cuif et al 2003;Wolstenholme et al 2003). For regions that have not diverged considerably between paralogues, such as the ITS, mixed PCR products can be split into two dominant sequences based on phase reconstruction of forward and reverse chromatograms of distinct lengths (Flot and Tillier 2006;Flot et al 2006).…”

Section: The Rise Of Molecular Phylogenetic Methodsmentioning

confidence: 99%

“…The noncoding intergenic region identified by Fukami et al (2004a), for instance, was too variable to be aligned across all of Merulinidae (Huang et al 2011) and is not orthologous with the intergenic region (or the putative control region) in Acropora (van Oppen et al 2001;Wolstenholme 2004;Richards et al 2008Richards et al , 2013, Montipora (van Oppen et al 2004;Forsman et al 2010), Porites (Forsman et al 2009) or Agariciidae (Luck et al 2013;Pochon et al 2015). These fast-evolving mitochondrial markers remain useful for phylogenetic studies among closely-related species.…”

Section: The Rise Of Molecular Phylogenetic Methodsmentioning

confidence: 99%

See 1 more Smart Citation

The New Systematics of Scleractinia: Integrating Molecular and Morphological Evidence

Kitahara

Fukami

Benzoni

et al. 2016

The Cnidaria, Past, Present and Future

102

100

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The taxonomy of scleractinian corals has traditionally been established based on morphology at the "macro" scale since the time of Carl Linnaeus. Taxa described using macromorphology are useful for classifying the myriad of growth forms, yet new molecular and small-scale morphological data have challenged the natural historicity of many familiar groups, motivating multiple revisions at every taxonomic level. In this synthesis of scleractinian phylogenetics and systematics, we present the most current state of affairs in the field covering both zooxanthellate and azooxanthellate taxa, focusing on the progress of our phylogenetic understanding of this ecologically-significant clade, which today is supported by rich sets of molecular and morphological data. It is worth noting that when DNA sequence data was first used to investigate coral evolution in the 1990s, there was no concerted effort to use phylogenetic information to delineate problematic taxa. In the last decade, however, the incompatibility of coral taxonomy with their evolutionary history has become much clearer, as molecular analyses for corals have been improved upon technically and expanded to all major scleractinian clades, shallow and deep. We describe these methodological developments and summarise new taxonomic revisions based on robust inferences of the coral tree of life. Despite these efforts, there are still unresolved sections of the scleractinian phylogeny, resulting in uncertain taxonomy for several taxa. We highlight these and propose a way forward for the taxonomy of corals.

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Section: The Rise Of Molecular Phylogenetic Methodsmentioning

confidence: 99%

Section: The Rise Of Molecular Phylogenetic Methodsmentioning

confidence: 99%

The New Systematics of Scleractinia: Integrating Molecular and Morphological Evidence

Kitahara

Fukami

Benzoni

et al. 2016

The Cnidaria, Past, Present and Future

102

100

View full text Add to dashboard Cite

show abstract

“…samples selected in this study were a subset of a more detailed host/symbiont genetic study (Pochon et al 2015). To address the high cryptic diversity in the genus Leptoseris (Luck et al 2013), we used the fast-evolving mitochondrial marker cox1-1-rRNA intron to assign host species following the protocol of Luck et al (2013).…”

Section: Coral and Symbiont Geneticsmentioning

confidence: 99%

Fluorescent proteins in dominant mesophotic reef-building corals

Röth¹,

Padilla-Gamiño²,

Pochon³

et al. 2015

Mar. Ecol. Prog. Ser.

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Reef-building corals inhabiting the mesophotic zone (30−150 m) not only survive but thrive in light-limiting environments. Similar to shallow corals, mesophotic corals also exhibit coral fluorescence. Because fluorescent proteins (FPs) absorb high-energy light and emit lowerenergy light, FPs could play an important role in mesophotic coral physiology and ecology. For 4 species of the Hawaiian mesophotic reef-building coral Leptoseris (65−125 m), we investigated the abundance of fluorescent morphs, types of FPs, fluorescence emission phenotypes, and the physiological relationship between coral fluorescence and endosymbiotic Symbiodinium (dinoflagellate; Dinophyta). Cyan/green coral fluorescence emission was widespread in mesophotic Leptoseris spp.; more than 70% of corals fluoresced, yet fluorescent and nonfluorescent corals cooccurred at all depths investigated. Coral fluorescence was attributed to 2 proteins, a cyan fluorescent protein (CFP, λ ex = 424 nm, λ em = 490 nm) and a green fluorescent protein (GFP, λ ex = 478 nm, λ em = 502 nm). The type of FP in Leptoseris colonies was correlated with depth; CFP was dominant in corals from shallower depths (65−85 m), GFP was dominant in corals from deeper depths (96−125 m), and CFP and GFP were present in corals from middle depths (86−95 m). Coral FP emission was primarily localized in the coenosarc and/or the oral disc. Symbiodinium from corals with and without fluorescence emission had similar genotypes, abundances, photosynthetic pigments, photosynthetic efficiencies, photosynthetic rates, and chlorophyll excitation spectra. As such, it is unlikely that these FPs play a significant role in enhancing symbiont photosynthesis. The high abundance of fluorescent morphs (> 70%) dominating this energetically limited environment may suggest that FPs play an integral and conserved physiological role in corals.

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“…Photosymbiotic corals, however, occur much deeper than the 30 m broadly recognized as the lower depth limit of reefs (e.g., Fricke and Meischner 1985;Bridge et al 2011). Below 30 m, where light attenuation is stronger, zooxanthellate corals can still form reefs and many zooxanthellate species are known below the depth limit of 100 m (e.g., Dinesen 1980;Pochon et al 2015). The deepest zooxanthellates occur even below 150 m, as in the case of Leptoseris papyracea (e.g., Lesser et al 2009;Slattery et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Deep in shadows, deep in time: the oldest mesophotic coral ecosystems from the Devonian of the Holy Cross Mountains (Poland)

et al. 2017

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Depth specialization in mesophotic corals ( Leptoseris spp.) and associated algal symbionts in Hawai'i

Cited by 61 publications

References 83 publications

The New Systematics of Scleractinia: Integrating Molecular and Morphological Evidence

The New Systematics of Scleractinia: Integrating Molecular and Morphological Evidence

Fluorescent proteins in dominant mesophotic reef-building corals

Deep in shadows, deep in time: the oldest mesophotic coral ecosystems from the Devonian of the Holy Cross Mountains (Poland)

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