Abstract
Abstract. That corals skeletons are built of aragonite crystals with taxonomy-linked ultrastructure has been well understood since the 19th century. Yet, the way by which corals control this crystallization process remains an unsolved question. Here, I outline a new conceptual model of coral biomineralisation that endeavours to relate known skeletal features with homeostatic functions beyond traditional growth (structural) determinants. In particular, I propose that the dominant physiological driver of skeletal extension is night-time hypoxia, which is exacerbated by the respiratory oxygen demands of the coral's algal symbionts (= zooxanthellae). The model thus provides a new narrative to explain the high growth rate of symbiotic corals, by equating skeletal deposition with the "work-rate" of the coral host needed to maintain a stable and beneficial symbiosis. In this way, coral skeletons are interpreted as a continuous (long-run) recording unit of the stability and functioning of the coral–algae endosymbiosis. After providing supportive evidence for the model across multiple scales of observation, I use coral core data from the Great Barrier Reef (Australia) to highlight the disturbed nature of the symbiosis in recent decades, but suggest that its onset is consistent with a trajectory that has been followed since at least the start of the 1900s. In concluding, I outline how the proposed capacity of cnidarians (which includes modern reef corals) to overcome the metabolic limitation of hypoxia via skeletogenesis also provides a new hypothesis to explain the sudden appearance in the fossil record of calcified skeletons at the Precambrian–Cambrian transition – and the ensuing rapid appearance of most major animal phyla.
Highlights
Background: prevailing concepts in coral biomineralisationCoral growth or skeletogenesis is driven by calcification, the process whereby calcium (Ca+2) and carbonate (CO−3 2) ions obtained from seawater precipitate beneath the calcioblastic ectoderm (CE) of the coral polyp to form crystals of the calcium carbonate (CaCO3) mineral polymorph, aragonite
No calcium oxalate has ever been identified within the aragonitic skeletons of corals it is important to note that the proposed precipitation of calcium oxalate is not envisioned as a skeletal building block, but rather to act as a nucleating seed crystal that initiates skeletogenesis, i.e. aragonite (CaCO3) crystal growth (Fig. 7)
This paper has proposed a new paradigm to explain coral biomineralisation, wherein the morphological attribute of skeletal extension has been linked to the physiological requirements of the coral host to ensure its metabolic status during periods of O2-limitation
Summary
Coral growth or skeletogenesis is driven by calcification, the process whereby calcium (Ca+2) and carbonate (CO−3 2) ions obtained from seawater precipitate beneath the calcioblastic ectoderm (CE) of the coral polyp to form crystals of the calcium carbonate (CaCO3) mineral polymorph, aragonite. The physiochemical outcome of this ion exchange is twofold: (i) by elevating the [Ca2+] and pH of the ECF, a higher aragonite saturation state ( arag) is achieved, promoting enhanced CaCO3 deposition rates, (ii) by transferring H+ into the seawater contained by the coelenteron cavity, the carbonic anhydrase (CA) mediated dehydration of bicarbonate (HCO−3 + H+ → CO2 + H2O) is facilitated, thereby increasing the potentially limiting supply of CO2(aq) for endosymbiont photosynthesis In this way, the biological functioning of the Ca2+-ATPase enzyme provides an indelible link between host calcification and zooxanthellae photosynthesis: autotrophic carbon products fuel the metabolic (respiratory) processes necessary to energise Ca2+-ATPase and promote. The precise mechanism(s) leading to the “dark” calcification phase of skeletogenesis remain equivocal, but is believed to be mediated by the dynamic behaviour of the of the CE, including: (i) the secretion of cellular products needed for the biological formation of a structural organic matrix (Johnston, 1980; Clode and Marshall, 2002) and (ii) the formation of small pockets of uplifted tissue into which the incipient skeletal framework extends (Barnes, 1970; Raz-Bahat et al, 2006)
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