海水 pCO2 和温度对珊瑚骨骼氨基酸组成和文石 CO3 紊乱的影响

IF 2.7 2区 生物学 Q1 MARINE & FRESHWATER BIOLOGY
Nicola Allison, Phoebe Ross, Cristina Castillo Alvarez, Kirsty Penkman, Roland Kröger, Celeste Kellock, Catherine Cole, Matthieu Clog, David Evans, Chris Hintz, Ken Hintz, Adrian A. Finch
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引用次数: 0

摘要

珊瑚骨骼是文石和生物大分子的复合体。我们报告了在两种温度(25 °C和28 °C)和三种海水pCO2(180、400和750 µatm)条件下培养的大块Porites属珊瑚骨骼中11种氨基酸的浓度。珊瑚骨骼中的天冬氨酸/天冬酰胺(Asx)、谷氨酸/谷氨酰胺(Glx)、甘氨酸、丝氨酸和总氨基酸浓度在 28 °C 时明显高于 25 °C 时。骨骼中的 Asx、Glx、Gly、Ser、Ala、L-Thr 和氨基酸总量在 180 微摄氏度海水 pCO2 条件下明显低于 400 微摄氏度海水 pCO2 条件下,Ser 在 180 微摄氏度海水 pCO2 条件下低于 750 微摄氏度海水 pCO2 条件下。所有骨骼氨基酸的浓度与珊瑚的钙化率呈明显的反比关系,但与钙化介质的 pH 值无关。对这些标本和其他标本进行的拉曼光谱分析表明,骨架文石晶格中的 CO3 紊乱不受海水 pCO2 的影响,但在较高温度下会减少。这与在合成文石中观察到的情况相反,在合成文石中,无序度与文石沉淀速率呈正相关,沉淀速率受温度升高(本研究)或Ω升高(本研究和之前的一份报告)以及沉淀介质中氨基酸浓度(之前的一份报告)的影响。我们观察到,结构紊乱与珊瑚钙化率或骨骼[氨基酸]之间没有明显关系。温度和海水 pCO2 都会对骨骼氨基酸组成产生重大影响,因此需要进一步研究来阐明环境变化如何介导结构紊乱。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The influence of seawater pCO2 and temperature on the amino acid composition and aragonite CO3 disorder of coral skeletons

The influence of seawater pCO2 and temperature on the amino acid composition and aragonite CO3 disorder of coral skeletons

Coral skeletons are composites of aragonite and biomolecules. We report the concentrations of 11 amino acids in massive Porites spp. coral skeletons cultured at two temperatures (25 °C and 28 °C) and 3 seawater pCO2 (180, 400 and 750 µatm). Coral skeletal aspartic acid/asparagine (Asx), glutamic acid/glutamine (Glx), glycine, serine and total amino acid concentrations are significantly higher at 28 °C than at 25 °C. Skeletal Asx, Glx, Gly, Ser, Ala, L-Thr and total amino acid are significantly lower at 180 µatm seawater pCO2 compared to 400 µatm, and Ser is reduced at 180 µatm compared to 750 µatm. Concentrations of all skeletal amino acids are significantly inversely related to coral calcification rate but not to calcification media pH. Raman spectroscopy of these and additional specimens indicates that CO3 disorder in the skeletal aragonite lattice is not affected by seawater pCO2 but decreases at the higher temperature. This is contrary to observations in synthetic aragonite where disorder is positively related to the aragonite precipitation rate mediated by either increasing temperature (this study) or increasing Ω (this study and a previous report) and to the concentration of amino acid in the precipitation media (a previous report). We observe no significant relationship between structural disorder and coral calcification rate or skeletal [amino acid]. Both temperature and seawater pCO2 can significantly affect skeletal amino acid composition, and further work is required to clarify how environmental change mediates disorder.

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来源期刊
Coral Reefs
Coral Reefs 生物-海洋与淡水生物学
CiteScore
6.80
自引率
11.40%
发文量
111
审稿时长
4-8 weeks
期刊介绍: Coral Reefs, the Journal of the International Coral Reef Society, presents multidisciplinary literature across the broad fields of reef studies, publishing analytical and theoretical papers on both modern and ancient reefs. These encourage the search for theories about reef structure and dynamics, and the use of experimentation, modeling, quantification and the applied sciences. Coverage includes such subject areas as population dynamics; community ecology of reef organisms; energy and nutrient flows; biogeochemical cycles; physiology of calcification; reef responses to natural and anthropogenic influences; stress markers in reef organisms; behavioural ecology; sedimentology; diagenesis; reef structure and morphology; evolutionary ecology of the reef biota; palaeoceanography of coral reefs and coral islands; reef management and its underlying disciplines; molecular biology and genetics of coral; aetiology of disease in reef-related organisms; reef responses to global change, and more.
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