The roles of carbonate, borate, and bicarbonate ions in affecting zooplankton hatching success under ocean acidification

IF 3 3区 地球科学 Q2 CHEMISTRY, MULTIDISCIPLINARY
John P. Christensen
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引用次数: 0

Abstract

Two ocean acidification studies about egg hatching success (HS) in geographically important marine copepods, Calanus finmarchicus and C. helgolandicus, were reanalyzed with improved statistical procedures. The new results at low and moderate levels of seawater acidification showed no HS inhibition at normal habitat temperatures but statistically significant inhibition at warmer and colder temperatures. These HS results were compared with seawater carbonate system and borate concentrations from precise seawater measurements. The temperature dependent differences in HS could not be directly explained by changes in the seawater concentrations of either H+, bicarbonate (HCO3), or CO2* (CO2* being the sum of unhydrated CO2 and H2CO3). In contrast, HS differences did match trends in seawater carbonate (CO32−) concentrations. A numerical model was developed which evaluates the concentrations of O2 or CO2*, HCO3, and CO32− at the cellular level across an egg and embryo by considering both gas diffusion with the seawater and respiration by the embryo. Again, temperature-dependent trends in HS could not be explained changes in intracellular CO2* or HCO3 concentrations, but HS did trend with the changes in intracellular CO32− concentrations. Carbonate ions form strong coordination complexes with metals, so acidification-driven decreases in external seawater carbonate concentrations, which are amplified at warmer temperatures, could release injurious metals, thus driving the HS inhibition at warmer temperatures. Increases in cytoplasmic carbonate concentrations at warmer temperatures caused by seawater acidification could complex with biochemically-needed nutrient-type metals within the cells, also causing the increased HS inhibition at warmer temperatures. Furthermore, boron is essential in chemically signaling within and between cells. Seawater borate concentrations were closely correlated with HS inhibition via Michaelis-Menton equations, suggesting that acidification-driven decreases in seawater borate concentrations may also inhibit HS. Finally, the acidification-driven increases in CO2 diffusion into cells dramatically increased intracellular bicarbonate concentrations. At mild levels of seawater acidification, an organism might compensate by exporting bicarbonate from the cells to the haemolymph and then to the seawater. Although the energetic cost, as percentage of ATP production, might be high, increased respiration rates at warmer temperatures might better allow the organism to survive. However, as temperature is lowered, the cellular respiration rate declines more rapidly with respect to temperature than does the gas diffusion coefficient. Consequently, bicarbonate accumulation driven by inward CO2 diffusion might overwhelm the egg's bicarbonate export capacity at colder temperatures, explaining the colder temperature HS inhibition.

海洋酸化条件下,碳酸盐、硼酸盐和碳酸氢盐离子对浮游动物孵化成功的影响
利用改进的统计程序重新分析了两项关于地理上重要的海洋桡足类Calanus finmarchicus和C.helgolandicus卵孵化成功(HS)的海洋酸化研究。在低和中等海水酸化水平下的新结果显示,在正常栖息地温度下没有HS抑制作用,但在温暖和寒冷的温度下具有统计学意义的抑制作用。将这些HS结果与精确海水测量的海水碳酸盐体系和硼酸盐浓度进行了比较。HS的温度依赖性差异不能通过海水中H+、碳酸氢盐(HCO3−)或CO2*(CO2*是未水合CO2和H2CO3的总和)浓度的变化直接解释。相反,HS差异确实与海水碳酸盐(CO32-)浓度的趋势相匹配。开发了一个数值模型,通过考虑气体与海水的扩散和胚胎的呼吸,评估卵子和胚胎细胞水平上O2或CO2*、HCO3−和CO32-的浓度。同样,HS的温度依赖性趋势不能解释细胞内CO2*或HCO3−浓度的变化,但HS确实随着细胞内CO32-浓度的变化而变化。碳酸盐离子与金属形成强烈的配位络合物,因此酸化导致的外部海水碳酸盐浓度的降低(在更高的温度下被放大)可能会释放有害金属,从而在更高温度下驱动HS抑制。海水酸化导致的高温下细胞质碳酸盐浓度的增加可能与细胞内生化所需的营养型金属复合,也会导致高温下HS抑制作用的增加。此外,硼在细胞内部和细胞之间的化学信号传导中是必不可少的。通过Michaelis-Menton方程,海水硼酸盐浓度与HS抑制密切相关,表明酸化驱动的海水硼酸盐含量降低也可能抑制HS。最后,酸化驱动的CO2扩散到细胞中的增加显著增加了细胞内碳酸氢盐的浓度。在轻度海水酸化的情况下,生物体可能会通过将细胞中的碳酸氢盐输出到血淋巴,然后再输出到海水中来进行补偿。尽管能量成本(占ATP产生的百分比)可能很高,但在更高的温度下增加呼吸速率可能会更好地使生物体存活。然而,随着温度的降低,细胞呼吸速率相对于温度的下降速度比气体扩散系数的下降速度更快。因此,在较冷的温度下,由向内CO2扩散驱动的碳酸氢盐积累可能会超过鸡蛋的碳酸氢根输出能力,这解释了较冷温度HS的抑制作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Marine Chemistry
Marine Chemistry 化学-海洋学
CiteScore
6.00
自引率
3.30%
发文量
70
审稿时长
4.5 months
期刊介绍: Marine Chemistry is an international medium for the publication of original studies and occasional reviews in the field of chemistry in the marine environment, with emphasis on the dynamic approach. The journal endeavours to cover all aspects, from chemical processes to theoretical and experimental work, and, by providing a central channel of communication, to speed the flow of information in this relatively new and rapidly expanding discipline.
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