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在文石不饱和的多种驱动因素下幼虫东部牡蛎的转录组到表型的响应

Transcriptome-To-Phenome Response of Larval Eastern Oysters Under Multiple Drivers of Aragonite Undersaturation.

作者信息

Gurr Samuel J, Meseck Shannon L, Bernatchez Genevieve, Redman Dylan, Dixon Mark S, Guy Lisa, MacDonald Aaron, Stiles Sheila, McFarland Katherine

机构信息

National Research Council Post-Doctoral Associate at NOAA National Marine Fisheries Service Northeast Fisheries Science Center Milford Connecticut USA.

NOAA, National Marine Fisheries Service Northeast Fisheries Science Center Milford Connecticut USA.

出版信息

Ecol Evol. 2025 Feb 11;15(2):e70953. doi: 10.1002/ece3.70953. eCollection 2025 Feb.

DOI:10.1002/ece3.70953
PMID:39944909
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11813985/
Abstract

Understanding how interactive environmental challenges affect marine species is critical to long-term ecological and economic stability under global change. Marine calcifiers are thought to be vulnerable to ocean acidification (OA; elevated CO); active dissolution of aragonite (Ω) is associated with disrupted development, survivorship, and gene expression in bivalve larvae, resulting in an early life-stage bottleneck. Dynamic carbonate chemistry in coastal systems emphasizes the importance of multiple stressors, e.g., warming and low salinity events may change organismal responses relative to OA alone. We exposed Eastern oyster larvae () to a full-factorial experimental design using two temperatures (23°C and 27°C), salinities (17 and 27), and CO levels (~700 μatm and 1850 μatm CO), resulting in Ω conditions 0.3-1.7. Ω reduced by low salinity, elevated CO, and low temperature, each slowed early development and reduced survival. Low salinity × elevated CO was linked to severe Ω undersaturation (< 0.5) that suppressed expression of bicarbonate transport, biomineralization and augmented expression for ciliary locomotion, proteostasis, and histone modifiers. In isolation and under moderate Ω intensity (0.5 < Ω < 1), larvae increased transcription for osmoregulatory activity and endocytosis under low salinity, and suppressed transcription for iron metabolism under elevated CO. Although shell growth and survival were affected by Ω undersaturation, gene expression patterns of D-stage oyster larvae and oyster juveniles suggests tolerance to dynamic estuarine environments. Genes and expression patterns that confer survival of postmetamorphosed oysters can improve our understanding of environmental-organismal interactions and improve breeding programs enabling sustainable production.

摘要

了解交互式环境挑战如何影响海洋物种对于全球变化下的长期生态和经济稳定至关重要。海洋钙化生物被认为易受海洋酸化(OA;二氧化碳浓度升高)的影响;文石(Ω)的活性溶解与双壳类幼虫发育受阻、存活率降低和基因表达紊乱有关,导致早期生命阶段出现瓶颈。沿海系统中动态的碳酸盐化学强调了多种压力源的重要性,例如,变暖和低盐度事件可能会改变相对于单独OA的生物体反应。我们采用全因子实验设计,将东部牡蛎幼虫暴露于两种温度(23°C和27°C)、盐度(17和27)和二氧化碳水平(约700 μatm和1850 μatm二氧化碳)下,导致Ω条件为0.3 - 1.7。低盐度、高二氧化碳和低温会降低Ω,每种情况都会减缓早期发育并降低存活率。低盐度×高二氧化碳与严重的Ω不饱和(< 0.5)有关,这抑制了碳酸氢盐转运、生物矿化的表达,并增强了纤毛运动、蛋白质稳态和组蛋白修饰剂的表达。在单独且中等Ω强度(0.5 < Ω < 1)下,幼虫在低盐度下增加了渗透调节活性和内吞作用的转录,并在高二氧化碳下抑制了铁代谢的转录。尽管壳生长和存活率受到Ω不饱和的影响,但D期牡蛎幼虫和牡蛎幼体的基因表达模式表明它们对动态河口环境具有耐受性。赋予变态后牡蛎存活能力的基因和表达模式可以增进我们对环境与生物体相互作用的理解,并改善育种计划以实现可持续生产。

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