Enhanced thermotolerance of photosystem II by elevated pore-water salinity in the coastal marsh graminoid Sporobolus pumilus

IF 1.3 4区生物学 Q3 MARINE & FRESHWATER BIOLOGY

Aquatic Biology Pub Date : 2020-09-03 DOI:10.3354/ab00730

B. Touchette, S. Schmitt, J. G. Moody

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引用次数: 1

Abstract

In coastal marsh ecosystems, high salinities, anoxic waterlogged soils, and elevated summer temperatures often promote physiological strain that results in only a few tolerant halophytic species. Although not well understood, plant physiological responses to multiple stressors can be complex and may involve intensifying or offsetting reactions. In this study, we investigated physiological responses to combined salinity and high temperature in the coastal marsh graminoid Sporobolus pumilus (syn. Spartina patens). Specifically, we considered changes in plant–water relations and Photosystem II (PSII) behavior (involving chlorophyll [chl] a fluorescence) in heatshocked plants that were acclimated to different salinities (0, 15, and 30 psu). Higher salinities fostered lower stomatal conductance (g), lower leaf-water potential (Ψleaf) and lower tissue-water content (θ), as well as decreased potential quantum yield (Fv/Fm) and decreased excitation energy capture efficiencies of open reaction centers (Fv’/Fm’). Heat-shocked plants acclimated to freshwater only had decreased Fv/Fm and PSII performance index (PIABS). Interestingly, there were no changes in chl a fluorescent outputs in heat-shocked plants acclimated to moderate salinities, and minimal changes in plants acclimated to high salinities. Approximately 25% of the heat-shocked S. pumilus in freshwater revealed a K-step in their polyphasic chl a fluorescent transients (OJIP procedure); K-steps were not observed in salt-treated plants. This suggests that, for plants residing in freshwater, heat-shock promoted disturbances in the PSII reaction centers and, in some cases, disrupted the oxygen-evolving complex. These PSII disruptions were either absent or less intense in salinity-treated plants, indicating that acclimation to environmental salts may provide PSII thermostability in S. pumilus.

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海岸带沼泽禾本科植物孢子虫孔隙水盐度提高光系统ⅱ耐热性

在沿海沼泽生态系统中，高盐度、缺氧涝渍土壤和夏季温度升高往往会促进生理应变，导致只有少数耐盐生植物物种。植物对多种应激源的生理反应可能是复杂的，可能包括强化或抵消反应。在这项研究中,我们调查了生理反应结合沿海沼泽禾草状的盐度和高温Sporobolus、(syn。摘要金属盘)。具体来说，我们考虑了适应不同盐度(0,15和30 psu)的热休克植物中植物-水关系和光系统II (PSII)行为(涉及叶绿素[chl]荧光)的变化。较高的盐度降低了气孔导度(g)、叶片水势(Ψleaf)和组织含水量(θ)，降低了潜在量子产率(Fv/Fm)和开放反应中心激发能捕获效率(Fv ' /Fm ')。仅适应淡水的热休克植物Fv/Fm和PSII性能指数(PIABS)下降。有趣的是，在适应中等盐度的热休克植物中，chl - a荧光输出没有变化，而在适应高盐度的植物中，chl - a荧光输出变化很小。在淡水中，大约25%的热休克小弧菌在其多相荧光瞬态(OJIP程序)中显示出k步;在盐处理植物中未观察到k -step。这表明，对于生活在淡水中的植物，热休克促进了PSII反应中心的干扰，在某些情况下，破坏了氧气进化复合物。这些PSII干扰在盐度处理的植物中要么不存在，要么不那么强烈，这表明对环境盐的适应可能提供了S. pumilus PSII的热稳定性。

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来源期刊

Aquatic Biology 生物-海洋与淡水生物学

CiteScore

2.70

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： AB publishes rigorously refereed and carefully selected Feature Articles, Research Articles, Reviews and Notes, as well as Comments/Reply Comments (for details see MEPS 228:1), Theme Sections, Opinion Pieces (previously called ''As I See It'') (for details consult the Guidelines for Authors) concerned with the biology, physiology, biochemistry and genetics (including the ’omics‘) of all aquatic organisms under laboratory and field conditions, and at all levels of organisation and investigation. Areas covered include: -Biological aspects of biota: Evolution and speciation; life histories; biodiversity, biogeography and phylogeography; population genetics; biological connectedness between marine and freshwater biota; paleobiology of aquatic environments; invasive species. -Biochemical and physiological aspects of aquatic life; synthesis and conversion of organic matter (mechanisms of auto- and heterotrophy, digestion, respiration, nutrition); thermo-, ion, osmo- and volume-regulation; stress and stress resistance; metabolism and energy budgets; non-genetic and genetic adaptation. -Species interactions: Environment–organism and organism–organism interrelationships; predation: defenses (physical and chemical); symbioses. -Molecular biology of aquatic life. -Behavior: Orientation in space and time; migrations; feeding and reproductive behavior; agonistic behavior. -Toxicology and water-quality effects on organisms; anthropogenic impacts on aquatic biota (e.g. pollution, fisheries); stream regulation and restoration. -Theoretical biology: mathematical modelling of biological processes and species interactions. -Methodology and equipment employed in aquatic biological research; underwater exploration and experimentation. -Exploitation of aquatic biota: Fisheries; cultivation of aquatic organisms: use, management, protection and conservation of living aquatic resources. -Reproduction and development in marine, brackish and freshwater organisms