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在长期盐胁迫下,四个油橄榄品种脯氨酰 4-羟化酶、阿拉伯半乳聚糖蛋白和同型半乳糖醛酸聚糖的响应与生理和形态变化的关系。

Response of Prolyl 4 Hydroxylases, Arabinogalactan Proteins and Homogalacturonans in Four Olive Cultivars under Long-Term Salinity Stress in Relation to Physiological and Morphological Changes.

机构信息

Department of Horticultural Genetics & Biotechnology, Mediterranean Agronomic Institute of Chania, Alsyllion Agrokipiou, 73100 Chania, Greece.

Department of Botany, Faculty of Biology, University of Athens, 15784 Athens, Greece.

出版信息

Cells. 2023 May 24;12(11):1466. doi: 10.3390/cells12111466.

DOI:10.3390/cells12111466
PMID:37296587
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10252747/
Abstract

Olive ( L.) salinity stress induces responses at morphological, physiological and molecular levels, affecting plant productivity. Four olive cultivars with differential tolerance to salt were grown under saline conditions in long barrels for regular root growth to mimic field conditions. Arvanitolia and Lefkolia were previously reported as tolerant to salinity, and Koroneiki and Gaidourelia were characterized as sensitive, exhibiting a decrease in leaf length and leaf area index after 90 days of salinity. Prolyl 4-hydroxylases (P4Hs) hydroxylate cell wall glycoproteins such as arabinogalactan proteins (AGPs). The expression patterns of and under saline conditions showed cultivar-dependent differences in leaves and roots. In the tolerant cultivars, no changes in P4H and AGP mRNAs were observed, while in the sensitive cultivars, the majority of P4Hs and AGPs were upregulated in leaves. Immunodetection showed that the AGP signal intensity and the cortical cell size, shape and intercellular spaces under saline conditions were similar to the control in Arvanitolia, while in Koroneiki, a weak AGP signal was associated with irregular cells and intercellular spaces, leading to aerenchyma formation after 45 days of NaCl treatment. Moreover, the acceleration of endodermal development and the formation of exodermal and cortical cells with thickened cell walls were observed, and an overall decrease in the abundance of cell wall homogalacturonans was detected in salt-treated roots. In conclusion, Arvanitolia and Lefkolia exhibited the highest adaptive capacity to salinity, indicating that their use as rootstocks might provide increased tolerance to irrigation with saline water.

摘要

油橄榄(L.)盐胁迫会在形态、生理和分子水平上引起响应,从而影响植物的生产力。为了模拟田间条件,让根系正常生长,将具有不同耐盐性的四个橄榄品种种植在长桶中进行盐胁迫处理。此前,Arvanitolia 和 Lefkolia 被报道为耐盐品种,而 Koroneiki 和 Gaidourelia 则表现出敏感性,在盐胁迫 90 天后叶片长度和叶面积指数下降。脯氨酰 4-羟化酶(P4Hs)羟化细胞壁糖蛋白,如阿拉伯半乳聚糖蛋白(AGPs)。在叶片和根系中, 和 在盐胁迫下的表达模式表现出品种依赖性差异。在耐盐品种中,未观察到 P4H 和 AGP mRNAs 的变化,而在敏感品种中,大多数 P4Hs 和 AGPs 在叶片中上调。免疫检测显示,在 Arvanitolia 中,盐胁迫下的 AGP 信号强度和皮层细胞大小、形状和细胞间隙与对照相似,而在 Koroneiki 中,较弱的 AGP 信号与不规则的细胞和细胞间隙相关,导致在 NaCl 处理 45 天后形成通气组织。此外,还观察到内皮层发育加速,形成具有增厚细胞壁的外皮层和皮层细胞,以及盐处理根中细胞壁 homogalacturonans 丰度整体下降。综上所述,Arvanitolia 和 Lefkolia 对盐胁迫表现出最高的适应能力,表明它们作为砧木的使用可能会提高对盐水灌溉的耐受性。

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3
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4
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