A Whole Plant Analysis of Chloride and Sodium Exclusion Using a Range of Grapevine Rootstock Genotypes

IF 2.5 3区 农林科学 Q3 FOOD SCIENCE & TECHNOLOGY Australian Journal of Grape and Wine Research Pub Date : 2024-05-17 DOI:10.1155/2024/5313158
R. R. Walker, D. H. Blackmore, J. D. Dunlevy, P. R. Clingeleffer, A. R. Walker
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Abstract

Background and Aims. Salt exclusion is an important attribute for wine grapes since many countries have limits to the concentration of sodium (Na+) and/or chloride (Cl) tolerated in wine. The aim was to investigate whole plant capacity for Na+ and Cl‾ exclusion and the within-plant partitioning of accumulated ions to better understand these important salt tolerance traits. Methods and Results. Rooted cuttings of 140 Ruggeri and K51-40 (good and poor shoot Cl excluders, respectively) and five hybrids from a cross between the two genotypes were used. When challenged with salinity, 140 Ruggeri limited the accumulation of Cl and Na+ in the stem, petioles, and laminae and had a significantly lower whole plant concentration of Cl and Na+ when compared to K51-40. The latter indicates that 140 Ruggeri accumulates less Cl and Na+ than K51-40 by a lower uptake or a potentially greater efflux by roots, or both. While K51-40 accumulated significantly more Na+, it was able to retrieve it from the xylem; store it in the roots, stem, and petiole; and keep the lamina concentration comparable to that of 140 Ruggeri. Petioles of all genotypes appeared to play a role in limiting Cl accumulation in laminae and particularly for K51-40, to limit Na+ accumulation in laminae. Conclusions. The grapevine capacity for Cl and Na+ exclusion can be defined primarily as the lower net accumulation on a whole plant basis, reflecting the difference between the uptake and any efflux that may occur. Lower root to shoot transport is a key factor in shoot Cl and Na+ exclusion. Petiole accumulation assists in limiting the Cl and Na+ accumulation in the laminae. Significance of the Study. The study addressed the knowledge gap by examining Cl and Na+ exclusion on a whole plant basis, highlighting a range of within-plant mechanisms that act in limiting the accumulation of both ions in the laminae.

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利用一系列葡萄根茎基因型对氯化物和钠的排出进行全株分析
背景和目的。排盐是酿酒葡萄的一个重要特性,因为许多国家对葡萄酒中钠(Na+)和/或氯(Cl-)的耐受浓度有限制。本研究旨在调查整株葡萄对 Na+ 和 Cl‾ 的排盐能力以及累积离子在植株内部的分配情况,以更好地了解这些重要的耐盐特性。方法和结果使用了 140 Ruggeri 和 K51-40(分别具有良好和较差的芽Cl-排除能力)以及这两种基因型杂交产生的五个杂交种的生根插条。与 K51-40 相比,140 Ruggeri 在盐度条件下限制了 Cl- 和 Na+ 在茎干、叶柄和叶片中的积累,其全株 Cl- 和 Na+ 浓度明显较低。后者表明,140 Ruggeri 比 K51-40 积累的 Cl- 和 Na+ 更少,原因是根系吸收较少或外流较多,或两者兼而有之。虽然 K51-40 积累的 Na+ 明显多于 140 Ruggeri,但它能从木质部吸收 Na+,将其储存在根、茎和叶柄中,并保持叶片浓度与 140 Ruggeri 相当。所有基因型的叶柄似乎都能限制叶片中 Cl- 的积累,尤其是 K51-40 能限制叶片中 Na+ 的积累。结论。葡萄对 Cl- 和 Na+ 的排除能力主要可以定义为全株较低的净积累量,反映了可能发生的吸收和外流之间的差异。较低的根部至嫩枝运输量是嫩枝排除 Cl- 和 Na+ 的关键因素。叶柄的积累有助于限制叶片中 Cl- 和 Na+ 的积累。研究的意义。该研究从整个植物的角度研究了 Cl- 和 Na+ 的排斥作用,突出了植物内部限制这两种离子在叶片中积累的一系列机制,从而填补了知识空白。
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来源期刊
CiteScore
5.30
自引率
7.10%
发文量
35
审稿时长
3 months
期刊介绍: The Australian Journal of Grape and Wine Research provides a forum for the exchange of information about new and significant research in viticulture, oenology and related fields, and aims to promote these disciplines throughout the world. The Journal publishes results from original research in all areas of viticulture and oenology. This includes issues relating to wine, table and drying grape production; grapevine and rootstock biology, genetics, diseases and improvement; viticultural practices; juice and wine production technologies; vine and wine microbiology; quality effects of processing, packaging and inputs; wine chemistry; sensory science and consumer preferences; and environmental impacts of grape and wine production. Research related to other fermented or distilled beverages may also be considered. In addition to full-length research papers and review articles, short research or technical papers presenting new and highly topical information derived from a complete study (i.e. not preliminary data) may also be published. Special features and supplementary issues comprising the proceedings of workshops and conferences will appear periodically.
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