Exogenous glycine betaine alleviates water-deficit stress in Indian pennywort (Centella asiatica) under greenhouse conditions.

IF 2.5 3区生物学 Q3 CELL BIOLOGY

Protoplasma Pub Date : 2024-07-01 Epub Date: 2024-01-11 DOI:10.1007/s00709-023-01919-6

Daonapa Chungloo, Rujira Tisarum, Thapanee Samphumphuang, Piyanan Pipatsitee, Thanyaporn Sotesaritkul, Suriyan Cha-Um

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Abstract

Centella asiatica (Indian pennywort) is a green leafy vegetable containing centelloside' (triterpenoid), a key phytochemical component in traditional medicine. Being a glycophytic species, they exhibit decline in growth performance and yield traits when subjected to water-deficit (WD) conditions. Glycine betaine (GB) is a low molecular-weight organic metabolite that plays a crucial role in abiotic stress conditions in higher plants. The objective of this study was to investigate the potential of GB in alleviating water-deficit stress (in terms of morphological and physiological responses) in two different genotypes of Indian pennywort, "Nakhon Pathom" (NP; high centelloside-yielding genotype) and "Pathum Thani" (PT; low centelloside-yielding genotype). The genotypes of Indian pennywort were propagated by stolon cutting and transplanted into plastic bags containing 2 kg of garden soil. At the flower-initiation stage (30 days after transplantation), uniform plant material was treated exogenously with 0 (control), 25, and 50 mM GB at 100 mL per plant (one-time foliar spray) and then divided into two groups, 1) well watered (WW; irrigated daily with 400 mL fresh water; 98% field capacity) and 2) water deficit (WD; withheld water for 14 days; 72% field capacity). Foliar application of GB (25 mM) significantly improved leaf osmotic potential in NP under WD conditions via osmotic adjustment by free proline and fructose. Differences in leaf temperature (T_leaf) between WD and WW in NP were maximized (+ 1.93 °C) and the gap of T_leaf was reduced in the case of 25-50 mM GB application. Similarly, crop water stress index (CWSI) in NP and PT plants under WD condition was significantly increased by 1.95- and 1.86-fold over the control, respectively; however, it was significantly decreased by exogenous GB application. Increasing T_leaf and CWSI in drought-stressed plants was closely related to stomatal closure, leading to reduced gas exchange parameters, i.e., stomatal conductance (g_s), transpiration rate (E), net photosynthetic rate (P_n), and intercellular CO₂ concentration (C_i), and consequently decreased plant biomass and total centelloside yield. Overall physiological, morphological, and secondary metabolite traits were enhanced in NP under WD conditions using 25 mM GB exogenous application compared with the control. The study highlights the significance of GB in Indian pennywort production under limited water irrigation (water deficit) with higher vegetable yield and phytochemical stabilization.

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外源甘氨酸甜菜碱可缓解温室条件下印度五色草（积雪草）的缺水胁迫。

积雪草（印度五味子）是一种绿叶蔬菜，含有积雪草苷（三萜类化合物），这是传统医学中的一种重要植物化学成分。作为一种糖叶植物，它们在缺水（WD）条件下会出现生长性能和产量特征下降。甘氨酸甜菜碱（GB）是一种低分子量的有机代谢物，在高等植物的非生物胁迫条件下起着至关重要的作用。本研究的目的是调查 GB 在缓解印度五色草两种不同基因型--"Nakhon Pathom"（NP；高产 centelloside 基因型）和 "Pathum Thani"（PT；低产 centelloside 基因型）--的缺水胁迫（形态和生理反应）方面的潜力。印度五色草的基因型通过匍匐茎切割繁殖，并移植到装有 2 公斤园土的塑料袋中。在始花期（移栽后 30 天），用 0（对照组）、25 和 50 mM GB（每株 100 mL，一次性叶面喷洒）对均匀的植物材料进行外源处理，然后将其分为两组：1）水分充足组（WW；每天用 400 mL 清水灌溉；田间灌溉能力 98%）和 2）水分亏缺组（WD；14 天内不给水；田间灌溉能力 72%）。在 WD 条件下，通过游离脯氨酸和果糖的渗透调节作用，叶面施用 GB（25 mM）能显著改善 NP 的叶片渗透势。在施用 25-50 毫摩尔 GB 的情况下，NP 中 WD 和 WW 的叶温（Tleaf）差异最大（+ 1.93 °C），Tleaf 的差距缩小。同样，在 WD 条件下，NP 和 PT 植物的作物水分胁迫指数（CWSI）分别比对照显著增加了 1.95 倍和 1.86 倍；但施用外源 GB 后，CWSI 显著降低。干旱胁迫植株叶片和CWSI的增加与气孔关闭密切相关，导致气体交换参数（即气孔导度（gs）、蒸腾速率（E）、净光合速率（Pn）和细胞间二氧化碳浓度（Ci））降低，进而导致植株生物量和总胞苷产量降低。与对照相比，外源施用 25 mM GB 的 NP 在 WD 条件下的整体生理、形态和次生代谢物性状均有所提高。该研究强调了在有限水灌溉（缺水）条件下使用 GB 对印度五色草生产的重要意义，它能提高蔬菜产量和植物化学物质的稳定性。

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来源期刊

Protoplasma 生物-细胞生物学

CiteScore

6.60

自引率

6.90%

发文量

审稿时长

4-8 weeks

期刊介绍： Protoplasma publishes original papers, short communications and review articles which are of interest to cell biology in all its scientific and applied aspects. We seek contributions dealing with plants and animals but also prokaryotes, protists and fungi, from the following fields: cell biology of both single and multicellular organisms molecular cytology the cell cycle membrane biology including biogenesis, dynamics, energetics and electrophysiology inter- and intracellular transport the cytoskeleton organelles experimental and quantitative ultrastructure cyto- and histochemistry Further, conceptual contributions such as new models or discoveries at the cutting edge of cell biology research will be published under the headings "New Ideas in Cell Biology".