Nanoparticles mitigate arsenic stress in plants by modulating defence mechanisms

IF 1.1 4区 综合性期刊 Q3 MULTIDISCIPLINARY SCIENCES Current Science Pub Date : 2022-09-10 DOI:10.18520/cs/v123/i5/642-649
Thorny Chanu Thounaojam, Zesmin Khan, T. Meetei, S. Panda, H. Upadhyaya
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Abstract

Arsenic stress greatly affects plant production, threatening food security, and also human health through food chain. Arsenic alters various physiological processes that subsequently affect plant’s normal metabolism. Plant has different mechanisms to protect from stress, where nanoparticles improve plant metabolisms and defence system, thereby alleviating arsenic stress in plant. Therefore, this review discusses the effects of arsenic in plant at different levels, and the roles of NPs in modulating plant defence system against As stress. This review will be encouraging in future research on plant protective mechanisms against stress and the significance of NPs in plant science and agriculture. nitrite reductase, and glutamate dehydrogease, thereby, reducing NO 3̄ and NO 2 ̄ contents and glutamic acid and glutamine ratio 24,25 . AsV uncouples oxidative phosphorylation, which resulted into the inhibition of ATP synthesis 26 . ATP is formed by phosphorylation of ADP in mitochondria, but due to the interference of AsV with the mitochondrial enzymes, F 1 F o ATP synthase, the enzyme reacts with AsV and formed ADP-AsV and thereby inhibiting the normal metabolism. AsV interferes the activity of polynucleotide phosphorylase enzyme (PNPase), the enzyme that catalyze phosphorolysis and also the exchange of the terminal phosphate group of ADP and Pi. In presence of AsV, PNPase catalyze the arsenolysis of RNA and ADP giving AMP-arsenate 27 . AsV also alters the activity of glycolytic ezymes by substituting the Pi group. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is the glycolytic enzyme that catalyzes the oxidative phosphorylation of D -glyceraldehyde 3-phosphate (G3P) to 1,3-biphospho- D -glycerate (1,3BPG), but presence of AsV inhibited the formation of 1,3BPG, and formed 1-arseno-3-phosphoglycerate (1As3PG) 28 . The study of Tariang et al. 29 also revealed that As altered activity of hexokinase, phosphofructokinase and pyruvate kinase enzymes, which might have caused to inhibition of carbohydrate metabolism. cell walls by decreasing degree of pectin methylesterification. The SiO 2 NPs treated cell show higher expression of OsNIP1; 1 and OsNIP3; 3 and lower expression of OsLis1 and OsLis2 genes. These findings provide the possibility of using SiO 2 NPs in As-contaminated paddy soil. It has been reported that many other abiotic stresses such as salinity stress, drought and Cd stresses were mitigated by different NPs by increasing antioxidant enzyme activities while lowering ROS 48, 49 . The recent study of Hussain et al. 50 on the use of different NPs (ZnO, FeO and Si) under Cd stress in wheat plant also revealed that NPs ameliorate Cd stress by increasing nutrient uptake and antioxidant enzyme activities, while reducing Cd intake by the plant. The prospective of NPs to mitigate abiotic stress in crop plant was reviewed by Das and Das 51 where the significant roles of NPs in mediating different stresses have been explained. Abiotic stress such as drought, flood or salinity stress was mediated by different NPs including Ag, Al 2 O 3 , Fe 3 O 4 , TiO 2 , SiO 2 , ZnO NPs in different plants by increasing essential nutrient content and enzymic and non-enzymic antioxidant, altogether increased total antioxidant capacity of plant. Gohari et al. 48 , Duo et al. 52 and Mahammadi et al. 53 also demonstrated stimulation of antioxidant enzymes with the supplementation of NPs, enhancing plant defence system and tolerance against salt, drought and cold stress respectively. NPs possess great potential towards amelioration of different stresses by counteracting stress induced oxidative damage with the increase of antioxidant activities. Studies of Khan et al. 54 and Praveen et al. 55 , also revealed the prominent role of antioxidants in the mitigation of As in plants.
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纳米颗粒通过调节防御机制减轻植物的砷胁迫
砷胁迫严重影响植物生产,威胁粮食安全,并通过食物链威胁人类健康。砷改变多种生理过程,进而影响植物的正常代谢。植物具有不同的保护机制,其中纳米颗粒改善了植物的代谢和防御系统,从而减轻了植物的砷胁迫。因此,本文就砷在不同水平下对植物的影响以及NPs在调节植物抗砷胁迫中的作用进行了综述。这一综述将为进一步研究植物抗胁迫保护机制以及NPs在植物科学和农业中的重要意义提供参考。亚硝酸盐还原酶和谷氨酸脱氢酶,从而降低no3和no2的含量以及谷氨酸和谷氨酰胺的比值24,25。AsV解偶氧化磷酸化,导致ATP合成抑制26。ATP是由线粒体内ADP的磷酸化形成的,但由于AsV对线粒体酶f1f - ATP合成酶的干扰,酶与AsV反应形成ADP-AsV,从而抑制了正常的代谢。AsV干扰多核苷酸磷酸化酶(PNPase)的活性,PNPase是催化磷酸解的酶,也是ADP和Pi的末端磷酸基交换的酶。在AsV存在的情况下,PNPase催化RNA和ADP的砷溶解,产生amp - arsena27。AsV还通过取代Pi基团改变糖酵解酶的活性。甘油醛-3-磷酸脱氢酶(GAPDH)是一种糖酵解酶,可催化D -甘油醛-3-磷酸(G3P)氧化磷酸化为1,3-二磷酸- D -甘油(1,3 bpg),但AsV的存在抑制了1,3 bpg的形成,形成1-砷-3-磷酸甘油(1As3PG) 28。Tariang et al. 29的研究也揭示了己糖激酶、磷酸果糖激酶和丙酮酸激酶活性的改变,可能导致碳水化合物代谢的抑制。通过降低果胶甲基化程度来破坏细胞壁。sio2nps处理后的细胞OsNIP1表达增加;1和OsNIP3;OsLis1和OsLis2基因表达降低。这些发现为在砷污染的水稻土中使用二氧化硅纳米粒子提供了可能性。据报道,不同的NPs可以通过提高抗氧化酶活性同时降低活性氧来缓解许多其他非生物胁迫,如盐胁迫、干旱胁迫和镉胁迫。Hussain等人最近对不同氮磷酰胺(ZnO、FeO和Si)在Cd胁迫下对小麦植株的影响的研究也表明,氮磷酰胺通过增加养分吸收和抗氧化酶活性来改善Cd胁迫,同时减少植株对Cd的摄入。Das和Das 51综述了NPs缓解作物非生物胁迫的前景,并解释了NPs在介导不同胁迫中的重要作用。Ag、al2o3、fe2o3、tio2、sio2、ZnO等不同NPs通过增加植物体内必需营养素含量和酶促抗氧化和非酶促抗氧化能力,介导干旱、洪涝或盐胁迫等非生物胁迫。Gohari等人48,Duo等人52和Mahammadi等人53也分别证明了补充NPs可以刺激抗氧化酶,增强植物防御系统和对盐、干旱和冷胁迫的耐受性。NPs通过提高抗氧化活性来对抗应激引起的氧化损伤,在改善不同应激条件方面具有很大的潜力。Khan等人(54)和Praveen等人(55)的研究也揭示了抗氧化剂在缓解植物砷中毒中的突出作用。
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来源期刊
Current Science
Current Science 综合性期刊-综合性期刊
CiteScore
1.50
自引率
10.00%
发文量
97
审稿时长
3 months
期刊介绍: Current Science, published every fortnight by the Association, in collaboration with the Indian Academy of Sciences, is the leading interdisciplinary science journal from India. It was started in 1932 by the then stalwarts of Indian science such as CV Raman, Birbal Sahni, Meghnad Saha, Martin Foster and S.S. Bhatnagar. In 2011, the journal completed one hundred volumes. The journal is intended as a medium for communication and discussion of important issues that concern science and scientific activities. Besides full length research articles and shorter research communications, the journal publishes review articles, scientific correspondence and commentaries, news and views, comments on recently published research papers, opinions on scientific activity, articles on universities, Indian laboratories and institutions, interviews with scientists, personal information, book reviews, etc. It is also a forum to discuss issues and problems faced by science and scientists and an effective medium of interaction among scientists in the country and abroad. Current Science is read by a large community of scientists and the circulation has been continuously going up. Current Science publishes special sections on diverse and topical themes of interest and this has served as a platform for the scientific fraternity to get their work acknowledged and highlighted. Some of the special sections that have been well received in the recent past include remote sensing, waves and symmetry, seismology in India, nanomaterials, AIDS, Alzheimer''s disease, molecular biology of ageing, cancer, cardiovascular diseases, Indian monsoon, water, transport, and mountain weather forecasting in India, to name a few. Contributions to these special issues ‘which receive widespread attention’ are from leading scientists in India and abroad.
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