Trehalose and NO work together to alleviate Cd toxicity in pepper (Capsicum annuum L.) plants by regulating cadmium sequestration and distribution within cells and the antioxidant defense system
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C. Kaya | P. Ahmad | J. Rinklebe | M. Alyemeni | M. Ashraf
[1] C. Kaya,et al. Nitric oxide and hydrogen sulfide work together to improve tolerance to salinity stress in wheat plants by upraising the AsA-GSH cycle. , 2022, Plant physiology and biochemistry : PPB.
[2] C. Kaya,et al. The participation of nitric oxide in hydrogen sulphide-mediated chromium tolerance in pepper (Capsicum annuum L) plants by modulating subcellular distribution of chromium and the ascorbate-glutathione cycle. , 2022, Environmental Pollution.
[3] Junpu Liu,et al. Transcriptomic and Metabolomic Analysis of the Effects of Exogenous Trehalose on Salt Tolerance in Watermelon (Citrullus lanatus) , 2022, Cells.
[4] Sameer H Qari,et al. Trehalose: a promising osmo-protectant against salinity stress—physiological and molecular mechanisms and future prospective , 2022, Molecular Biology Reports.
[5] Xiaofang Zhu,et al. The Role of Nitric Oxide Signaling in Plant Responses to Cadmium Stress , 2022, International journal of molecular sciences.
[6] Shengnan Zhang,et al. Jasmonic acid alleviates cadmium toxicity through regulating the antioxidant response and enhancing the chelation of cadmium in rice (Oryza sativa L.). , 2022, Environmental pollution.
[7] A. Raza,et al. Mechanistic Insights Into Trehalose-Mediated Cold Stress Tolerance in Rapeseed (Brassica napus L.) Seedlings , 2022, Frontiers in Plant Science.
[8] A. Mahmood,et al. Exogenously Applied Trehalose Augments Cadmium Stress Tolerance and Yield of Mung Bean (Vigna radiata L.) Grown in Soil and Hydroponic Systems through Reducing Cd Uptake and Enhancing Photosynthetic Efficiency and Antioxidant Defense Systems , 2022, Plants.
[9] A. Iyer-Pascuzzi,et al. Trehalose increases tomato drought tolerance, induces defenses, and increases resistance to bacterial wilt disease , 2022, bioRxiv.
[10] A. Sarkar,et al. Imperative role of trehalose metabolism and trehalose-6-phosphate signalling on salt stress responses in plants. , 2022, Physiologia plantarum.
[11] T. Aftab,et al. Cellular Responses, Osmotic Adjustments, and Role of Osmolytes in Providing Salt Stress Resilience in Higher Plants: Polyamines and Nitric Oxide Crosstalk , 2022, Journal of Plant Growth Regulation.
[12] Qiaochun Wang,et al. ROS-induced oxidative stress in plant cryopreservation: occurrence and alleviation , 2021, Planta.
[13] X. Cao,et al. Proline, a multifaceted signalling molecule in plant responses to abiotic stress: understanding the physiological mechanisms. , 2021, Plant biology.
[14] K. Siddique,et al. Nitric oxide secures reproductive efficiency in heat-stressed lentil (Lens culinaris Medik.) plants by enhancing the photosynthetic ability to improve yield traits , 2021, Physiology and Molecular Biology of Plants.
[15] P. Ahmad,et al. Jasmonic acid (JA) and gibberellic acid (GA3) mitigated Cd-toxicity in chickpea plants through restricted cd uptake and oxidative stress management , 2021, Scientific Reports.
[16] Haiying Yu,et al. The role of polysaccharides functional groups in cadmium binding in root cell wall of a cadmium-safe rice line. , 2021, Ecotoxicology and environmental safety.
[17] J. M. Cámara-Zapata,et al. The Addition of Selenium to the Nutrient Solution Decreases Cadmium Toxicity in Pepper Plants Grown under Hydroponic Conditions , 2021, Agronomy.
[18] K. Abd-Elsalam,et al. Hydrogen peroxide detoxifying enzymes show different activity patterns in host and non-host plant interactions with Magnaporthe oryzae Triticum pathotype , 2021, Physiology and Molecular Biology of Plants.
[19] J. Rivoal,et al. Glutathione Metabolism in Plants under Stress: Beyond Reactive Oxygen Species Detoxification , 2021, Metabolites.
[20] H. Kalaji,et al. Molecular Mechanisms of Nitric Oxide (NO) Signaling and Reactive Oxygen Species (ROS) Homeostasis during Abiotic Stresses in Plants , 2021, International journal of molecular sciences.
[21] M. Jafari,et al. Sodium nitroprusside: its beneficial role in drought stress tolerance of “Mexican lime” (Citrus aurantifolia (Christ.) Swingle) under in vitro conditions , 2021, In Vitro Cellular & Developmental Biology - Plant.
[22] Indu,et al. Roles of Nitric Oxide in Conferring Multiple Abiotic Stress Tolerance in Plants and Crosstalk with Other Plant Growth Regulators , 2021, Journal of Plant Growth Regulation.
[23] P. Finnegan,et al. Application of Trehalose and Salicylic Acid Mitigates Drought Stress in Sweet Basil and Improves Plant Growth , 2021, Plants.
[24] Vinay Kumar,et al. Nitric oxide, crosstalk with stress regulators and plant abiotic stress tolerance , 2021, Plant Cell Reports.
[25] Xueyuan Zhang,et al. Effects of cadmium stress on growth and physiological characteristics of sassafras seedlings , 2021, Scientific Reports.
[26] Ritika Rajpoot. Sugars: Coping the Stress in Plants , 2021 .
[27] Siyu Huang,et al. Comparative responses of cadmium accumulation and subcellular distribution in wheat and rice supplied with selenite or selenate , 2021, Environmental Science and Pollution Research.
[28] M. Azhar,et al. Review of oxidative stress and antioxidative defense mechanisms in Gossypium hirsutum L. in response to extreme abiotic conditions , 2021 .
[29] Meng Li,et al. Trehalose triggers hydrogen peroxide and nitric oxide to participate in melon seedlings oxidative stress tolerance under cold stress , 2021 .
[30] K. Nahar,et al. Nitric Oxide Regulates Plant Growth, Physiology, Antioxidant Defense, and Ion Homeostasis to Confer Salt Tolerance in the Mangrove Species, Kandelia obovata , 2021, Antioxidants.
[31] A. Oukarroum,et al. Interactive effect of potassium and cadmium on growth, root morphology and chlorophyll a fluorescence in tomato plant , 2021, Scientific Reports.
[32] N. Verma,et al. Regulation of redox homeostasis in cadmium stressed rice field cyanobacteria by exogenous hydrogen peroxide and nitric oxide , 2021, Scientific Reports.
[33] Jianli Liu,et al. Cadmium induced BEAS-2B cells apoptosis and mitochondria damage via MAPK signaling pathway. , 2021, Chemosphere.
[34] G. S. Shekhawat,et al. Nitric oxide induced Cd tolerance and phytoremediation potential of B. juncea by the modulation of antioxidant defense system and ROS detoxification , 2020, Biometals : an international journal on the role of metal ions in biology, biochemistry, and medicine.
[35] R. Mittler,et al. Integration of ROS and hormone signaling during abiotic stress. , 2020, The Plant journal : for cell and molecular biology.
[36] H. Ali,et al. Crosstalk of hydrogen sulfide and nitric oxide requires calcium to mitigate impaired photosynthesis under cadmium stress by activating defense mechanisms in Vigna radiata. , 2020, Plant physiology and biochemistry : PPB.
[37] Zhengguo Song,et al. Mechanisms of trehalose-mediated mitigation of Cd toxicity in rice seedlings , 2020 .
[38] B. Zechmann. Subcellular Roles of Glutathione in Mediating Plant Defense during Biotic Stress , 2020, Plants.
[39] A. Shah,et al. Butanolide alleviated cadmium stress by improving plant growth, photosynthetic parameters and antioxidant defense system of brassica oleracea. , 2020, Chemosphere.
[40] K. Shah,et al. Alterations in antioxidative machinery and growth parameters upon application of nitric oxide donor that reduces detrimental effects of cadmium in rice seedlings with increasing days of growth , 2020 .
[41] B. Rather,et al. Mechanisms and Role of Nitric Oxide in Phytotoxicity-Mitigation of Copper , 2020, Frontiers in Plant Science.
[42] S. Prasad,et al. Sulphur and calcium attenuate arsenic toxicity inBrassicaby adjusting ascorbate–glutathione cycle and sulphur metabolism , 2020, Plant Growth Regulation.
[43] M. Li,et al. H2O2 and NO are involved in trehalose-regulated oxidative stress tolerance in cold-stressed tomato plants , 2020 .
[44] Liao Yanling,et al. Analysis of genes related to chlorophyll metabolism under elevated CO2 in cucumber (Cucumis sativus L.) , 2020 .
[45] W. Liao,et al. Roles of nitric oxide in heavy metal stress in plants: Cross-talk with phytohormones and protein S-nitrosylation. , 2020, Environmental pollution.
[46] D. Chauhan,et al. Silicon and nitric oxide-mediated mechanisms of cadmium toxicity alleviation in wheat seedlings. , 2020, Physiologia plantarum.
[47] E. A. Qaid. Effect of Exogenous Trehalose on Physiological Responses of Wheat Plants Under Drought Stress , 2020 .
[48] Y. Wan,et al. Physiological responses of peanut seedlings to exposure to low or high cadmium concentration and the alleviating effect of exogenous nitric oxide to high cadmium concentration stress , 2020, Plant Biosystems - An International Journal Dealing with all Aspects of Plant Biology.
[49] Khalid Rehman Hakeem,et al. Exogenous Nitric Oxide Mitigates Nickel-Induced Oxidative Damage in Eggplant by Upregulating Antioxidants, Osmolyte Metabolism, and Glyoxalase Systems , 2019, Plants.
[50] M. Sadak. Physiological role of trehalose on enhancing salinity tolerance of wheat plant , 2019, Bulletin of the National Research Centre.
[51] M. Fujita,et al. Trehalose Protects Maize Plants from Salt Stress and Phosphorus Deficiency , 2019, Plants.
[52] P. Ahmad,et al. Sodium nitroprusside (SNP) improves tolerance to arsenic (As) toxicity in Vicia faba through the modifications of biochemical attributes, antioxidants, ascorbate-glutathione cycle and glyoxalase cycle. , 2019, Chemosphere.
[53] Xiaohong Wang,et al. Accumulation and fixation of Cd by tomato cell wall pectin under Cd stress , 2019, Environmental and Experimental Botany.
[54] C. Kaya,et al. Alleviating effect of nitric oxide on oxidative stress and antioxidant defence system in pepper (Capsicum annuum L.) plants exposed to cadmium and lead toxicity applied separately or in combination , 2019, Scientia Horticulturae.
[55] C. Kaya,et al. Responses of nitric oxide and hydrogen sulfide in regulating oxidative defence system in wheat plants grown under cadmium stress. , 2019, Physiologia plantarum.
[56] Ashwani Kumar Thukral,et al. Nitric oxide-mediated regulation of oxidative stress in plants under metal stress: a review on molecular and biochemical aspects. , 2019, Physiologia plantarum.
[57] Samiksha Singh,et al. Management of chromium (VI) toxicity by calcium and sulfur in tomato and brinjal: Implication of nitric oxide. , 2019, Journal of hazardous materials.
[58] G. Habibi,et al. Exogenous trehalose alleviates the inhibitory effects of salt stress in strawberry plants , 2019, Acta Physiologiae Plantarum.
[59] Hong-Duo Chen,et al. Cell wall mannoprotein of Candida albicans polarizes macrophages and affects proliferation and apoptosis through activation of the Akt signal pathway. , 2019, International immunopharmacology.
[60] A. Elrys,et al. Interplaying roles of silicon and proline effectively improve salt and cadmium stress tolerance in Phaseolus vulgaris plant. , 2019, Plant physiology and biochemistry : PPB.
[61] Hui Liu,et al. Effects of exogenous sulfur on alleviating cadmium stress in tartary buckwheat , 2019, Scientific Reports.
[62] N. Khan,et al. Nitric oxide reverses glucose-mediated photosynthetic repression in wheat (Triticum aestivum L.) under salt stress , 2019, Environmental and Experimental Botany.
[63] Y. Wan,et al. Effect of selenium on the subcellular distribution of cadmium and oxidative stress induced by cadmium in rice (Oryza sativa L.) , 2019, Environmental Science and Pollution Research.
[64] Md. Abu Reza,et al. Cadmium tolerance is associated with the root-driven coordination of cadmium sequestration, iron regulation, and ROS scavenging in rice. , 2019, Plant physiology and biochemistry : PPB.
[65] R. Azevedo,et al. Nutritional status and root morphology of tomato under Cd-induced stress: Comparing contrasting genotypes for metal-tolerance , 2019, Scientia Horticulturae.
[66] Karl H. Mühling,et al. Silicon decreases cadmium concentrations by modulating root endodermal suberin development in wheat plants. , 2019, Journal of hazardous materials.
[67] Zhumei Xi,et al. Amelioration of cold-induced oxidative stress by exogenous 24-epibrassinolide treatment in grapevine seedlings: Toward regulating the ascorbate–glutathione cycle , 2019 .
[68] E. Yıldıztugay,et al. Humic acid protects against oxidative damage induced by cadmium toxicity in wheat (Triticum aestivum) roots through water management and the antioxidant defence system , 2019, Botanica Serbica.
[69] R. Bharagava,et al. Heavy Metal Contamination: An Alarming Threat to Environment and Human Health , 2018, Environmental Biotechnology: For Sustainable Future.
[70] Fangbai Li,et al. Selenium reduces cadmium uptake into rice suspension cells by regulating the expression of lignin synthesis and cadmium-related genes. , 2018, The Science of the total environment.
[71] N. Akram,et al. Trehalose: A Key Organic Osmolyte Effectively Involved in Plant Abiotic Stress Tolerance , 2018, Journal of Plant Growth Regulation.
[72] N. Iqbal,et al. Exogenous sodium nitroprusside increases antioxidative potential and grain yield of bread wheat exposed to cadmium , 2018, Pakistan Journal of Botany.
[73] R. Rasheed,et al. Menadione sodium bisulphite mediated growth, secondary metabolism, nutrient uptake and oxidative defense in okra (Abelmoschus esculentus Moench) under cadmium stress. , 2018, Journal of hazardous materials.
[74] E. Karalija,et al. The effect of hydro and proline seed priming on growth, proline and sugar content, and antioxidant activity of maize under cadmium stress , 2018, Environmental Science and Pollution Research.
[75] Zhong-Guang Li,et al. Signaling Molecule Hydrogen Sulfide Improves Seed Germination and Seedling Growth of Maize (Zea mays L.) Under High Temperature by Inducing Antioxidant System and Osmolyte Biosynthesis , 2018, Front. Plant Sci..
[76] S. Singh,et al. Mycorrhizal inoculations and silicon fortifications improve rhizobial symbiosis, antioxidant defense, trehalose turnover in pigeon pea genotypes under cadmium and zinc stress , 2018, Plant Growth Regulation.
[77] Y. M. Gao,et al. Exogenously-Supplied Trehalose Provides Better Protection for D1 Protein in Winter Wheat under Heat Stress , 2018, Russian Journal of Plant Physiology.
[78] C. Kaya,et al. Hydrogen sulfide regulates the levels of key metabolites and antioxidant defense system to counteract oxidative stress in pepper (Capsicum annuum L.) plants exposed to high zinc regime , 2018, Environmental Science and Pollution Research.
[79] Xiaoyong Chen,et al. Effects of cadmium on photosynthesis of Schima superba young plant detected by chlorophyll fluorescence , 2018, Environmental Science and Pollution Research.
[80] N. Akram,et al. TREHALOSE-INDUCED IMPROVEMENT IN GROWTH , PHOTOSYNTHETIC CHARACTERISTICS AND LEVELS OF SOME KEY OSMOPROTECTANTS IN SUNFLOWER ( HELIANTHUS ANNUUS L . ) UNDER DROUGHT STRESS , 2018 .
[81] H. Kermanian,et al. Effects of exogenous salicylic acid and sodium nitroprusside on α-tocopherol and phytochelatin biosynthesis in zinc-stressed safflower plants , 2018 .
[82] Xiaoe Yang,et al. Morphological and Physiological Responses of Plants to Cadmium Toxicity: A Review , 2017 .
[83] C. Bartoli,et al. Ascorbate-Glutathione Cycle and Abiotic Stress Tolerance in Plants , 2017 .
[84] G. Sidhu. Heavy Metal Toxicity in Soils: Sources, Remediation Technologies and Challenges , 2016 .
[85] A. Caverzan,et al. Antioxidant responses of wheat plants under stress , 2016, Genetics and molecular biology.
[86] F. Tabatabaei,et al. Role of hematin and sodium nitroprusside in regulating Brassica nigra seed germination under nanosilver and silver nitrate stresses. , 2015, Ecotoxicology and environmental safety.
[87] Li-Ping Zhu,et al. Involvement of trehalose in hydrogen sulfide donor sodium hydrosulfide-induced the acquisition of heat tolerance in maize (Zea mays L.) seedlings , 2014, Botanical Studies.
[88] Chenyang Huang,et al. Nitric oxide is involved in the regulation of trehalose accumulation under heat stress in Pleurotus eryngii var. tuoliensis , 2012, Biotechnology Letters.
[89] A. Siosemardeh,et al. Changes in antioxidant enzymes activity and plant performance by salinity stress and zinc application in soybean ( Glycine max L.) , 2012 .
[90] H. Nayyar,et al. Abscisic acid induces heat tolerance in chickpea (Cicer arietinum L.) seedlings by facilitated accumulation of osmoprotectants , 2012, Acta Physiologiae Plantarum.
[91] M. Arasimowicz-Jelonek,et al. The message of nitric oxide in cadmium challenged plants. , 2011, Plant science : an international journal of experimental plant biology.
[92] M. Stitt,et al. Sugar-induced increases in trehalose 6-phosphate are correlated with redox activation of ADPglucose pyrophosphorylase and higher rates of starch synthesis in Arabidopsis thaliana. , 2006, The Biochemical journal.
[93] P. Su,et al. Increased sensitivity to salt stress in an ascorbate-deficient Arabidopsis mutant. , 2005, Journal of experimental botany.
[94] M. Yücel,et al. Biochemical analysis of trehalose and its metabolizing enzymes in wheat under abiotic stress conditions , 2005 .
[95] I. D. Teare,et al. Rapid determination of free proline for water-stress studies , 1973, Plant and Soil.
[96] Chih-Wen Yu,et al. Hydrogen peroxide-induced chilling tolerance in mung beans mediated through ABA-independent glutathione accumulation. , 2003, Functional plant biology : FPB.
[97] P. Grewal,et al. Acclimation of entomopathogenic nematodes to novel temperatures: trehalose accumulation and the acquisition of thermotolerance. , 2003, International journal for parasitology.
[98] V. Velikova,et al. Oxidative stress and some antioxidant systems in acid rain-treated bean plants Protective role of exogenous polyamines , 2000 .
[99] M. Dionisio-Sese,et al. Antioxidant responses of rice seedlings to salinity stress , 1998 .
[100] M. Alberda,et al. Role of oxidative damage in tulip bulb scale micropropagation. , 1997 .
[101] H. Marschner,et al. Activities of Hydrogen Peroxide-Scavenging Enzymes in Germinating Wheat Seeds , 1993 .
[102] K. Asada,et al. Hydrogen Peroxide is Scavenged by Ascorbate-specific Peroxidase in Spinach Chloroplasts , 1981 .
[103] M. M. Bradford. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. , 1976, Analytical biochemistry.
[104] H. Barrs,et al. A Re-Examination of the Relative Turgidity Technique for Estimating Water Deficits in Leaves , 1962 .
[105] G. Ellman,et al. Tissue sulfhydryl groups. , 1959, Archives of biochemistry and biophysics.
[106] D. R. Hoagland,et al. The Water-Culture Method for Growing Plants Without Soil , 2018 .