Copper nanoparticles mediated physiological changes and transcriptional variations in microRNA159 (miR159) and mevalonate kinase (MVK) in pepper; potential benefits and phytotoxicity assessment

[1]  J. White,et al.  Copper Oxide Nanoparticle-Embedded Hydrogels Enhance Nutrient Supply and Growth of Lettuce (Lactuca sativa) Infected with Fusarium oxysporum f. sp. lactucae. , 2021, Environmental science & technology.

[2]  A. Pugazhendhi,et al.  Antibacterial activity and photocatalytic dye degradation of copper oxide nanoparticles (CuONPs) using Justicia gendarussa , 2021, Applied Nanoscience.

[3]  A. Mahmoud,et al.  Are Copper Nanoparticles Toxic to All Plants? A Case Study on Onion (Allium cepa L.) , 2021 .

[4]  N. Abdelsalam,et al.  Toxicity, inflammatory and antioxidant genes expression, and physiological changes of green synthesis silver nanoparticles on Nile tilapia (Oreochromis niloticus) fingerlings. , 2021, Comparative biochemistry and physiology. Toxicology & pharmacology : CBP.

[5]  Hania A. Guirguis,et al.  Biogenic copper nanoparticles from Avicennia marina leaves: Impact on seed germination, detoxification enzymes, chlorophyll content and uptake by wheat seedlings , 2021, PloS one.

[6]  A. Pugazhendhi,et al.  Green chemistry route of biosynthesized copper oxide nanoparticles using Psidium guajava leaf extract and their antibacterial activity and effective removal of industrial dyes , 2021 .

[7]  A. Iranbakhsh,et al.  New Insights into the Transcriptional, Epigenetic, and Physiological Responses to Zinc Oxide Nanoparticles in Datura stramonium; Potential Species for Phytoremediation , 2021, Journal of Plant Growth Regulation.

[8]  R. Ahmadvand,et al.  Comparative efficacy of selenate and selenium nanoparticles for improving growth, productivity, fruit quality, and postharvest longevity through modifying nutrition, metabolism, and gene expression in tomato; potential benefits and risk assessment , 2020, PloS one.

[9]  Rehab Y. Ghareeb,et al.  Utilization of Cladophora glomerata extract nanoparticles as eco-nematicide and enhancing the defense responses of tomato plants infected by Meloidogyne javanica , 2020, Scientific Reports.

[10]  B. Chefetz,et al.  Copper sulfide nanoparticles suppress Gibberella fujikuroi infection in rice (Oryza sativa L.) by multiple mechanisms: contact-mortality, nutritional modulation and phytohormone regulation , 2020 .

[11]  R. Hamers,et al.  Copper nanomaterial morphology and composition control foliar transfer through the cuticle and mediate resistance to root fungal disease in tomato (Solanum lycopersicum). , 2020, Journal of agricultural and food chemistry.

[12]  A. Iranbakhsh,et al.  Nitric oxide and selenium nanoparticles confer changes in growth, metabolism, antioxidant machinery, gene expression, and flowering in chicory (Cichorium intybus L.): potential benefits and risk assessment , 2020, Environmental Science and Pollution Research.

[13]  A. Pugazhendhi,et al.  Eco-biocompatibility of chitosan coated biosynthesized copper oxide nanocomposite for enhanced industrial (Azo) dye removal from aqueous solution and antibacterial properties. , 2020, Carbohydrate polymers.

[14]  A. Majd,et al.  Red elemental selenium nanoparticles mediated substantial variations in growth, tissue differentiation, metabolism, gene transcription, epigenetic cytosine DNA methylation, and callogenesis in bittermelon (Momordica charantia); an in vitro experiment , 2020, PloS one.

[15]  J. Gardea-Torresdey,et al.  Copper nanowires as nanofertilizers for alfalfa plants: Understanding nano-bio systems interactions from microbial genomics, plant molecular responses and spectroscopic studies. , 2020, The Science of the total environment.

[16]  A. Majd,et al.  Selenium nanoparticles induced variations in growth, morphology, anatomy, biochemistry, gene expression, and epigenetic DNA methylation in Capsicum annuum; an in vitro study. , 2020, Environmental pollution.

[17]  Yan-fang Ren,et al.  Phytotoxicity Assessment of Copper Oxide Nanoparticles on the Germination, Early Seedling Growth, and Physiological Responses in Oryza sativa L. , 2020, Bulletin of Environmental Contamination and Toxicology.

[18]  A. Seabra,et al.  Effects of copper oxide nanoparticles on growth of lettuce (Lactuca sativa L.) seedlings and possible implications of nitric oxide in their antioxidative defense , 2020, Environmental Monitoring and Assessment.

[19]  Huong Mai Le,et al.  Copper Nanoparticle Application Enhances Plant Growth and Grain Yield in Maize Under Drought Stress Conditions , 2020, bioRxiv.

[20]  Ming-Bo Wang,et al.  miR159 Represses a Constitutive Pathogen Defense Response in Tobacco1[OPEN] , 2020, Plant Physiology.

[21]  A. Iranbakhsh,et al.  Multi-walled carbon nanotubes improved growth, anatomy, physiology, secondary metabolism, and callus performance in Catharanthus roseus: an in vitro study , 2019, 3 Biotech.

[22]  C. Sayes,et al.  The potential exposure and hazards of copper nanoparticles: A review. , 2019, Environmental toxicology and pharmacology.

[23]  N. Abdelsalam,et al.  Morphological, Pomological, and Specific Molecular Marker Resources for Genetic Diversity Analyses in Fig (Ficus carica L.) , 2019, HortScience.

[24]  M. J. López-Galiano,et al.  Expression of miR159 Is Altered in Tomato Plants Undergoing Drought Stress , 2019, Plants.

[25]  G. Bai,et al.  Development of Single Nucleotide Polymorphism Markers for the Wheat Curl Mite Resistance Gene Cmc4 , 2019, Crop Science.

[26]  N. Kavroulakis,et al.  Use of copper, silver and zinc nanoparticles against foliar and soil-borne plant pathogens. , 2019, The Science of the total environment.

[27]  A. Khaled,et al.  Comparison of uridine diphosphate-glycosyltransferase UGT76G1 genes from some varieties of Stevia rebaudiana Bertoni , 2019, Scientific Reports.

[28]  Elsy Rubisela López-Vargas,et al.  Responses of Tomato Plants under Saline Stress to Foliar Application of Copper Nanoparticles , 2019, Plants.

[29]  Kareem A. Mosa,et al.  Phytotoxic and Genotoxic Effects of Copper Nanoparticles in Coriander (Coriandrum sativum—Apiaceae) , 2019, Plants.

[30]  J. Peralta-Videa,et al.  Toxicity of copper hydroxide nanoparticles, bulk copper hydroxide, and ionic copper to alfalfa plants: A spectroscopic and gene expression study. , 2018, Environmental pollution.

[31]  A. Iranbakhsh,et al.  Potential benefits and toxicity of nanoselenium and nitric oxide in peppermint , 2018, Acta agriculturae Slovenica.

[32]  G. Cadenas-Pliego,et al.  Chitosan-PVA and Copper Nanoparticles Improve Growth and Overexpress the SOD and JA Genes in Tomato Plants under Salt Stress , 2018, Agronomy.

[33]  N. Abdelsalam,et al.  Genetic and Morphological Characterization of Mangifera indica L. Growing in Egypt , 2018, HortScience.

[34]  Liwei Sun,et al.  Impact of copper nanoparticles and ionic copper exposure on wheat (Triticum aestivum L.) root morphology and antioxidant response. , 2018, Environmental pollution.

[35]  Kareem A. Mosa,et al.  Copper Nanoparticles Induced Genotoxicty, Oxidative Stress, and Changes in Superoxide Dismutase (SOD) Gene Expression in Cucumber (Cucumis sativus) Plants , 2018, Front. Plant Sci..

[36]  Antonio Juárez-Maldonado,et al.  Foliar Application of Copper Nanoparticles Increases the Fruit Quality and the Content of Bioactive Compounds in Tomatoes , 2018, Applied Sciences.

[37]  T. Minkina,et al.  Effects of Copper Nanoparticles (CuO NPs) on Crop Plants: a Mini Review , 2018 .

[38]  Fengning Xiang,et al.  Primary root growth in Arabidopsis thaliana is inhibited by the miR159 mediated repression of MYB33, MYB65 and MYB101. , 2017, Plant science : an international journal of experimental plant biology.

[39]  Gang Wu,et al.  Repression of miR156 by miR159 Regulates the Timing of the Juvenile-to-Adult Transition in Arabidopsis , 2017, Plant Cell.

[40]  Suvendu Dey,et al.  Effectivity of copper and cadmium sulphide nanoparticles in mitotic and meiotic cells of Nigella sativa L. (black cumin) – can nanoparticles act as mutagenic agents? , 2016 .

[41]  A. Millar,et al.  Specificity of plant microRNA target MIMICs: Cross-targeting of miR159 and miR319. , 2015, Journal of plant physiology.

[42]  R. Dubey,et al.  Effect of aluminum on protein oxidation, non-protein thiols and protease activity in seedlings of rice cultivars differing in aluminum tolerance. , 2014, Journal of plant physiology.

[43]  S. Jackson,et al.  The role of microRNAs in the control of flowering time. , 2014, Journal of experimental botany.

[44]  Junhui Wang,et al.  Flowering time control in ornamental gloxinia (Sinningia speciosa) by manipulation of miR159 expression. , 2013, Annals of botany.

[45]  Chao-Long Chen,et al.  The effect of water deficit and excess copper on proline metabolism in Nicotiana benthamiana , 2011, Biologia Plantarum.

[46]  Nam-Hai Chua,et al.  ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. , 2007, The Plant journal : for cell and molecular biology.

[47]  C. Kao,et al.  Regulation of proline accumulation in detached rice leaves exposed to excess copper. , 2001, Plant science : an international journal of experimental plant biology.

[48]  A. Wellburn,et al.  Determinations of total carotenoids and chlorophylls a and b of leaf extracts in different solvents , 1983 .

[49]  I. D. Teare,et al.  Rapid determination of free proline for water-stress studies , 1973, Plant and Soil.

[50]  A. Iranbakhsh,et al.  Synthesis and Characterization of Zinc Oxide Nanoparticles and Their Impact on Plants , 2021, Plant Responses to Nanomaterials.

[51]  A. Iranbakhsh,et al.  Gene regulation by H2S in plants , 2021, Hydrogen Sulfide in Plant Biology.

[52]  C. Clément,et al.  Transient effect of the herbicide flazasulfuron on carbohydrate physiology in Vitis vinifera L. , 2006, Chemosphere.

[53]  A. Ferrer,et al.  Molecular cloning and expression analysis of the mevalonate kinase gene from Arabidopsis thaliana , 2004, Plant Molecular Biology.

[54]  A. Kembhavi,et al.  Salt-tolerant and thermostable alkaline protease fromBacillus subtilis NCIM No. 64 , 1993, Applied biochemistry and biotechnology.