We are analyzing https://link.springer.com/article/10.1007/s10725-017-0267-2.

Title:
Recent methods of drought stress tolerance in plants | Plant Growth Regulation
Description:
In the climate change scenario the drought has been diagnosed as major stress affecting crop productivity. This review demonstrates some recent findings on the amelioration of drought stress. Nanoparticles, synthetic growth regulators viz. Trinexapac-ethyl, and Biochar addition helps to economize the water budget of plants, enhances the bioavailability of water and nutrients as well as overcomes drought induced osmotic and oxidative stresses. Besides ABA, SA and JA are also involved in inducing tolerance to drought stress through modulation of physiological and biochemical processes in plants. Plant growth promoting rhizobacteria (PGPR) offer new opportunities in agricultural biotechnology. These beneficial microorganisms colonize the rhizosphere/endo-rhizosphere of plants and impart drought tolerance by improving root architechture, enhancing water use efficiency, producing exopolysaccharides, phytohormones viz, ABA, SA and IAA and volatile compounds. Further PGPR also play positive role in combating osmotic and oxidative stresses induced by drought stress through enhancing the accumulation of osmolytes, antioxidants and upregulation or down regulation of stress responsive genes. In transgenic plants stress inducible genes enhanced abiotic stress tolerance by encoding key enzymes regulating biosynthesis of compatible solutes. The role of genes/cDNAs encoding proteins involved in regulating other genes/proteins, signal transduction process and strategies to improve drought stress tolerance have also been discussed.
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28 years and 1 months (reg. 1997-05-29).

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Keywords {🔍}

google, scholar, article, plant, cas, pubmed, drought, stress, tolerance, plants, growth, sci, arabidopsis, cell, gene, rice, central, transgenic, physiol, acid, salt, zhang, biol, water, abiotic, expression, biochar, soil, shinozaki, yamaguchishinozaki, bot, transcription, involved, genes, responses, wang, kim, liu, crop, role, abscisic, zhu, effect, resistance, conditions, response, review, enhances, physiological, rhizobacteria,

Topics {✒️}

month download article/chapter asghari bano & aliya fazal aba-dependent stress-signaling pathway low-temperature-responsive gene expression plant growth-promoting rhizobacteria dehydration-induced nac protein cold-inducible downstream genes plant heat-shock proteins component pseudo-response regulator dehydration-responsive rd22 gene plant growth-promoting bacteria ethylene-induced stomatal closure dehydration-induced grp94 homologue stress-induced growth reduction quaid-e-azam university low-temperature pyrolysis conditions drought stress-induced rma1h1 drought-sensitive barley genotypes drought-responsive gene expression cold-responsive gene expression water-deficit stress induced full article pdf asghari bano transcription factors involved stress hormones zat12 transcription factors mediates plant responses abiotic stress responses transcription factor ap37 wrky transcription factor cold-inducible genes privacy choices/manage cookies aba signal transduction arabidopsis transcription factor stress responsive genes signal transduction process membrane-located receptor author correspondence transgenic creeping bentgrass synthetic growth regulators enhanced root growth drought-tolerant genotypes agricultural biotechnology recent methods low temperature transcriptome related subjects molecular biology al-whaibi mh abiotic stress signalling understanding regulatory networks

Questions {❓}

Cakmak I (2008) Enrichment of cereal grains with zinc: agronomic or genetic biofortification?
Maggio A, Miyazaki S, Veronese P, Fujita T, Ibeas JI, Damsz B, Bressan RA (2002) Does proline accumulation play an active role in stress-induced growth reduction?
Quilliam RS, Glanville HC, Wade SC, Jones DL (2013) Life in the ‘charosphere’–Does biochar in agricultural soil provide a significant habitat for microorganisms?

Schema {🗺️}

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