Bacterial RNA chaperones confer abiotic stress tolerance in plants and improved grain yield in maize under water-limited conditions.
about
Genome sequence and transcriptome analysis of the radioresistant bacterium Deinococcus gobiensis: insights into the extreme environmental adaptationsBreeding and Domesticating Crops Adapted to Drought and Salinity: A New Paradigm for Increasing Food ProductionEngineering food crops to grow in harsh environmentsClimate Change, Drought and Human Health in Canada.Emerging Roles of RNA-Binding Proteins in Plant Growth, Development, and Stress ResponsesPlanning for food security in a changing climateGenetic basis and detection of unintended effects in genetically modified crop plantsDevelopment and application of modern agricultural biotechnology in Botswana: the potentials, opportunities and challengesTowards a carbon-negative sustainable bio-based economy.Tackling drought stress: receptor-like kinases present new approachesA future of the model organism modelPlant breeding: Discovery in a dry spell.Transportability of confined field trial data from cultivation to import countries for environmental risk assessment of genetically modified crops.Emerging tools, concepts and ideas to track the modulator genes underlying plant drought adaptive traits: An overviewIrrE, a global regulator of extreme radiation resistance in Deinococcus radiodurans, enhances salt tolerance in Escherichia coli and Brassica napus.Identifying target traits and molecular mechanisms for wheat breeding under a changing climate.Building the crops of tomorrow: advantages of symbiont-based approaches to improving abiotic stress tolerance.Glycine-rich RNA-binding proteins are functionally conserved in Arabidopsis thaliana and Oryza sativa during cold adaptation process.Any trait or trait-related allele can confer drought tolerance: just design the right drought scenario.Creating drought- and salt-tolerant cotton by overexpressing a vacuolar pyrophosphatase geneHybridization between crops and wild relatives: the contribution of cultivated lettuce to the vigour of crop-wild hybrids under drought, salinity and nutrient deficiency conditionsSubcellular protein overexpression to develop abiotic stress tolerant plants.Characterising microbial protein test substances and establishing their equivalence with plant-produced proteins for use in risk assessments of transgenic crops.Excavating abiotic stress-related gene resources of terrestrial macroscopic cyanobacteria for crop genetic engineering: dawn and challengeDiversity and heritability of the maize rhizosphere microbiome under field conditionsAdvances in maize genomics and their value for enhancing genetic gains from breeding.COLD SHOCK DOMAIN PROTEIN 3 is involved in salt and drought stress tolerance in Arabidopsis.Drought-Tolerant Corn Hybrids Yield More in Drought-Stressed Environments with No Penalty in Non-stressed Environments.Cold shock domain protein 3 regulates freezing tolerance in Arabidopsis thaliana.Increasing crop productivity to meet global needs for feed, food, and fuel.The Conservation and Function of RNA Secondary Structure in Plants.Endophytic Bacterium Pseudomonas fluorescens RG11 May Transform Tryptophan to Melatonin and Promote Endogenous Melatonin Levels in the Roots of Four Grape Cultivars.ARGOS8 variants generated by CRISPR-Cas9 improve maize grain yield under field drought stress conditions.Improved drought tolerance in wheat plants overexpressing a synthetic bacterial cold shock protein gene SeCspA.Why genetically modified crops?Engineering cold stress tolerance in crop plants.Genetic engineering to improve plant performance under drought: physiological evaluation of achievements, limitations, and possibilities.The agony of choice: how plants balance growth and survival under water-limiting conditions.Complexity of the alternative splicing landscape in plants.Translational research: from pot to plot.
P2860
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P2860
Bacterial RNA chaperones confer abiotic stress tolerance in plants and improved grain yield in maize under water-limited conditions.
description
2008 nĆ® lÅ«n-bĆ»n
@nan
2008幓ć®č«ę
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2008幓å¦ęÆęē«
@wuu
2008幓å¦ęÆęē«
@zh-cn
2008幓å¦ęÆęē«
@zh-hans
2008幓å¦ęÆęē«
@zh-my
2008幓å¦ęÆęē«
@zh-sg
2008幓åøč”ęē«
@yue
2008幓åøč”ęē«
@zh
2008幓åøč”ęē«
@zh-hant
name
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@en
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@nl
type
label
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@en
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@nl
prefLabel
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@en
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@nl
P2093
P2860
P356
P1433
P1476
Bacterial RNA chaperones confe ...... nder water-limited conditions.
@en
P2093
Christopher Bonin
Dave Warner
Don C Anstrom
Ganesh Kumar
Jacqueline E Heard
Jay Harrison
Jayaprakash Targolli
Martin Stoecker
Mary Fernandes
P2860
P304
P356
10.1104/PP.108.118828
P407
P577
2008-06-01T00:00:00Z