Nome |
# |
Iodine biofortification of crops: agronomic biofortification, metabolic engineering and iodine bioavailability, file dd9e0b31-eb6f-709e-e053-3705fe0a83fd
|
1.982
|
Plant responses to flooding stress, file dd9e0b31-eb74-709e-e053-3705fe0a83fd
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1.750
|
Quiescence in rice submergence tolerance: an evolutionary hypothesis, file dd9e0b31-c0b0-709e-e053-3705fe0a83fd
|
483
|
Accumulation of anthocyanins in tomato skin extends shelf life, file dd9e0b31-c04e-709e-e053-3705fe0a83fd
|
388
|
Making sense of low oxygen sensing, file dd9e0b31-bf64-709e-e053-3705fe0a83fd
|
376
|
Purple as a tomato: towards high anthocyanin tomatoes, file dd9e0b31-bc17-709e-e053-3705fe0a83fd
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367
|
Plants and flooding stress, file dd9e0b31-be8e-709e-e053-3705fe0a83fd
|
366
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A reassessment of the role of sucrose synthase in the hypoxic sucrose‐ethanol transition in Arabidopsis, file dd9e0b31-c17d-709e-e053-3705fe0a83fd
|
326
|
Tomato fruits: a good target for iodine biofortification, file dd9e0b31-c055-709e-e053-3705fe0a83fd
|
277
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Plant responses to flooding, file dd9e0b31-c17f-709e-e053-3705fe0a83fd
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269
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Phenotiki: an open software and hardware platform for affordable and easy image-based phenotyping of rosette-shaped plants, file dd9e0b31-f6c6-709e-e053-3705fe0a83fd
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249
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Bacterial Endophytes Contribute to Rice Seedling Establishment Under Submergence, file 0d96d453-e482-4cf5-b477-ac901341b917
|
239
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Misexpression of a chloroplast aspartyl protease leads to severe growth defects and alters carbohydrate metabolism in Arabidopsis, file dd9e0b31-c039-709e-e053-3705fe0a83fd
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232
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A Trihelix DNA Binding Protein Counterbalances Hypoxia-Responsive Transcriptional Activation in Arabidopsis, file dd9e0b31-c18a-709e-e053-3705fe0a83fd
|
215
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Low Oxygen Response Mechanisms in Green Organisms, file dd9e0b31-c08f-709e-e053-3705fe0a83fd
|
203
|
Flooding tolerance in plants, file dd9e0b31-bf57-709e-e053-3705fe0a83fd
|
183
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New Role for an Old Rule: N-end Rule Mediated Degradation of ERF Proteins Governs Low Oxygen Response in Plants, file dd9e0b31-c06b-709e-e053-3705fe0a83fd
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178
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Analysis of the role of the pyruvate decarboxylase gene family in Arabidopsis thaliana under low-oxygen conditions, file dd9e0b31-c09a-709e-e053-3705fe0a83fd
|
167
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Iodine biofortification in tomato, file dd9e0b31-bfda-709e-e053-3705fe0a83fd
|
166
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Alcohol dehydrogenase and hydrogenase transcript fluctuations during a day/night cycle in Chlamydomonas reinhardtii: the role of anoxia, file dd9e0b31-bed8-709e-e053-3705fe0a83fd
|
163
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Distinct Mechanisms Regulating Gene Expression Coexist within the Fermentative Pathways in Chlamydomonas reinhardtii, file dd9e0b31-bf28-709e-e053-3705fe0a83fd
|
154
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How plants sense low oxygen, file dd9e0b31-bfb2-709e-e053-3705fe0a83fd
|
153
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ROS signaling as common element in low oxygen and heat stresses, file dd9e0b31-bf74-709e-e053-3705fe0a83fd
|
152
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A mutant in the ADH1 gene of Chlamydomonas reinhardtii elicits metabolic restructuring during anaerobiosis, file dd9e0b31-bf65-709e-e053-3705fe0a83fd
|
127
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Anthocyanin tomato mutants: overview and characterization of an anthocyaninless somaclonal mutant, file dd9e0b31-bf0e-709e-e053-3705fe0a83fd
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124
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Iodine fortification plant screening process and accumulation in tomato fruits and potato Tubers, file dd9e0b31-be84-709e-e053-3705fe0a83fd
|
106
|
Transcript profiling of chitosan-treated Arabidopsis seedlings, file dd9e0b31-beda-709e-e053-3705fe0a83fd
|
105
|
Community recommendations on terminology and procedures used in flooding and low oxygen stress research, file dd9e0b31-eb71-709e-e053-3705fe0a83fd
|
100
|
HRE1 and HRE2, two hypoxia-inducible ethylene response factors, affect anaerobic responses in Arabidopsis thaliana, file dd9e0b31-beb3-709e-e053-3705fe0a83fd
|
83
|
The atroviolacea gene encodes an R3-MYB protein repressing anthocyanin synthesis in tomato plants, file dd9e0b32-1e3c-709e-e053-3705fe0a83fd
|
83
|
Optimizing shelf life conditions for anthocyanin-rich tomatoes, file dd9e0b32-223e-709e-e053-3705fe0a83fd
|
83
|
Ethylene influences in vitro regeneration frequency in the FR13A
rice harbouring the SUB1A gene, file dd9e0b31-c052-709e-e053-3705fe0a83fd
|
82
|
Sucrose-specific induction of the anthocyanin biosynthetic pathway in Arabidopsis thaliana., file dd9e0b31-bc1c-709e-e053-3705fe0a83fd
|
80
|
Physiological responses to Megafol® treatments in tomato plants under drought stress: A phenomic and molecular approach, file dd9e0b31-c17e-709e-e053-3705fe0a83fd
|
73
|
Functional Balancing of the Hypoxia Regulators RAP2.12 and HRA1 Takes Place in vivo in Arabidopsis thaliana Plants, file dd9e0b31-eb73-709e-e053-3705fe0a83fd
|
68
|
Hormonal interplay during adventitious root formation in flooded tomato plants, file dd9e0b31-bec0-709e-e053-3705fe0a83fd
|
65
|
A genome wide-analysis of the effects of sucrose on gene expression in Arabidopsis under anoxia, file dd9e0b31-bc1b-709e-e053-3705fe0a83fd
|
63
|
Expansin gene expression and anoxic coleoptile elongation in rice cultivars, file dd9e0b31-bc8c-709e-e053-3705fe0a83fd
|
63
|
Proteomic identification of differentially expressed proteins in the anoxic rice coleoptile, file dd9e0b31-bf8b-709e-e053-3705fe0a83fd
|
63
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The Heat-Inducible Transcription Factor HsfA2 Enhances Anoxia Tolerance in Arabidopsis, file dd9e0b31-beb4-709e-e053-3705fe0a83fd
|
53
|
Distinct mechanisms for aerenchyma formation in leaf sheaths of rice genotypes displaying a quiescence or escape strategy for flooding tolerance, file dd9e0b31-be8f-709e-e053-3705fe0a83fd
|
49
|
Genomic approaches to unveil the physiological pathways activated in Arabidopsis treated with plant-derived raw extracts, file dd9e0b31-c13a-709e-e053-3705fe0a83fd
|
46
|
SUB1A dependent and independent mechanisms are involved in the flooding tolerance of wild rice species, file dd9e0b31-bf5c-709e-e053-3705fe0a83fd
|
45
|
Regulatory interplay of the Sub1A and CIPK15 pathways in the regulation of alpha-amylase production in flooded rice plants, file dd9e0b31-bed9-709e-e053-3705fe0a83fd
|
43
|
Reactive oxygen species-driven transcription in Arabidopsis under oxygen deprivation, file dd9e0b31-bf97-709e-e053-3705fe0a83fd
|
40
|
Recent progress in understanding the cellular and genetic basis of plant responses to low oxygen hold promise for developing flood-resilient crops, file 44b1b0ca-7f95-4aec-9e90-019e7fbb25dd
|
32
|
Genomic and transcriptomic analysis of the AP2/ERF superfamily in Vitis vinifera, file dd9e0b31-bedb-709e-e053-3705fe0a83fd
|
31
|
Anoxia Effects on Plant Physiology, file dd9e0b31-baff-709e-e053-3705fe0a83fd
|
16
|
Physiological responses to Megafol® treatments in tomato plants under drought stress: A phenomic and molecular approach, file dd9e0b31-c17c-709e-e053-3705fe0a83fd
|
16
|
Role of CBL/CIPK complex in Arabidopsis under oxygen shortage, file dd9e0b32-255c-709e-e053-3705fe0a83fd
|
4
|
Universal stress protein HRU1 mediates ROS homeostasis under anoxia, file dd9e0b31-d79b-709e-e053-3705fe0a83fd
|
3
|
Exploring legume-rhizobia symbiotic models for waterlogging tolerance, file dd9e0b32-2824-709e-e053-3705fe0a83fd
|
3
|
The Oxidative Paradox in Low Oxygen Stress in Plants, file dd9e0b32-4c0a-709e-e053-3705fe0a83fd
|
3
|
Low Oxygen Signaling and Tolerance in Plants, file dd9e0b31-bb92-709e-e053-3705fe0a83fd
|
2
|
Dissection of coleoptile elongation in japonica rice under submergence through integrated genome wide association mapping and transcriptional analyses, file dd9e0b32-313b-709e-e053-3705fe0a83fd
|
2
|
Transcriptional analysis in high-anthocyanin tomatoes reveals synergistical effect of Aft and atv genes, file dd9e0b31-bed6-709e-e053-3705fe0a83fd
|
1
|
Transcriptome profiling of short-term response to chilling stress in tolerant and sensitive Oryza sativa ssp. Japonica seedlings, file dd9e0b32-313d-709e-e053-3705fe0a83fd
|
1
|
A calcineurin B-like protein participates in low oxygen signalling in rice, file dd9e0b32-319e-709e-e053-3705fe0a83fd
|
1
|
The calcineurin β-like interacting protein kinase CIPK25 regulates potassium homeostasis under low oxygen in Arabidopsis, file dd9e0b32-4863-709e-e053-3705fe0a83fd
|
1
|
Auxin is required for the long coleoptile trait in japonica rice under submergence, file dd9e0b32-4866-709e-e053-3705fe0a83fd
|
1
|
A Ratiometric Sensor Based on Plant N-Terminal Degrons Able to Report Oxygen Dynamics in Saccharomyces cerevisiae, file dd9e0b32-51d8-709e-e053-3705fe0a83fd
|
1
|
Totale |
10.800 |