Emerging trends in the functional genomics of the abiotic stress response in crop plants.
about
Regulation of abiotic stress signal transduction by E3 ubiquitin ligases in Arabidopsis.Suitability Analysis and Projected Climate Change Impact on Banana and Coffee Production Zones in Nepal.Transcriptomic changes and signalling pathways induced by arsenic stress in rice roots.Characterization of expressed sequence tags (ESTs) of pigeonpea (Cajanus cajan L.) and functional validation of selected genes for abiotic stress tolerance in Arabidopsis thaliana.Common and distinct organ and stress responsive transcriptomic patterns in Oryza sativa and Arabidopsis thaliana.Individual vs. combinatorial effect of elevated CO2 conditions and salinity stress on Arabidopsis thaliana liquid cultures: comparing the early molecular response using time-series transcriptomic and metabolomic analysesFactors affecting food security and contribution of modern technologies in food sustainability.Cold-induced modulation and functional analyses of the DRE-binding transcription factor gene, GmDREB3, in soybean (Glycine max L.).Suppression Subtractive Hybridization Analysis of Genes Regulated by Application of Exogenous Abscisic Acid in Pepper Plant (Capsicum annuum L.) Leaves under Chilling Stress.Genome-Wide Analysis of Differentially Expressed Genes Relevant to Rhizome Formation in Lotus Root (Nelumbo nucifera Gaertn).Marker-assisted breeding as next-generation strategy for genetic improvement of productivity and quality: can it be realized in cotton?Roles for farnesol and ABA in Arabidopsis flower development.Glycinebetaine and abiotic stress tolerance in plantsUnravelling molecular responses to moderate dehydration in harvested fruit of sweet orange (Citrus sinensis L. Osbeck) using a fruit-specific ABA-deficient mutantLong-term balancing selection at the Phosphorus Starvation Tolerance 1 (PSTOL1) locus in wild, domesticated and weedy rice (Oryza).Phenotyping for drought tolerance of crops in the genomics era.Transcriptome analysis in different rice cultivars provides novel insights into desiccation and salinity stress responses.Engineering the future. Development of transgenic plants with enhanced tolerance to adverse environments.Systems biology approaches to abscisic acid signaling.Genetic approaches towards overcoming water deficit in plants - special emphasis on LEAs.SAPs as novel regulators of abiotic stress response in plants.Stress-inducible expression of barley Hva1 gene in transgenic mulberry displays enhanced tolerance against drought, salinity and cold stress.Transgenic Plants as Sensors of Environmental Pollution GenotoxicityRice A20/AN1 zinc-finger containing stress-associated proteins (SAP1/11) and a receptor-like cytoplasmic kinase (OsRLCK253) interact via A20 zinc-finger and confer abiotic stress tolerance in transgenic Arabidopsis plants.Water stress induces up-regulation of DOF1 and MIF1 transcription factors and down-regulation of proteins involved in secondary metabolism in amaranth roots (Amaranthus hypochondriacus L.).Arabidopsis Small Rubber Particle Protein Homolog SRPs Play Dual Roles as Positive Factors for Tissue Growth and Development and in Drought Stress Responses.Constitutive expression of CaSRP1, a hot pepper small rubber particle protein homolog, resulted in fast growth and improved drought tolerance in transgenic Arabidopsis plants.Drought stress-induced Rma1H1, a RING membrane-anchor E3 ubiquitin ligase homolog, regulates aquaporin levels via ubiquitination in transgenic Arabidopsis plants.Overexpression of a Phytophthora Cytoplasmic CRN Effector Confers Resistance to Disease, Salinity and Drought in Nicotiana benthamiana.Salt stress-induced alterations in the root proteome of barley genotypes with contrasting response towards salinity.Raising salinity tolerant rice: recent progress and future perspectives.Functional validation of Phragmites communis glutathione reductase (PhaGR) as an essential enzyme in salt tolerance.Comparative Transcriptional Profiling of Two Contrasting Barley Genotypes under Salinity Stress during the Seedling Stage.TaPUB1, a Putative E3 Ligase Gene from Wheat, Enhances Salt Stress Tolerance in Transgenic Nicotiana benthamiana.Ultrastructural and physiological responses of potato (Solanum tuberosum L.) plantlets to gradient saline stress.The effect of phospholipase Dalpha3 on Arabidopsis response to hyperosmotic stress and glucoseAnalysis of transcriptional and upstream regulatory sequence activity of two environmental stress-inducible genes, NBS-Str1 and BLEC-Str8, of rice.Signal transduction during cold stress in plants.Whole genome profiling physical map and ancestral annotation of tobacco Hicks Broadleaf.Food Legumes and Rising Temperatures: Effects, Adaptive Functional Mechanisms Specific to Reproductive Growth Stage and Strategies to Improve Heat Tolerance.
P2860
Q27686867-BBDAFB8F-65DC-4445-AB9D-849AB765BF96Q31133969-407F014C-23FF-4A2B-9326-2D4CC4B452F1Q33354347-D6C1C428-8093-4887-AF6F-64D454602974Q33529407-B469B3DF-B0A8-404E-B7E9-3C3EAAA4BD2BQ33755395-E8EBA340-0C3A-48BB-BE58-AF4C23E6D607Q33781696-9059CE49-8DD6-4CD9-9274-1DE04E4C71E5Q34048957-F50A3726-1DD3-4248-B1FD-76A5619CB50BQ34767539-8517702F-3E3E-4982-920D-9EF19C4D03C9Q34794176-D9383D80-643D-429F-A6AB-2F0FEE6E9892Q34806485-40136B3A-8451-4A42-94EF-D0BF42915A9EQ34974387-F5A3C9A4-2CBF-4986-9F02-79E21F9AC5C4Q35679118-C1CB4725-D97F-4D67-AECA-CE06D00C411DQ35896940-EA6D4B56-40E4-4558-AF2E-F1B59E61CA1CQ35940326-0C86BF6C-B558-436B-8F3C-9384D0CAC632Q35996381-1C093015-1909-4665-B9D8-14CA1C73BDACQ36246570-99AB82D9-5CFD-42FE-BEC9-3A230BBF1DA7Q36748116-427BFC1B-45A4-4EB9-A06A-ACBDD9BDF172Q37854442-64FBDA9E-DABD-42B4-A559-90A2DAC4B6BAQ37860973-91E96A4E-BFD0-4695-8EF3-6796390AB1FAQ38097775-9B77FD06-C486-44E8-9ABD-A3B435E84F61Q38103832-2CA6B845-155E-4B1F-8220-EDC66D235A8AQ38940864-C84359AA-8EE7-4003-8BF5-CBA2445AF465Q39018118-91BA78E8-829E-4B19-9DFB-6720272F4940Q39024554-F9766A12-6152-47B5-B142-B891E815CBC2Q39085466-32F36365-B8EB-474E-9658-3B38780E2631Q39136490-45A344BA-AF87-4484-A602-501AE14037B5Q39136499-AD0030E1-651C-4281-92DC-452CF37278BEQ39166445-542539A4-4F12-44AB-9422-47664A0700A8Q39379930-ACAF7745-10DF-4FD8-AB34-8972BCD3326AQ39599235-C5665F19-428B-41CA-B12F-3A45D9C9385DQ40109254-CB7C6A29-043B-4B2A-B0CB-10EDF68FF380Q41442030-12412416-6CAD-45DD-94FC-D321801B4609Q41472483-A65785AC-8A4D-41E8-93E7-8273E62E19C8Q41920841-185C6124-E1B3-4EB1-9527-CAD195F5C88FQ41964112-670C232D-B451-4350-98D9-D58F794FEC6EQ42149802-428629A7-60B0-4DA0-BF6E-8E3281C35CB9Q42490987-788BF83A-AFD8-48F2-BF40-253105657F9FQ42878154-1316258B-4FA1-41BA-9FD9-050A65D4F34BQ42912480-FE2065C1-8747-4105-BC1E-821F402C5969Q43231033-CEDEFA86-640D-4359-AC32-1FA9E4D7E5D5
P2860
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@ast
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@en
type
label
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@ast
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@en
prefLabel
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@ast
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@en
P2860
P1476
Emerging trends in the functional genomics of the abiotic stress response in crop plants.
@en
P2093
Akhilesh K Tyagi
Shubha Vij
P2860
P304
P356
10.1111/J.1467-7652.2007.00239.X
P577
2007-05-01T00:00:00Z