A.thaliana mRNA for LEA D113 type 1 protein.Raynal M.Cited forNUCLEOTIDE SEQUENCE [MRNA]Straincv. ColumbiaTissueDry seedCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)Submission Submitted to EMBL/GenBank/DDBJ databases (OCT-1995)Cited in1
Structural analysis of Arabidopsis thaliana chromosome 5. XI.Kaneko T., Katoh T., Asamizu E., Sato S., Nakamura Y., Kotani H., Tabata S.Cited forNUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]Straincv. ColumbiaCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)Submission Submitted to EMBL/GenBank/DDBJ databases (MAY-2000)Cited in3017
Araport11: a complete reannotation of the Arabidopsis thaliana reference genome.Cheng C.Y., Krishnakumar V., Chan A.P., Thibaud-Nissen F., Schobel S., Town C.D.View abstractCited forGENOME REANNOTATIONStraincv. ColumbiaCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCPlant J. 89:789-804 (2017)Cited in99+99+
Empirical analysis of transcriptional activity in the Arabidopsis genome.Yamada K., Lim J., Dale J.M., Chen H., Shinn P., Palm C.J., Southwick A.M., Wu H.C., Kim C.J.[...], Ecker J.R.View abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE MRNA]Straincv. ColumbiaCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCScience 302:842-846 (2003)Cited in99+Mapped to2
Further progress towards a catalogue of all Arabidopsis genes: analysis of a set of 5000 non-redundant ESTs.Cooke R., Raynal M., Laudie M., Grellet F., Delseny M., Morris P.-C., Guerrier D., Giraudat J., Quigley F.[...], Hoefte H.View abstractCited forNUCLEOTIDE SEQUENCE [LARGE SCALE MRNA] OF 1-82Straincv. ColumbiaTissueDry seedCategorySequencesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCPlant J. 9:101-124 (1996)Cited in92
LEA (late embryogenesis abundant) proteins and their encoding genes in Arabidopsis thaliana.Hundertmark M., Hincha D.K.View abstractCited forGENE FAMILY, NOMENCLATURECategoryNamesSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCBMC Genomics 9:118-118 (2008)Cited in15Mapped to47
Functional analysis of the group 4 late embryogenesis abundant proteins reveals their relevance in the adaptive response during water deficit in Arabidopsis.Olvera-Carrillo Y., Campos F., Reyes J.L., Garciarrubio A., Covarrubias A.A.View abstractCited forFUNCTION, DEVELOPMENTAL STAGE, INDUCTIONCategoriesFunction, ExpressionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCPlant Physiol. 154:373-390 (2010)Cited in3
The unstructured N-terminal region of Arabidopsis group 4 late embryogenesis abundant (LEA) proteins is required for folding and for chaperone-like activity under water deficit.Cuevas-Velazquez C.L., Saab-Rincon G., Reyes J.L., Covarrubias A.A.View abstractCited forFUNCTIONCategoryFunctionSourceUniProtKB reviewed (Swiss-Prot)PubMedEurope PMCJ. Biol. Chem. 291:10893-10903 (2016)Cited in2Mapped to1
Divergence in the Regulation of the Salt Tolerant Response Between <i>Arabidopsis thaliana</i> and Its Halophytic Relative <i>Eutrema salsugineum</i> by mRNA Alternative Polyadenylation.Ma H., Cai L., Lin J., Zhou K., Li Q.Q.View abstractCategoryExpressionSourceTAIR: AT5G06760PubMedEurope PMCFront Plant Sci 13:866054-866054 (2022)Mapped to4
BASIC PENTACYSTEINE2 negatively regulates osmotic stress tolerance by modulating LEA4-5 expression in Arabidopsis thaliana.Li Q., Wang M., Fang L.View abstractAnnotationBASIC PENTACYSTEINE2 negatively regulates osmotic stress tolerance by modulating LEA4-5 expression in Arabidopsis thaliana.CategoriesFunction, ExpressionSourceGeneRif: 830565, TAIR: AT5G06760PubMedEurope PMCPlant Physiol Biochem 168:373-380 (2021)Mapped to6
Intrinsically disordered protein biosensor tracks the physical-chemical effects of osmotic stress on cells.Cuevas-Velazquez C.L., Vellosillo T., Guadalupe K., Schmidt H.B., Yu F., Moses D., Brophy J.A.N., Cosio-Acosta D., Das A.[...], Dinneny J.R.View abstractAnnotationIntrinsically disordered protein biosensor tracks the physical-chemical effects of osmotic stress on cells.CategoryFunctionSourceGeneRif: 830565, TAIR: AT5G06760PubMedEurope PMCNat Commun 12:5438-5438 (2021)Mapped to2
Investigation of a Novel Salt Stress-Responsive Pathway Mediated by Arabidopsis DEAD-Box RNA Helicase Gene <i>AtRH17</i> Using RNA-Seq Analysis.Seok H.Y., Nguyen L.V., Van Nguyen D., Lee S.Y., Moon Y.H.View abstractCategoriesFunction, ExpressionSourceTAIR: AT5G06760PubMedEurope PMCInt J Mol Sci 21:E1595-E1595 (2020)Mapped to12
AtMYB44 suppresses transcription of the late embryogenesis abundant protein gene AtLEA4-5.Nguyen N.H., Nguyen C.T.T., Jung C., Cheong J.J.View abstractAnnotationThese results indicate that MYB44 suppresses polymerase-mediated transcription of the LEA4-5.CategoriesFunction, ExpressionSourceGeneRif: 830565, pGenN:30851934, pGenN:30851934, TAIR: AT5G06760PubMedEurope PMCBiochem Biophys Res Commun 511:931-934 (2019)Mapped to4
Metal-binding polymorphism in late embryogenesis abundant protein AtLEA4- 5, an intrinsically disordered protein.French-Pacheco L., Cuevas-Velazquez C.L., Rivillas-Acevedo L., Covarrubias A.A., Amero C.View abstractCategoryFunctionSourceTAIR: AT5G06760PubMedEurope PMCPeerJ 6:e4930-e4930 (2018)Mapped to1
Salt hypersensitive mutant 9, a nucleolar APUM23 protein, is essential for salt sensitivity in association with the ABA signaling pathway in Arabidopsis.Huang K.-C., Lin W.-C., Cheng W.-H.View abstractCategoriesFunction, ExpressionSourceTAIR: AT5G06760PubMedEurope PMCBMC Plant Biol. 18:40-40 (2018)Cited in1Mapped to99+
The ubiquitous distribution of late embryogenesis abundant proteins across cell compartments in Arabidopsis offers tailored protection against abiotic stress.Candat A., Paszkiewicz G., Neveu M., Gautier R., Logan D.C., Avelange-Macherel M.-H., Macherel D.View abstractCategoriesNames, Subcellular LocationSourceTAIR: AT5G06760PubMedEurope PMCPlant Cell 26:3148-3166 (2014)Cited in12Mapped to54
Functional dissection of hydrophilins during in vitro freeze protection.Reyes J.L., Campos F., Wei H., Arora R., Yang Y., Karlson D.T., Covarrubias A.A.View abstractCategoriesFunction, Phenotypes & VariantsSourceTAIR: AT5G06760PubMedEurope PMCPlant Cell Environ 31:1781-1790 (2008)Mapped to3
The Arabidopsis sweetie mutant is affected in carbohydrate metabolism and defective in the control of growth, development and senescence.Veyres N., Danon A., Aono M., Galliot S., Karibasappa Y.B., Diet A., Grandmottet F., Tamaoki M., Lesur D.[...], Sangwan R.S.View abstractCategoriesFunction, Phenotypes & VariantsSourceTAIR: AT5G06760PubMedEurope PMCPlant J. 55:665-686 (2008)Cited in1Mapped to40
Salt stress responses in Arabidopsis utilize a signal transduction pathway related to endoplasmic reticulum stress signaling.Liu J.X., Srivastava R., Che P., Howell S.H.View abstractCategoryFunctionSourceTAIR: AT5G06760PubMedEurope PMCPlant J. 51:897-909 (2007)Cited in4Mapped to41
Components of the Arabidopsis mRNA decapping complex are required for early seedling development.Goeres D.C., Van Norman J.M., Zhang W., Fauver N.A., Spencer M.L., Sieburth L.E.View abstractCategoryFunctionSourceTAIR: AT5G06760PubMedEurope PMCPlant Cell 19:1549-1564 (2007)Cited in2Mapped to17
Regulation and functional analysis of ZmDREB2A in response to drought and heat stresses in Zea mays L.Qin F., Kakimoto M., Sakuma Y., Maruyama K., Osakabe Y., Tran L.S., Shinozaki K., Yamaguchi-Shinozaki K.View abstractCategoryExpressionSourceTAIR: AT5G06760PubMedEurope PMCPlant J 50:54-69 (2007)Mapped to61
Proteomic and transcriptomic analysis of Arabidopsis seeds: molecular evidence for successive processing of seed proteins and its implication in the stress response to sulfur nutrition.Higashi Y., Hirai M.Y., Fujiwara T., Naito S., Noji M., Saito K.View abstractCategorySequencesSourceTAIR: AT5G06760PubMedEurope PMCPlant J 48:557-571 (2006)Mapped to48
The phs1-3 mutation in a putative dual-specificity protein tyrosine phosphatase gene provokes hypersensitive responses to abscisic acid in Arabidopsis thaliana.Quettier A.L., Bertrand C., Habricot Y., Miginiac E., Agnes C., Jeannette E., Maldiney R.View abstractCategoriesFunction, Phenotypes & VariantsSourceTAIR: AT5G06760PubMedEurope PMCPlant J. 47:711-719 (2006)Cited in1Mapped to20
Induction of abscisic acid-regulated gene expression by diacylglycerol pyrophosphate involves Ca2+ and anion currents in Arabidopsis suspension cells.Zalejski C., Paradis S., Maldiney R., Habricot Y., Miginiac E., Rona J.-P., Jeannette E.View abstractCategoryExpressionSourceTAIR: AT5G06760PubMedEurope PMCPlant Physiol. 141:1555-1562 (2006)Cited in1Mapped to5
Transcriptome analysis of Arabidopsis clubroots indicate a key role for cytokinins in disease development.Siemens J., Keller I., Sarx J., Kunz S., Schuller A., Nagel W., Schmuelling T., Parniske M., Ludwig-Mueller J.View abstractCategoryExpressionSourceTAIR: AT5G06760PubMedEurope PMCMol. Plant Microbe Interact. 19:480-494 (2006)Cited in1Mapped to99+