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Imaging plant growth in 4D: robust tissue reconstruction and lineaging at cell resolution
Nature Methods, ISSN 1548-7091, 07/2010, Volume 7, Issue 7, pp. 547 - 553
Quantitative information on growing organs is required to better understand morphogenesis in both plants and animals. However, detailed analyses of growth...
ARABIDOPSIS-THALIANA | NETWORK | SHOOT APEX | ELEGANS | BIOCHEMICAL RESEARCH METHODS | MODEL | MICROSCOPY | PHYLLOTAXIS | Green Fluorescent Proteins | Meristem - cytology | Reproducibility of Results | Arabidopsis - cytology | Flowers - cytology | Image Processing, Computer-Assisted - methods | Flowers - growth & development | Meristem - growth & development | Cell Lineage - physiology | Cell Division - physiology | Algorithms | Time Factors | Plant Proteins - metabolism | Arabidopsis thaliana | Morphogenesis | Growth | Physiological aspects | Development | Research | Plants | Scientific imaging | Plant growth | Cellular biology | Research methodology | Innovations | Life Sciences | Vegetal Biology
ARABIDOPSIS-THALIANA | NETWORK | SHOOT APEX | ELEGANS | BIOCHEMICAL RESEARCH METHODS | MODEL | MICROSCOPY | PHYLLOTAXIS | Green Fluorescent Proteins | Meristem - cytology | Reproducibility of Results | Arabidopsis - cytology | Flowers - cytology | Image Processing, Computer-Assisted - methods | Flowers - growth & development | Meristem - growth & development | Cell Lineage - physiology | Cell Division - physiology | Algorithms | Time Factors | Plant Proteins - metabolism | Arabidopsis thaliana | Morphogenesis | Growth | Physiological aspects | Development | Research | Plants | Scientific imaging | Plant growth | Cellular biology | Research methodology | Innovations | Life Sciences | Vegetal Biology
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Loading RightsThe Plant Journal, ISSN 0960-7412, 03/2013, Volume 73, Issue 6, pp. 1006 - 1018
Summary The grape berry provides a model for investigating the physiology of non‐climacteric fruits. Increased K+ accumulation in the berry has a strong...
expression pattern | Shaker K+ channel | CIPK–CBL network | grape berry flesh cells | K+ uptake | in situ hybridization | CIPK-CBL network | Shaker K | Expression pattern | uptake | channel | Grape berry flesh cells | In situ hybridization | NETWORK | HOMEOSTASIS | PROTEIN-KINASE | MECHANISMS | K plus uptake | PLANT SCIENCES | CIPKCBL network | Shaker K plus channel | XYLEM | HIGHER-PLANTS | AKT1 | ARABIDOPSIS | ACCUMULATION | VITIS-VINIFERA | Potassium - metabolism | Arabidopsis Proteins - genetics | Vitis - growth & development | Fruit - cytology | Shaker Superfamily of Potassium Channels - metabolism | Protein-Serine-Threonine Kinases - genetics | Molecular Sequence Data | Potassium Channels, Inwardly Rectifying - genetics | Phylogeny | Fruit - growth & development | Plant Proteins - genetics | Animals | Oocytes - physiology | Droughts | Cloning, Molecular | Gene Expression Regulation, Plant | Female | Ion Transport | Plant Proteins - metabolism | Vitis - metabolism | Fruit - metabolism | Potassium Channels, Inwardly Rectifying - metabolism | Vitis - genetics | Calcium-Binding Proteins - genetics | Arabidopsis thaliana | Fruit | Amphibians | Analysis | Plant biology | Berries | Drought | Stress response | Potassium | Life Sciences
expression pattern | Shaker K+ channel | CIPK–CBL network | grape berry flesh cells | K+ uptake | in situ hybridization | CIPK-CBL network | Shaker K | Expression pattern | uptake | channel | Grape berry flesh cells | In situ hybridization | NETWORK | HOMEOSTASIS | PROTEIN-KINASE | MECHANISMS | K plus uptake | PLANT SCIENCES | CIPKCBL network | Shaker K plus channel | XYLEM | HIGHER-PLANTS | AKT1 | ARABIDOPSIS | ACCUMULATION | VITIS-VINIFERA | Potassium - metabolism | Arabidopsis Proteins - genetics | Vitis - growth & development | Fruit - cytology | Shaker Superfamily of Potassium Channels - metabolism | Protein-Serine-Threonine Kinases - genetics | Molecular Sequence Data | Potassium Channels, Inwardly Rectifying - genetics | Phylogeny | Fruit - growth & development | Plant Proteins - genetics | Animals | Oocytes - physiology | Droughts | Cloning, Molecular | Gene Expression Regulation, Plant | Female | Ion Transport | Plant Proteins - metabolism | Vitis - metabolism | Fruit - metabolism | Potassium Channels, Inwardly Rectifying - metabolism | Vitis - genetics | Calcium-Binding Proteins - genetics | Arabidopsis thaliana | Fruit | Amphibians | Analysis | Plant biology | Berries | Drought | Stress response | Potassium | Life Sciences
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Loading RightsAnnals of Botany, ISSN 0305-7364, 10/2013, Volume 112, Issue 6, pp. 1003 - 1014
• Background and Aims Condensed tannins (also called proanthocyanidins) are widespread polymers of catechins and are essential for the defence mechanisms of...
Tannins | Chloroplasts | Polymerization | Thylakoids | Plants | Vascular plants | Diameters | Vacuoles | Chlorophylls | Plant cells | polymerization | tonoplast | proanthocyanidins | vascular plants | chloroplast | vacuole | organelle | condensed tannins | Tannosome | Tracheophyta | LOCALIZATION | UV-B RADIATION | LEAVES | PROANTHOCYANIDIN BIOSYNTHESIS | PHENOLIC-STORING CELLS | PLANT SCIENCES | CHALCONE SYNTHASE | ULTRASTRUCTURE | GRAPE BERRY DEVELOPMENT | ENDOPLASMIC-RETICULUM | ARABIDOPSIS | Organelles - chemistry | Tracheophyta - chemistry | Vacuoles - ultrastructure | Vitis - chemistry | Chloroplasts - chemistry | Chromatography, High Pressure Liquid | Vitis - ultrastructure | Proanthocyanidins - chemistry | Ebenaceae - chemistry | Organelles - ultrastructure | Vacuoles - chemistry | Ebenaceae - ultrastructure | Cell Membrane - metabolism | Catechin - metabolism | Fruit - ultrastructure | Fruit - metabolism | Plant Leaves - chemistry | Microscopy, Electron, Transmission | Chloroplasts - ultrastructure | Fruit - chemistry | Proanthocyanidins - metabolism | Ginkgo biloba - metabolism | Ginkgo biloba - ultrastructure | Cell Membrane - ultrastructure | Ginkgo biloba - chemistry | Chlorophyll - metabolism | Tracheophyta - metabolism | Chloroplasts - metabolism | Ebenaceae - metabolism | Microscopy, Confocal | Animals | Plant Leaves - metabolism | Models, Biological | Vacuoles - metabolism | Tracheophyta - ultrastructure | Vitis - metabolism | Organelles - metabolism | Plant Leaves - ultrastructure | Proanthocyanidins - isolation & purification | Life Sciences | Vegetal Biology | 2013 | Original
Tannins | Chloroplasts | Polymerization | Thylakoids | Plants | Vascular plants | Diameters | Vacuoles | Chlorophylls | Plant cells | polymerization | tonoplast | proanthocyanidins | vascular plants | chloroplast | vacuole | organelle | condensed tannins | Tannosome | Tracheophyta | LOCALIZATION | UV-B RADIATION | LEAVES | PROANTHOCYANIDIN BIOSYNTHESIS | PHENOLIC-STORING CELLS | PLANT SCIENCES | CHALCONE SYNTHASE | ULTRASTRUCTURE | GRAPE BERRY DEVELOPMENT | ENDOPLASMIC-RETICULUM | ARABIDOPSIS | Organelles - chemistry | Tracheophyta - chemistry | Vacuoles - ultrastructure | Vitis - chemistry | Chloroplasts - chemistry | Chromatography, High Pressure Liquid | Vitis - ultrastructure | Proanthocyanidins - chemistry | Ebenaceae - chemistry | Organelles - ultrastructure | Vacuoles - chemistry | Ebenaceae - ultrastructure | Cell Membrane - metabolism | Catechin - metabolism | Fruit - ultrastructure | Fruit - metabolism | Plant Leaves - chemistry | Microscopy, Electron, Transmission | Chloroplasts - ultrastructure | Fruit - chemistry | Proanthocyanidins - metabolism | Ginkgo biloba - metabolism | Ginkgo biloba - ultrastructure | Cell Membrane - ultrastructure | Ginkgo biloba - chemistry | Chlorophyll - metabolism | Tracheophyta - metabolism | Chloroplasts - metabolism | Ebenaceae - metabolism | Microscopy, Confocal | Animals | Plant Leaves - metabolism | Models, Biological | Vacuoles - metabolism | Tracheophyta - ultrastructure | Vitis - metabolism | Organelles - metabolism | Plant Leaves - ultrastructure | Proanthocyanidins - isolation & purification | Life Sciences | Vegetal Biology | 2013 | Original
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Loading RightsMolecules, ISSN 1420-3049, 03/2015, Volume 20, Issue 3, pp. 5024 - 5037
Autofluorescent molecules are abundant in plant cells and spectral images offer means for analyzing their spectra, yielding information on their accumulation...
Plant tissue | Secondary metabolites | Linear unmixing | Autofluorescence | Spectral imaging | Phenolic compounds | Hydroxycinnamic acids | COFFEA-PSEUDOZANGUEBARIAE | EXCITATION | MANGIFERIN | BIOCHEMISTRY & MOLECULAR BIOLOGY | LEAVES | LASER-INDUCED FLUORESCENCE | ABSORPTION | ACCUMULATION | GREEN PLANTS | CHEMISTRY, MULTIDISCIPLINARY | PRINCIPLES | ORGANELLE | Plant Leaves - chemistry | Phenols - analysis | Image Processing, Computer-Assisted | Fruit - chemistry | Coffea - chemistry | Microscopy, Fluorescence, Multiphoton - methods | Plant Cells - chemistry | Vanilla - chemistry | Secondary Metabolism | Life Sciences | Vegetal Biology | secondary metabolites | Linear Unmixing | plant tissue | phenolic compounds | hydroxycinnamic acids | spectral imaging | autofluorescence
Plant tissue | Secondary metabolites | Linear unmixing | Autofluorescence | Spectral imaging | Phenolic compounds | Hydroxycinnamic acids | COFFEA-PSEUDOZANGUEBARIAE | EXCITATION | MANGIFERIN | BIOCHEMISTRY & MOLECULAR BIOLOGY | LEAVES | LASER-INDUCED FLUORESCENCE | ABSORPTION | ACCUMULATION | GREEN PLANTS | CHEMISTRY, MULTIDISCIPLINARY | PRINCIPLES | ORGANELLE | Plant Leaves - chemistry | Phenols - analysis | Image Processing, Computer-Assisted | Fruit - chemistry | Coffea - chemistry | Microscopy, Fluorescence, Multiphoton - methods | Plant Cells - chemistry | Vanilla - chemistry | Secondary Metabolism | Life Sciences | Vegetal Biology | secondary metabolites | Linear Unmixing | plant tissue | phenolic compounds | hydroxycinnamic acids | spectral imaging | autofluorescence
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Loading RightsJournal of Experimental Botany, ISSN 0022-0957, 1/2011, Volume 62, Issue 12, pp. 4115 - 4126
It is not known to what degree aquaporin-facilitated water uptake differs between root development regions and types of root. The aim of this study was to...
Barley | Transpiration | Hydraulics | Aquaporins | Plant roots | Water uptake | Hydraulic conductivity | Plants | Adventitious roots | Seminal roots | RESEARCH PAPER | hydraulic conductivity | barley (Hordeum vulgare) | lateral root | Aquaporin inhibitor mercury chloride | cortical cell | ARABIDOPSIS-THALIANA | ZEA-MAYS | TRANSGENIC RICE PLANTS | PLASMA-MEMBRANE | PLANT SCIENCES | TRANSPORT | LEAF TISSUES | CHANNELS | EXPRESSION | CELL | Organ Specificity - drug effects | Plant Transpiration - drug effects | Hordeum - drug effects | Plant Roots - metabolism | Hordeum - metabolism | Hordeum - cytology | Water - metabolism | Aquaporins - metabolism | Mercuric Chloride - pharmacology | Plant Roots - cytology | Reverse Transcriptase Polymerase Chain Reaction | Aquaporins - genetics | Plant Roots - drug effects | Organ Specificity - genetics | Plant Proteins - genetics | Gene Expression Regulation, Plant - drug effects | Plant Proteins - metabolism | Hordeum - genetics | Dithiothreitol - pharmacology | Research Papers
Barley | Transpiration | Hydraulics | Aquaporins | Plant roots | Water uptake | Hydraulic conductivity | Plants | Adventitious roots | Seminal roots | RESEARCH PAPER | hydraulic conductivity | barley (Hordeum vulgare) | lateral root | Aquaporin inhibitor mercury chloride | cortical cell | ARABIDOPSIS-THALIANA | ZEA-MAYS | TRANSGENIC RICE PLANTS | PLASMA-MEMBRANE | PLANT SCIENCES | TRANSPORT | LEAF TISSUES | CHANNELS | EXPRESSION | CELL | Organ Specificity - drug effects | Plant Transpiration - drug effects | Hordeum - drug effects | Plant Roots - metabolism | Hordeum - metabolism | Hordeum - cytology | Water - metabolism | Aquaporins - metabolism | Mercuric Chloride - pharmacology | Plant Roots - cytology | Reverse Transcriptase Polymerase Chain Reaction | Aquaporins - genetics | Plant Roots - drug effects | Organ Specificity - genetics | Plant Proteins - genetics | Gene Expression Regulation, Plant - drug effects | Plant Proteins - metabolism | Hordeum - genetics | Dithiothreitol - pharmacology | Research Papers
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Loading RightsRice, ISSN 1939-8425, 3/2009, Volume 2, Issue 1, pp. 15 - 34
Plant roots have a large range of functions, including acquisition of water and nutrients, as well as structural support. Dissecting the genetic and molecular...
Life Sciences | Plant Breeding/Biotechnology | Root apical meristem | Molecular genetics | Oryza sativa L | Agriculture | Plant Sciences | Plant Ecology | Plant Genetics & Genomics | Rice | Mutants | AGRONOMY | MONOCOT-DICOT DIVERGENCE | CROWN ROOTS | APICAL MERISTEM | EPIDERMAL-CELL DEATH | ORYZA-SATIVA L | QUANTITATIVE TRAIT LOCI | AUXIN-RESPONSE-FACTOR | HOMEOBOX GENE | ARABIDOPSIS-THALIANA ROOT | MAPPING QTLS | Analysis | Genetic aspects | Plant biology | Genetics | Mutation | Molecular biology | Meristems | Pattern formation | Cereals | Molecular modelling | Roots | Cortex | Cytology | Development | Data processing | Nutrients | Embryos
Life Sciences | Plant Breeding/Biotechnology | Root apical meristem | Molecular genetics | Oryza sativa L | Agriculture | Plant Sciences | Plant Ecology | Plant Genetics & Genomics | Rice | Mutants | AGRONOMY | MONOCOT-DICOT DIVERGENCE | CROWN ROOTS | APICAL MERISTEM | EPIDERMAL-CELL DEATH | ORYZA-SATIVA L | QUANTITATIVE TRAIT LOCI | AUXIN-RESPONSE-FACTOR | HOMEOBOX GENE | ARABIDOPSIS-THALIANA ROOT | MAPPING QTLS | Analysis | Genetic aspects | Plant biology | Genetics | Mutation | Molecular biology | Meristems | Pattern formation | Cereals | Molecular modelling | Roots | Cortex | Cytology | Development | Data processing | Nutrients | Embryos
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Loading RightsTrends in Plant Science, ISSN 1360-1385, 2007, Volume 12, Issue 6, pp. 245 - 252
Little is known of the mechanisms that induce the dedifferentiation of a single somatic cell into a totipotent embryogenic cell that can either be regenerated...
EMBRYO DEVELOPMENT | INTERCELLULAR MOVEMENT | QUIESCENT CENTER | CHROMATIN | GENES | SHOOT APICAL MERISTEM | HEVEA-BRASILIENSIS | WUSCHEL | SOMATIC EMBRYOGENESIS | ARABIDOPSIS LEAFY COTYLEDON1 | PLANT SCIENCES | Chromatin - metabolism | Meristem - cytology | Pluripotent Stem Cells - cytology | Totipotent Stem Cells - ultrastructure | Pluripotent Stem Cells - ultrastructure | Microscopy, Electron | Plant Cells | Pluripotent Stem Cells - metabolism | Plants - metabolism | Models, Biological | Meristem - metabolism | Totipotent Stem Cells - cytology | Totipotent Stem Cells - metabolism | Plants - embryology
EMBRYO DEVELOPMENT | INTERCELLULAR MOVEMENT | QUIESCENT CENTER | CHROMATIN | GENES | SHOOT APICAL MERISTEM | HEVEA-BRASILIENSIS | WUSCHEL | SOMATIC EMBRYOGENESIS | ARABIDOPSIS LEAFY COTYLEDON1 | PLANT SCIENCES | Chromatin - metabolism | Meristem - cytology | Pluripotent Stem Cells - cytology | Totipotent Stem Cells - ultrastructure | Pluripotent Stem Cells - ultrastructure | Microscopy, Electron | Plant Cells | Pluripotent Stem Cells - metabolism | Plants - metabolism | Models, Biological | Meristem - metabolism | Totipotent Stem Cells - cytology | Totipotent Stem Cells - metabolism | Plants - embryology
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Loading RightsPlant and Cell Physiology, ISSN 0032-0781, 12/2010, Volume 51, Issue 12, pp. 2119 - 2131
Here we report on the characterization of rice osa-miR827 and its two target genes, OsSPX-MFS1 and OsSPX-MFS2, which encode SPX-MFS proteins predicted to be...
MFS domain | Spx proteins | MicroRNA | Phosphate | HOMEOSTASIS | SMALL RNAS | MICRORNAS | SACCHAROMYCES-CEREVISIAE | PLANT SCIENCES | CELL BIOLOGY | ORYZA-SATIVA | TRANSPORT | STRESS RESPONSES | PLANT-RESPONSES | SPX proteins | ARABIDOPSIS | EXPRESSION | Adaptation, Physiological | Sequence Deletion | RNA Transport | Plants, Genetically Modified - genetics | Genes, Plant | Oryza - metabolism | RNA, Messenger - genetics | Stress, Physiological | Plant Roots - genetics | RNA, Plant - genetics | DNA, Bacterial | Phosphates - metabolism | Plants, Genetically Modified - metabolism | Oryza - genetics | Gene Expression Regulation, Plant | Phosphates - deficiency | Plants, Genetically Modified - cytology | Transcription, Genetic | MicroRNAs - physiology | Plant Shoots - genetics | Oryza - cytology | Phosphates | Populations and Evolution | Genomics | Biodiversity | Cellular Biology | Life Sciences | Oryza sativa | Plant Shoots | Plant Roots | Plants, Genetically Modified | Computer Science | Biomolecules | Genetics | Vegetal Biology | Bioinformatics | Plants genetics | RNA, Plant | Quantitative Methods | Biochemistry, Molecular Biology | Systematics, Phylogenetics and taxonomy | Plant breeding | MicroRNAs | Molecular biology | Molecular Networks | RNA, Messenger
MFS domain | Spx proteins | MicroRNA | Phosphate | HOMEOSTASIS | SMALL RNAS | MICRORNAS | SACCHAROMYCES-CEREVISIAE | PLANT SCIENCES | CELL BIOLOGY | ORYZA-SATIVA | TRANSPORT | STRESS RESPONSES | PLANT-RESPONSES | SPX proteins | ARABIDOPSIS | EXPRESSION | Adaptation, Physiological | Sequence Deletion | RNA Transport | Plants, Genetically Modified - genetics | Genes, Plant | Oryza - metabolism | RNA, Messenger - genetics | Stress, Physiological | Plant Roots - genetics | RNA, Plant - genetics | DNA, Bacterial | Phosphates - metabolism | Plants, Genetically Modified - metabolism | Oryza - genetics | Gene Expression Regulation, Plant | Phosphates - deficiency | Plants, Genetically Modified - cytology | Transcription, Genetic | MicroRNAs - physiology | Plant Shoots - genetics | Oryza - cytology | Phosphates | Populations and Evolution | Genomics | Biodiversity | Cellular Biology | Life Sciences | Oryza sativa | Plant Shoots | Plant Roots | Plants, Genetically Modified | Computer Science | Biomolecules | Genetics | Vegetal Biology | Bioinformatics | Plants genetics | RNA, Plant | Quantitative Methods | Biochemistry, Molecular Biology | Systematics, Phylogenetics and taxonomy | Plant breeding | MicroRNAs | Molecular biology | Molecular Networks | RNA, Messenger
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Loading RightsINTERNATIONAL JOURNAL OF MOLECULAR SCIENCES, ISSN 1422-0067, 10/2019, Volume 20, Issue 19, p. 4665
Somatic embryogenesis (SE) is one of the most promising processes for large-scale dissemination of elite varieties. However, for many plant species, optimizing...
hormone content | cell fate | somatic embryogenesis | BIOCHEMISTRY & MOLECULAR BIOLOGY | ACQUISITION | totipotency | INDUCTION | MATURATION | QUANTITATIVE-ANALYSIS | CHEMISTRY, MULTIDISCIPLINARY | NORWAY SPRUCE | EMBRYO DEVELOPMENT | histology | GAS-CHROMATOGRAPHY | metabolomics | coffee | cell imaging | ARABIDOPSIS | CULTURES | EXPRESSION | Life Sciences | Vegetal Biology
hormone content | cell fate | somatic embryogenesis | BIOCHEMISTRY & MOLECULAR BIOLOGY | ACQUISITION | totipotency | INDUCTION | MATURATION | QUANTITATIVE-ANALYSIS | CHEMISTRY, MULTIDISCIPLINARY | NORWAY SPRUCE | EMBRYO DEVELOPMENT | histology | GAS-CHROMATOGRAPHY | metabolomics | coffee | cell imaging | ARABIDOPSIS | CULTURES | EXPRESSION | Life Sciences | Vegetal Biology
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Loading RightsBMC Plant Biology, ISSN 1471-2229, 08/2012, Volume 12, Issue 1, pp. 150 - 150
Background: Cell separation that occurs during fleshy fruit abscission and dry fruit dehiscence facilitates seed dispersal, the final stage of plant...
Cell separation | Polygalacturonase | Fruit development | Elaeis guineensis | Ethylene | Abscission | TOMATO FRUIT | ARABIDOPSIS-THALIANA | LEAF ABSCISSION | RAPE BRASSICA-NAPUS | PETIOLE ABSCISSION | FLOWER ABSCISSION | TRANSGENIC TOMATOES | PLANT SCIENCES | ANTISENSE RNA | OILSEED RAPE | CELL-SEPARATION PROCESSES | Arecaceae - enzymology | Protein Structure, Tertiary | Gene Expression Regulation, Enzymologic - drug effects | Arecaceae - growth & development | Multigene Family | Fruit - drug effects | Polygalacturonase - chemistry | RNA, Messenger - genetics | Molecular Sequence Data | Gene Expression Profiling | Phylogeny | RNA, Messenger - metabolism | Fruit - growth & development | Palm Oil | Arecaceae - genetics | Gene Expression Regulation, Plant - drug effects | In Situ Hybridization | Arecaceae - drug effects | Time Factors | Genes, Plant - genetics | Plant Oils - metabolism | Polygalacturonase - genetics | Ethylenes - pharmacology | Fruit - genetics | Plant proteins | Ripening | Crops | Physiological aspects | Genetic aspects | Gene expression | Oil palm | Enzymes | Wildlife conservation | Genes | Pectin | Arabidopsis thaliana | Dried fruit | Genetic research | Studies | Animal reproduction | Genetic engineering | Life Sciences | Vegetal Biology
Cell separation | Polygalacturonase | Fruit development | Elaeis guineensis | Ethylene | Abscission | TOMATO FRUIT | ARABIDOPSIS-THALIANA | LEAF ABSCISSION | RAPE BRASSICA-NAPUS | PETIOLE ABSCISSION | FLOWER ABSCISSION | TRANSGENIC TOMATOES | PLANT SCIENCES | ANTISENSE RNA | OILSEED RAPE | CELL-SEPARATION PROCESSES | Arecaceae - enzymology | Protein Structure, Tertiary | Gene Expression Regulation, Enzymologic - drug effects | Arecaceae - growth & development | Multigene Family | Fruit - drug effects | Polygalacturonase - chemistry | RNA, Messenger - genetics | Molecular Sequence Data | Gene Expression Profiling | Phylogeny | RNA, Messenger - metabolism | Fruit - growth & development | Palm Oil | Arecaceae - genetics | Gene Expression Regulation, Plant - drug effects | In Situ Hybridization | Arecaceae - drug effects | Time Factors | Genes, Plant - genetics | Plant Oils - metabolism | Polygalacturonase - genetics | Ethylenes - pharmacology | Fruit - genetics | Plant proteins | Ripening | Crops | Physiological aspects | Genetic aspects | Gene expression | Oil palm | Enzymes | Wildlife conservation | Genes | Pectin | Arabidopsis thaliana | Dried fruit | Genetic research | Studies | Animal reproduction | Genetic engineering | Life Sciences | Vegetal Biology
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Loading RightsThe Plant Journal, ISSN 0960-7412, 01/2010, Volume 61, Issue 1, pp. 58 - 69
Summary Grapevine (Vitis vinifera), the genome sequence of which has recently been reported, is considered as a model species to study fleshy fruit development...
expression pattern | drought stress | Shaker K+ channel | CIPK–CBL network | K+ uptake | in situ hybridization | CIPK-CBL network | Shaker K | Expression pattern | uptake | Drought stress | channel | In situ hybridization | ARABIDOPSIS-THALIANA | TRANSPORT-SYSTEM | PROTEIN-KINASE | PLANT POTASSIUM CHANNEL | PLANT SCIENCES | GENES | VINIFERA L. DEVELOPMENT | AKT1 | XENOPUS OOCYTES | NUTRITION | ACCUMULATION | Sodium Chloride - pharmacology | Fruit - drug effects | Potassium Channels - physiology | Plant Roots - genetics | Phylogeny | Plant Roots - drug effects | In Situ Hybridization | Plant Proteins - classification | Droughts | Polymerase Chain Reaction | Plant Components, Aerial - drug effects | Potassium Channels - classification | Shaker Superfamily of Potassium Channels - classification | Vitis - genetics | Fruit - genetics | Arabidopsis Proteins - genetics | Arabidopsis Proteins - physiology | Genome, Plant - genetics | Shaker Superfamily of Potassium Channels - genetics | Plant Proteins - physiology | Protein-Serine-Threonine Kinases - physiology | Computational Biology | Protein-Serine-Threonine Kinases - genetics | Gene Expression Regulation, Plant - genetics | Vitis - drug effects | Plant Components, Aerial - genetics | Shaker Superfamily of Potassium Channels - physiology | Potassium Channels - genetics | Abscisic Acid - pharmacology | Plant Proteins - genetics | Gene Expression Regulation, Plant - drug effects | Arabidopsis Proteins - classification | Acids | Kinases | Potassium | Genomics | Fruits | Sodium Chloride | Fruit | Plant Components, Aerial | Protein-Serine-Threonine Kinases | Vitis | Abscisic Acid | Genome, Plant | Potassium Channels | Life Sciences | Arabidopsis Proteins | Plant Roots | Gene Expression Regulation, Plant | Plant Proteins | Shaker Superfamily of Potassium Channels | Vegetal Biology
expression pattern | drought stress | Shaker K+ channel | CIPK–CBL network | K+ uptake | in situ hybridization | CIPK-CBL network | Shaker K | Expression pattern | uptake | Drought stress | channel | In situ hybridization | ARABIDOPSIS-THALIANA | TRANSPORT-SYSTEM | PROTEIN-KINASE | PLANT POTASSIUM CHANNEL | PLANT SCIENCES | GENES | VINIFERA L. DEVELOPMENT | AKT1 | XENOPUS OOCYTES | NUTRITION | ACCUMULATION | Sodium Chloride - pharmacology | Fruit - drug effects | Potassium Channels - physiology | Plant Roots - genetics | Phylogeny | Plant Roots - drug effects | In Situ Hybridization | Plant Proteins - classification | Droughts | Polymerase Chain Reaction | Plant Components, Aerial - drug effects | Potassium Channels - classification | Shaker Superfamily of Potassium Channels - classification | Vitis - genetics | Fruit - genetics | Arabidopsis Proteins - genetics | Arabidopsis Proteins - physiology | Genome, Plant - genetics | Shaker Superfamily of Potassium Channels - genetics | Plant Proteins - physiology | Protein-Serine-Threonine Kinases - physiology | Computational Biology | Protein-Serine-Threonine Kinases - genetics | Gene Expression Regulation, Plant - genetics | Vitis - drug effects | Plant Components, Aerial - genetics | Shaker Superfamily of Potassium Channels - physiology | Potassium Channels - genetics | Abscisic Acid - pharmacology | Plant Proteins - genetics | Gene Expression Regulation, Plant - drug effects | Arabidopsis Proteins - classification | Acids | Kinases | Potassium | Genomics | Fruits | Sodium Chloride | Fruit | Plant Components, Aerial | Protein-Serine-Threonine Kinases | Vitis | Abscisic Acid | Genome, Plant | Potassium Channels | Life Sciences | Arabidopsis Proteins | Plant Roots | Gene Expression Regulation, Plant | Plant Proteins | Shaker Superfamily of Potassium Channels | Vegetal Biology
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Loading RightsPlant Physiology, ISSN 0032-0889, 8/2009, Volume 150, Issue 4, pp. 1955 - 1971
Plant growth under low K⁺ availability or salt stress requires tight control of K⁺ and Na⁻ uptake, long-distance transport, and accumulation. The family of...
Phloem | Ethanol | Epidermal cells | Plant roots | Environmental Stress and Adaptation to Stress | Cell membranes | Plants | Porters | Potassium | Oocytes | Rice | SODIUM TRANSPORTER | CATION TRANSPORTERS | HIGHER-PLANTS | K+-TRANSPORT | KINETIC-ANALYSIS | CURRENT-VOLTAGE RELATIONSHIPS | HIGH-AFFINITY POTASSIUM | SALT TOLERANCE | SACCHAROMYCES-CEREVISIAE | PLASMA-MEMBRANE | PLANT SCIENCES | Potassium - metabolism | Oocytes - metabolism | Xenopus laevis | Molecular Sequence Data | Plant Roots - genetics | Plant Roots - cytology | Sodium - metabolism | Protein Transport | Genetic Variation | Plant Proteins - genetics | Animals | Oryza - genetics | Membrane Transport Proteins - genetics | Models, Biological | Gene Expression Regulation, Plant | Membrane Transport Proteins - metabolism | Plant Proteins - metabolism | Oryza - cytology | Evaluation | Carrier proteins | Phytochemistry | Biological transport | Physiological aspects | Ion transport | Genetic aspects | Research | Gene expression | Properties | Life Sciences | Oryza sativa | Sodium | Plant Roots | Membrane Transport Proteins | Plant Proteins | Vegetal Biology
Phloem | Ethanol | Epidermal cells | Plant roots | Environmental Stress and Adaptation to Stress | Cell membranes | Plants | Porters | Potassium | Oocytes | Rice | SODIUM TRANSPORTER | CATION TRANSPORTERS | HIGHER-PLANTS | K+-TRANSPORT | KINETIC-ANALYSIS | CURRENT-VOLTAGE RELATIONSHIPS | HIGH-AFFINITY POTASSIUM | SALT TOLERANCE | SACCHAROMYCES-CEREVISIAE | PLASMA-MEMBRANE | PLANT SCIENCES | Potassium - metabolism | Oocytes - metabolism | Xenopus laevis | Molecular Sequence Data | Plant Roots - genetics | Plant Roots - cytology | Sodium - metabolism | Protein Transport | Genetic Variation | Plant Proteins - genetics | Animals | Oryza - genetics | Membrane Transport Proteins - genetics | Models, Biological | Gene Expression Regulation, Plant | Membrane Transport Proteins - metabolism | Plant Proteins - metabolism | Oryza - cytology | Evaluation | Carrier proteins | Phytochemistry | Biological transport | Physiological aspects | Ion transport | Genetic aspects | Research | Gene expression | Properties | Life Sciences | Oryza sativa | Sodium | Plant Roots | Membrane Transport Proteins | Plant Proteins | Vegetal Biology
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Loading RightsNew Phytologist, ISSN 0028-646X, 04/2019, Volume 222, Issue 1, pp. 286 - 300
Summary In grapevine, climate changes lead to increased berry potassium (K+) contents that result in must with low acidity. Consequently, wines are becoming...
VvK3.1 channel | Shaker K+ channel | grapevine | grape berry K+ loading | phloem | paraheliotropic movements | pulvinus | Shaker K | grape berry K | channel | loading | RED-LIGHT | SOLUTE ACCUMULATION | PLANT SCIENCES | MOBILE ENERGY-SOURCE | AKT2 | SAMANEA-SAMAN | KINASE CIPK23 | VITIS-VINIFERA | WATER RELATIONS | PERIPHERAL XYLEM | Economics | Organoleptic properties | AKT2 protein | Electrophysiology | Acidity | Hybridization | Phylogeny | Potassium channels | Fluxes | Apoplast | Cytosol | Fruits | Ripening | Climate change | Leaves | Phloem | Phylogenetics | Aging | Potassium currents | Potassium | Life Sciences | Vegetal Biology
VvK3.1 channel | Shaker K+ channel | grapevine | grape berry K+ loading | phloem | paraheliotropic movements | pulvinus | Shaker K | grape berry K | channel | loading | RED-LIGHT | SOLUTE ACCUMULATION | PLANT SCIENCES | MOBILE ENERGY-SOURCE | AKT2 | SAMANEA-SAMAN | KINASE CIPK23 | VITIS-VINIFERA | WATER RELATIONS | PERIPHERAL XYLEM | Economics | Organoleptic properties | AKT2 protein | Electrophysiology | Acidity | Hybridization | Phylogeny | Potassium channels | Fluxes | Apoplast | Cytosol | Fruits | Ripening | Climate change | Leaves | Phloem | Phylogenetics | Aging | Potassium currents | Potassium | Life Sciences | Vegetal Biology
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