Current Biology, ISSN 0960-9822, 09/2017, Volume 27, Issue 17, pp. R874 - R878
Reproduction is a critical time in plant life history. Therefore, genes affecting seed dormancy and germination are among those under strongest selection in...
TIME | ARABIDOPSIS | BIOCHEMISTRY & MOLECULAR BIOLOGY | CELL BIOLOGY | Germination - drug effects | Plant Dormancy - physiology | Seeds - growth & development | Seeds - physiology | Seeds - drug effects | Germination - physiology | Plant Growth Regulators - pharmacology | Plant Dormancy - drug effects | Physiological aspects | Seeds | Plant populations | Germination | Analysis
TIME | ARABIDOPSIS | BIOCHEMISTRY & MOLECULAR BIOLOGY | CELL BIOLOGY | Germination - drug effects | Plant Dormancy - physiology | Seeds - growth & development | Seeds - physiology | Seeds - drug effects | Germination - physiology | Plant Growth Regulators - pharmacology | Plant Dormancy - drug effects | Physiological aspects | Seeds | Plant populations | Germination | Analysis
Journal Article
Journal of Experimental Botany, ISSN 0022-0957, 02/2017, Volume 68, Issue 4, pp. 843 - 856
Many molecular mechanisms that regulate dormancy have been identified individually in controlled laboratory studies. However, little is known about how the...
Annual life cycle | Seed dormancy | Arabidopsis | DOG1 | PHYA | Germination | Nitrate signalling | Dormancy cycling | dormancy cycling | ARABIDOPSIS-THALIANA | LOCAL ADAPTATION | SISYMBRIUM-OFFICINALE SEEDS | MATURATION ENVIRONMENT | LOW-TEMPERATURE | PLANT SCIENCES | germination | seed dormancy | THRESHOLD MODELS | HYDROTHERMAL TIME | nitrate signalling | ABSCISIC-ACID | LIGHT SENSITIVITY | MOLECULAR-MECHANISMS | Arabidopsis - physiology | Plant Dormancy - physiology | Arabidopsis - growth & development | Gene Expression Regulation, Plant - physiology | Light | Environment | Plant Physiological Phenomena | Seasons | Water - physiology
Annual life cycle | Seed dormancy | Arabidopsis | DOG1 | PHYA | Germination | Nitrate signalling | Dormancy cycling | dormancy cycling | ARABIDOPSIS-THALIANA | LOCAL ADAPTATION | SISYMBRIUM-OFFICINALE SEEDS | MATURATION ENVIRONMENT | LOW-TEMPERATURE | PLANT SCIENCES | germination | seed dormancy | THRESHOLD MODELS | HYDROTHERMAL TIME | nitrate signalling | ABSCISIC-ACID | LIGHT SENSITIVITY | MOLECULAR-MECHANISMS | Arabidopsis - physiology | Plant Dormancy - physiology | Arabidopsis - growth & development | Gene Expression Regulation, Plant - physiology | Light | Environment | Plant Physiological Phenomena | Seasons | Water - physiology
Journal Article
Journal of Experimental Botany, ISSN 0022-0957, 05/2016, Volume 67, Issue 11, pp. 3189 - 3203
While diverse modes of quiescence span plant life cycles, form, and stress responses, the physiology of dormancy is distinct, and entrained in the life history...
Bud | meristem | seed | cell cycle | dormancy | chromatin accessibility | plant | oxygen and redox signalling | quiescence | seasonality | ARABIDOPSIS-THALIANA | NATURAL ALLELIC VARIATION | BUD DORMANCY | SEED DORMANCY | PLANT SCIENCES | NITRIC-OXIDE | DESICCATION-TOLERANCE | CELL-CYCLE | END RULE PATHWAY | MADS-BOX GENES | FREEZING TOLERANCE | Terminology as Topic | Trees - physiology | Botany | Plant Dormancy
Bud | meristem | seed | cell cycle | dormancy | chromatin accessibility | plant | oxygen and redox signalling | quiescence | seasonality | ARABIDOPSIS-THALIANA | NATURAL ALLELIC VARIATION | BUD DORMANCY | SEED DORMANCY | PLANT SCIENCES | NITRIC-OXIDE | DESICCATION-TOLERANCE | CELL-CYCLE | END RULE PATHWAY | MADS-BOX GENES | FREEZING TOLERANCE | Terminology as Topic | Trees - physiology | Botany | Plant Dormancy
Journal Article
Planta, ISSN 0032-0935, 1/2011, Volume 233, Issue 5, pp. 971 - 983
Low, non-freezing temperatures and/or short daylength (SD) regulates cold acclimation and dormancy in fruit trees. Regarding cold acclimation, C-repeat binding...
Dormancy | Leaves | Transcription factors | Genes | Greenhouses | Acclimatization | Plants | Transgenic plants | Freezing | Low temperature | Life Sciences | AP2/ERF | Forestry | Transgenic apple | Ecology | Agriculture | Leaf senescence | Plant Sciences | Cold acclimation | BINDING DOMAIN | DROUGHT | EVERGREEN PEACH | LOW-TEMPERATURE | PLANT SCIENCES | ACCLIMATION | RESISTANCE | WINTER HARDINESS | GENE FAMILY | ARABIDOPSIS | FREEZING TOLERANCE | Plant Dormancy - physiology | DNA, Complementary - genetics | Molecular Sequence Data | Prunus - metabolism | Gene Expression Regulation, Plant | Trans-Activators - genetics | Trans-Activators - biosynthesis | Acclimatization - physiology | Amino Acid Sequence | Cold Temperature | Plants, Genetically Modified - genetics | Photoperiod | DNA, Complementary - isolation & purification | Malus - genetics | Plant Proteins - genetics | Sequence Alignment | Malus - metabolism | Plants, Genetically Modified - metabolism | Aging - physiology | Plant Leaves - genetics | Plant Leaves - metabolism | Prunus - genetics | Plant Dormancy - genetics | Acclimatization - genetics | Plant Proteins - biosynthesis | Computer industry | Anopheles | Atmospheric carbon dioxide
Dormancy | Leaves | Transcription factors | Genes | Greenhouses | Acclimatization | Plants | Transgenic plants | Freezing | Low temperature | Life Sciences | AP2/ERF | Forestry | Transgenic apple | Ecology | Agriculture | Leaf senescence | Plant Sciences | Cold acclimation | BINDING DOMAIN | DROUGHT | EVERGREEN PEACH | LOW-TEMPERATURE | PLANT SCIENCES | ACCLIMATION | RESISTANCE | WINTER HARDINESS | GENE FAMILY | ARABIDOPSIS | FREEZING TOLERANCE | Plant Dormancy - physiology | DNA, Complementary - genetics | Molecular Sequence Data | Prunus - metabolism | Gene Expression Regulation, Plant | Trans-Activators - genetics | Trans-Activators - biosynthesis | Acclimatization - physiology | Amino Acid Sequence | Cold Temperature | Plants, Genetically Modified - genetics | Photoperiod | DNA, Complementary - isolation & purification | Malus - genetics | Plant Proteins - genetics | Sequence Alignment | Malus - metabolism | Plants, Genetically Modified - metabolism | Aging - physiology | Plant Leaves - genetics | Plant Leaves - metabolism | Prunus - genetics | Plant Dormancy - genetics | Acclimatization - genetics | Plant Proteins - biosynthesis | Computer industry | Anopheles | Atmospheric carbon dioxide
Journal Article
Proceedings of the National Academy of Sciences of the United States of America, ISSN 0027-8424, 4/2016, Volume 113, Issue 15, pp. E2199 - E2206
Seed germination and flowering, two critical developmental transitions in plant life cycles, are coordinately regulated by genetic and environmental factors to...
Seed dormancy | Flowering | Lettuce | DOG1 | MiRNA | TRANSCRIPTION FACTORS | ARABIDOPSIS-THALIANA | GENE-REGULATION CASCADES | HISTONE H2B MONOUBIQUITINATION | PHASE-TRANSITIONS | MULTIDISCIPLINARY SCIENCES | LOCUS-C EXPRESSION | BINDING-PROTEIN | flowering | lettuce | LIFE-CYCLES | seed dormancy | miRNA | ABSCISIC-ACID | FLORAL TRANSITION | Arabidopsis Proteins - genetics | Lettuce - genetics | Plant Dormancy - physiology | Flowers - metabolism | MicroRNAs - metabolism | Arabidopsis - metabolism | Arabidopsis - genetics | Transcription, Genetic - physiology | Arabidopsis Proteins - biosynthesis | Gene Expression Regulation, Plant - physiology | MicroRNAs - genetics | Mutation | Flowers - genetics | Lettuce - metabolism | Plants, Flowering of | MicroRNA | Germination | Physiological aspects | Genetic aspects | Observations | Biological Sciences | PNAS Plus
Seed dormancy | Flowering | Lettuce | DOG1 | MiRNA | TRANSCRIPTION FACTORS | ARABIDOPSIS-THALIANA | GENE-REGULATION CASCADES | HISTONE H2B MONOUBIQUITINATION | PHASE-TRANSITIONS | MULTIDISCIPLINARY SCIENCES | LOCUS-C EXPRESSION | BINDING-PROTEIN | flowering | lettuce | LIFE-CYCLES | seed dormancy | miRNA | ABSCISIC-ACID | FLORAL TRANSITION | Arabidopsis Proteins - genetics | Lettuce - genetics | Plant Dormancy - physiology | Flowers - metabolism | MicroRNAs - metabolism | Arabidopsis - metabolism | Arabidopsis - genetics | Transcription, Genetic - physiology | Arabidopsis Proteins - biosynthesis | Gene Expression Regulation, Plant - physiology | MicroRNAs - genetics | Mutation | Flowers - genetics | Lettuce - metabolism | Plants, Flowering of | MicroRNA | Germination | Physiological aspects | Genetic aspects | Observations | Biological Sciences | PNAS Plus
Journal Article
Proceedings of the National Academy of Sciences of the United States of America, ISSN 0027-8424, 9/2013, Volume 110, Issue 38, pp. 15485 - 15490
The transition from dormancy to germination in seeds is a key physiological process during the lifecycle of plants. Abscisic acid (ABA) is the sole plant...
Dormancy | Seed dormancy | Cotyledons | RNA | Germination | Auxins | Greening | Plants | Hormones | Seed germination | Preharvest sprouting | Evolutionary mechanism | Agriculture | Interaction | evolutionary mechanism | ROOT | hormones | MULTIDISCIPLINARY SCIENCES | BOX PROTEIN TIR1 | RECEPTOR | PLANT DEVELOPMENT | GERMINATION | agriculture | RESPONSE FACTORS | YUCCA FLAVIN MONOOXYGENASES | preharvest sprouting | BIOSYNTHESIS | GROWTH | interaction | GENE-EXPRESSION | Arabidopsis - physiology | Indoleacetic Acids - metabolism | Plant Dormancy - physiology | Gene Expression Profiling | Blotting, Western | Arabidopsis - metabolism | Arabidopsis Proteins - metabolism | Transcription Factors - metabolism | Two-Hybrid System Techniques | Blotting, Northern | Chromatin Immunoprecipitation | Gene Expression Regulation, Plant - physiology | Signal Transduction - physiology | Abscisic Acid - metabolism | Arabidopsis thaliana | Auxin | Physiological aspects | Abscisic acid | Cellular signal transduction | Research | Health aspects | Biological Sciences
Dormancy | Seed dormancy | Cotyledons | RNA | Germination | Auxins | Greening | Plants | Hormones | Seed germination | Preharvest sprouting | Evolutionary mechanism | Agriculture | Interaction | evolutionary mechanism | ROOT | hormones | MULTIDISCIPLINARY SCIENCES | BOX PROTEIN TIR1 | RECEPTOR | PLANT DEVELOPMENT | GERMINATION | agriculture | RESPONSE FACTORS | YUCCA FLAVIN MONOOXYGENASES | preharvest sprouting | BIOSYNTHESIS | GROWTH | interaction | GENE-EXPRESSION | Arabidopsis - physiology | Indoleacetic Acids - metabolism | Plant Dormancy - physiology | Gene Expression Profiling | Blotting, Western | Arabidopsis - metabolism | Arabidopsis Proteins - metabolism | Transcription Factors - metabolism | Two-Hybrid System Techniques | Blotting, Northern | Chromatin Immunoprecipitation | Gene Expression Regulation, Plant - physiology | Signal Transduction - physiology | Abscisic Acid - metabolism | Arabidopsis thaliana | Auxin | Physiological aspects | Abscisic acid | Cellular signal transduction | Research | Health aspects | Biological Sciences
Journal Article
Plant, Cell & Environment, ISSN 0140-7791, 06/2015, Volume 38, Issue 6, pp. 1157 - 1166
Dormancy‐associated MADS‐box (DAM) genes play an important role in endodormancy phase transition. We investigated histone modification in the DAM homolog...
C‐repeat binding factor (CBF) gene | FLOWERING LOCUS T (FT) gene | Japanese pear (Pyrus pyrifolia Nakai) | BUD FORMATION | LEAFY SPURGE | DNA METHYLATION | CHROMATIN IMMUNOPRECIPITATION | PERSICA L. BATSCH | RELEASE | PLANT SCIENCES | C-repeat binding factor (CBF) gene | ARABIDOPSIS | TRANSCRIPTION FACTOR | EXPRESSION | REVEALS | Plant Dormancy - physiology | Plant Proteins - physiology | Down-Regulation | MADS Domain Proteins - genetics | Gene Expression Regulation, Plant - genetics | Genes, Plant - physiology | Reverse Transcriptase Polymerase Chain Reaction | Pyrus - physiology | MADS Domain Proteins - metabolism | Plant Proteins - genetics | Chromatin Immunoprecipitation | Genes, Plant - genetics | Pyrus - genetics | Gene Expression Regulation, Plant - physiology | Pyrus - metabolism | Plant Dormancy - genetics | Signal Transduction - physiology | Histone Code - physiology | Histone Code - genetics | MADS Domain Proteins - physiology | Genes | Immunoglobulin G | Erythromycin
C‐repeat binding factor (CBF) gene | FLOWERING LOCUS T (FT) gene | Japanese pear (Pyrus pyrifolia Nakai) | BUD FORMATION | LEAFY SPURGE | DNA METHYLATION | CHROMATIN IMMUNOPRECIPITATION | PERSICA L. BATSCH | RELEASE | PLANT SCIENCES | C-repeat binding factor (CBF) gene | ARABIDOPSIS | TRANSCRIPTION FACTOR | EXPRESSION | REVEALS | Plant Dormancy - physiology | Plant Proteins - physiology | Down-Regulation | MADS Domain Proteins - genetics | Gene Expression Regulation, Plant - genetics | Genes, Plant - physiology | Reverse Transcriptase Polymerase Chain Reaction | Pyrus - physiology | MADS Domain Proteins - metabolism | Plant Proteins - genetics | Chromatin Immunoprecipitation | Genes, Plant - genetics | Pyrus - genetics | Gene Expression Regulation, Plant - physiology | Pyrus - metabolism | Plant Dormancy - genetics | Signal Transduction - physiology | Histone Code - physiology | Histone Code - genetics | MADS Domain Proteins - physiology | Genes | Immunoglobulin G | Erythromycin
Journal Article
Plant biology (Stuttgart, Germany), ISSN 1435-8603, 11/2014, Volume 16, Issue 6, pp. 1065 - 1074
The aim of this work was to examine whether seed ecophysiological traits in three closely related Crocus species were associated with ecological niche...
Epicotyl dormancy | Seed dormancy | Embryo growth | Germination | Shoot emergence | epicotyl dormancy | SIZE | HYBRIDIZATION | MATURATION | EMERGENCE | ECOPHYSIOLOGY | PLANT SCIENCES | germination | seed dormancy | TEMPERATURE | shoot emergence | ADAPTATION | AMARYLLIDACEAE | MORPHOPHYSIOLOGICAL DORMANCY | Biological Evolution | Crocus - physiology | Plant Dormancy - physiology | Seeds - physiology | Species Specificity | Germination - physiology | Crocus - genetics | Seasons | Seeds
Epicotyl dormancy | Seed dormancy | Embryo growth | Germination | Shoot emergence | epicotyl dormancy | SIZE | HYBRIDIZATION | MATURATION | EMERGENCE | ECOPHYSIOLOGY | PLANT SCIENCES | germination | seed dormancy | TEMPERATURE | shoot emergence | ADAPTATION | AMARYLLIDACEAE | MORPHOPHYSIOLOGICAL DORMANCY | Biological Evolution | Crocus - physiology | Plant Dormancy - physiology | Seeds - physiology | Species Specificity | Germination - physiology | Crocus - genetics | Seasons | Seeds
Journal Article
The Plant Cell, ISSN 1040-4651, 6/2011, Volume 23, Issue 6, pp. 2196 - 2208
After-ripening is the mechanism by which dormant seeds become nondormant during their dry storage after harvest. The absence of free water in mature seeds does...
Dormancy | Seed dormancy | After ripening | Messenger RNA | RNA | Gels | Germination | Genes | Oxidation | Embryos | VITAMIN-E | PROTEIN | ACID | PHOSPHATASE | BIOCHEMISTRY & MOLECULAR BIOLOGY | TRANSCRIPTION | GERMINATION | PLANT SCIENCES | CELL BIOLOGY | SIGNAL-TRANSDUCTION | GENE-EXPRESSION | ARABIDOPSIS CVI | STRESS GRANULES | Protein Biosynthesis | Oxidation-Reduction | Plant Dormancy - physiology | Transcriptome | Molecular Sequence Data | Gene Expression Profiling | RNA, Messenger - metabolism | Polymorphism, Genetic | Helianthus - physiology | Plant Proteins - genetics | Animals | Helianthus - anatomy & histology | Polymorphism, Restriction Fragment Length | Seeds - physiology | Microarray Analysis | Germination - physiology | Deoxyguanosine - metabolism | RNA, Messenger - chemistry | Signal Transduction - physiology | Plant Proteins - metabolism | Deoxyguanosine - analogs & derivatives | Ripening | Crops | Physiological aspects | Oxidation-reduction reaction | Genetic aspects | Research | Sunflowers
Dormancy | Seed dormancy | After ripening | Messenger RNA | RNA | Gels | Germination | Genes | Oxidation | Embryos | VITAMIN-E | PROTEIN | ACID | PHOSPHATASE | BIOCHEMISTRY & MOLECULAR BIOLOGY | TRANSCRIPTION | GERMINATION | PLANT SCIENCES | CELL BIOLOGY | SIGNAL-TRANSDUCTION | GENE-EXPRESSION | ARABIDOPSIS CVI | STRESS GRANULES | Protein Biosynthesis | Oxidation-Reduction | Plant Dormancy - physiology | Transcriptome | Molecular Sequence Data | Gene Expression Profiling | RNA, Messenger - metabolism | Polymorphism, Genetic | Helianthus - physiology | Plant Proteins - genetics | Animals | Helianthus - anatomy & histology | Polymorphism, Restriction Fragment Length | Seeds - physiology | Microarray Analysis | Germination - physiology | Deoxyguanosine - metabolism | RNA, Messenger - chemistry | Signal Transduction - physiology | Plant Proteins - metabolism | Deoxyguanosine - analogs & derivatives | Ripening | Crops | Physiological aspects | Oxidation-reduction reaction | Genetic aspects | Research | Sunflowers
Journal Article
JOURNAL OF EXPERIMENTAL BOTANY, ISSN 0022-0957, 02/2017, Volume 68, Issue 4, pp. 857 - 869
Primary seed dormancy is an important adaptive plant trait whereby seed germination is blocked under conditions that would otherwise be favorable for...
ABA | ARABIDOPSIS-THALIANA | seed | Arabidopsis | SECONDARY DORMANCY | NATURAL ALLELIC VARIATION | ABSCISIC-ACID BIOSYNTHESIS | PROTEIN PHOSPHATASE 2C | endosperm | LOW-TEMPERATURE | PLANT SCIENCES | germination | dormancy | GENE-EXPRESSION | NITRIC-OXIDE | FLOWERING TIME | Arabidopsis - physiology | Plant Dormancy - physiology | Seeds - growth & development | Seeds - physiology | Arabidopsis - growth & development | Gene Expression Regulation, Plant - physiology | Plant Growth Regulators - physiology | Abscisic Acid - physiology | Plant Physiological Phenomena | Endosperm - physiology | Dormancy | Endosperm | Germination | Seed
ABA | ARABIDOPSIS-THALIANA | seed | Arabidopsis | SECONDARY DORMANCY | NATURAL ALLELIC VARIATION | ABSCISIC-ACID BIOSYNTHESIS | PROTEIN PHOSPHATASE 2C | endosperm | LOW-TEMPERATURE | PLANT SCIENCES | germination | dormancy | GENE-EXPRESSION | NITRIC-OXIDE | FLOWERING TIME | Arabidopsis - physiology | Plant Dormancy - physiology | Seeds - growth & development | Seeds - physiology | Arabidopsis - growth & development | Gene Expression Regulation, Plant - physiology | Plant Growth Regulators - physiology | Abscisic Acid - physiology | Plant Physiological Phenomena | Endosperm - physiology | Dormancy | Endosperm | Germination | Seed
Journal Article
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Full Text
Effects of environmental variation during seed production on seed dormancy and germination
Journal of Experimental Botany, ISSN 0022-0957, 02/2017, Volume 68, Issue 4, pp. 819 - 825
The environment during seed production has major impacts on the behaviour of progeny seeds. It can be shown that for annual plants temperature perception over...
Maternal | Seed dormancy | Temperature | Tannin | Seed development | Environment | FLC | Flowering time | Seed coat | Seed germination | PATHWAYS | ARABIDOPSIS-THALIANA | MATURATION ENVIRONMENT | LIGHT | DESERT | seed germination | seed coat | tannin | PLANT SCIENCES | seed dormancy | flowering time | seed development | temperature | PLANTS | FLOWERING-LOCUS-C | ABSCISIC-ACID | EXPRESSION | maternal | Arabidopsis - physiology | Plant Dormancy - physiology | Arabidopsis - growth & development | Plant Growth Regulators - physiology | Fruit - physiology | Flowers - growth & development | Fruit - growth & development | Seeds - growth & development | Seeds - physiology | Germination - physiology | Flowers - physiology | Seeds - anatomy & histology
Maternal | Seed dormancy | Temperature | Tannin | Seed development | Environment | FLC | Flowering time | Seed coat | Seed germination | PATHWAYS | ARABIDOPSIS-THALIANA | MATURATION ENVIRONMENT | LIGHT | DESERT | seed germination | seed coat | tannin | PLANT SCIENCES | seed dormancy | flowering time | seed development | temperature | PLANTS | FLOWERING-LOCUS-C | ABSCISIC-ACID | EXPRESSION | maternal | Arabidopsis - physiology | Plant Dormancy - physiology | Arabidopsis - growth & development | Plant Growth Regulators - physiology | Fruit - physiology | Flowers - growth & development | Fruit - growth & development | Seeds - growth & development | Seeds - physiology | Germination - physiology | Flowers - physiology | Seeds - anatomy & histology
Journal Article
The Plant Cell, ISSN 1040-4651, 1/2013, Volume 25, Issue 1, pp. 149 - 166
Histone (de)acetylation is a highly conserved chromatin modification that is vital for development and growth. In this study, we identified a role in seed...
Dormancy | Seed dormancy | RESEARCH ARTICLES | Genes | Germination | Histones | Gene expression regulation | Acetylation | Plants | Plant cells | Seed germination | LATE EMBRYO DEVELOPMENT | DNA METHYLATION | BIOCHEMISTRY & MOLECULAR BIOLOGY | PLANT-CELLS | BIMOLECULAR FLUORESCENCE COMPLEMENTATION | GERMINATION | PLANT SCIENCES | CELL BIOLOGY | TRANSCRIPTIONAL COREPRESSOR | GENE-EXPRESSION | GENOME-WIDE | H2B MONOUBIQUITINATION | FLOWERING TIME | Arabidopsis - physiology | Plant Dormancy - physiology | Transcriptome | Ethylenes - analysis | Seedlings - genetics | Ethylenes - metabolism | Arabidopsis Proteins - metabolism | Chromatin Immunoprecipitation | Plants, Genetically Modified | Gene Expression Regulation, Plant | Disulfides - pharmacology | Abscisic Acid - metabolism | Seeds - cytology | Hydroxamic Acids - pharmacology | Plant Growth Regulators - analysis | Repressor Proteins - metabolism | Arabidopsis Proteins - genetics | Arabidopsis - drug effects | Abscisic Acid - analysis | Signal Transduction | Seedlings - cytology | Seeds - drug effects | Seeds - genetics | Arabidopsis - cytology | Models, Molecular | Repressor Proteins - genetics | Histone Deacetylases | Seedlings - drug effects | Allyl Compounds - pharmacology | Arabidopsis - genetics | Two-Hybrid System Techniques | Phenotype | Histones - genetics | Sequence Analysis, RNA | Seedlings - physiology | Seeds - physiology | Mutagenesis, Insertional | Histones - metabolism | Plant Growth Regulators - metabolism | Arabidopsis Proteins - antagonists & inhibitors | Arabidopsis thaliana | Seeds | Physiological aspects | Dormancy (Biology) | Genetic aspects | Research | Properties | Genetic regulation | Gene expression | Antibiosis
Dormancy | Seed dormancy | RESEARCH ARTICLES | Genes | Germination | Histones | Gene expression regulation | Acetylation | Plants | Plant cells | Seed germination | LATE EMBRYO DEVELOPMENT | DNA METHYLATION | BIOCHEMISTRY & MOLECULAR BIOLOGY | PLANT-CELLS | BIMOLECULAR FLUORESCENCE COMPLEMENTATION | GERMINATION | PLANT SCIENCES | CELL BIOLOGY | TRANSCRIPTIONAL COREPRESSOR | GENE-EXPRESSION | GENOME-WIDE | H2B MONOUBIQUITINATION | FLOWERING TIME | Arabidopsis - physiology | Plant Dormancy - physiology | Transcriptome | Ethylenes - analysis | Seedlings - genetics | Ethylenes - metabolism | Arabidopsis Proteins - metabolism | Chromatin Immunoprecipitation | Plants, Genetically Modified | Gene Expression Regulation, Plant | Disulfides - pharmacology | Abscisic Acid - metabolism | Seeds - cytology | Hydroxamic Acids - pharmacology | Plant Growth Regulators - analysis | Repressor Proteins - metabolism | Arabidopsis Proteins - genetics | Arabidopsis - drug effects | Abscisic Acid - analysis | Signal Transduction | Seedlings - cytology | Seeds - drug effects | Seeds - genetics | Arabidopsis - cytology | Models, Molecular | Repressor Proteins - genetics | Histone Deacetylases | Seedlings - drug effects | Allyl Compounds - pharmacology | Arabidopsis - genetics | Two-Hybrid System Techniques | Phenotype | Histones - genetics | Sequence Analysis, RNA | Seedlings - physiology | Seeds - physiology | Mutagenesis, Insertional | Histones - metabolism | Plant Growth Regulators - metabolism | Arabidopsis Proteins - antagonists & inhibitors | Arabidopsis thaliana | Seeds | Physiological aspects | Dormancy (Biology) | Genetic aspects | Research | Properties | Genetic regulation | Gene expression | Antibiosis
Journal Article