Nature Communications, ISSN 2041-1723, 2014, Volume 5, Issue 1, p. 4983
Legumes establish symbiotic associations with nitrogen-fixing bacteria (rhizobia) in root nodules to obtain nitrogen. Legumes control nodule number through...
MEDIUM-POLARITY FRACTION | WILD-TYPE | LOTUS-JAPONICUS | ARABIDOPSIS ABCG14 | PLANT TRANSFORMATION | MULTIDISCIPLINARY SCIENCES | RECEPTOR-LIKE KINASE | RESTRICTING SUBSTANCES | LONG-DISTANCE CONTROL | SOYBEAN PLANTS | NODULE ORGANOGENESIS | Promoter Regions, Genetic | Plant Roots - metabolism | Peptides - chemistry | Molecular Sequence Data | Gene Expression Profiling | Rhizobium - metabolism | Phenotype | Biological Transport | Plant Root Nodulation | Plant Shoots - metabolism | Gene Expression Regulation, Plant | Ligands | Cytokinins - metabolism | Plant Growth Regulators - metabolism | Fabaceae - physiology | Loteae - physiology
MEDIUM-POLARITY FRACTION | WILD-TYPE | LOTUS-JAPONICUS | ARABIDOPSIS ABCG14 | PLANT TRANSFORMATION | MULTIDISCIPLINARY SCIENCES | RECEPTOR-LIKE KINASE | RESTRICTING SUBSTANCES | LONG-DISTANCE CONTROL | SOYBEAN PLANTS | NODULE ORGANOGENESIS | Promoter Regions, Genetic | Plant Roots - metabolism | Peptides - chemistry | Molecular Sequence Data | Gene Expression Profiling | Rhizobium - metabolism | Phenotype | Biological Transport | Plant Root Nodulation | Plant Shoots - metabolism | Gene Expression Regulation, Plant | Ligands | Cytokinins - metabolism | Plant Growth Regulators - metabolism | Fabaceae - physiology | Loteae - physiology
Journal Article
The Plant Journal, ISSN 0960-7412, 10/2015, Volume 84, Issue 1, pp. 1 - 19
Summary Next‐generation sequencing technologies allow an almost exhaustive survey of the transcriptome, even in species with no available genome sequence. To...
nitrogen symbiotic fixation | Pisum sativum L | de novo assembly | gene expression atlas | next‐generation sequencing | nodule development | next-generation sequencing | PLANT | RECEPTOR KINASE GENE | IN-SILICO | LEGUME MEDICAGO-TRUNCATULA | TRANSCRIPTOME ANALYSIS | DISCOVERY | PLANT SCIENCES | LOTUS-JAPONICUS | DRAFT GENOME SEQUENCE | SYMBIOSIS | Plant Root Nodulation - genetics | Peas - growth & development | Gene Expression Regulation, Plant | Plant Roots - genetics | High-Throughput Nucleotide Sequencing | RNA, Plant - genetics | Peas - genetics | Plant Roots - growth & development | Peas | RNA | Analysis | Genes | Genomics | Genetic research | Gene expression | Legumes | Ribonucleic acid--RNA
nitrogen symbiotic fixation | Pisum sativum L | de novo assembly | gene expression atlas | next‐generation sequencing | nodule development | next-generation sequencing | PLANT | RECEPTOR KINASE GENE | IN-SILICO | LEGUME MEDICAGO-TRUNCATULA | TRANSCRIPTOME ANALYSIS | DISCOVERY | PLANT SCIENCES | LOTUS-JAPONICUS | DRAFT GENOME SEQUENCE | SYMBIOSIS | Plant Root Nodulation - genetics | Peas - growth & development | Gene Expression Regulation, Plant | Plant Roots - genetics | High-Throughput Nucleotide Sequencing | RNA, Plant - genetics | Peas - genetics | Plant Roots - growth & development | Peas | RNA | Analysis | Genes | Genomics | Genetic research | Gene expression | Legumes | Ribonucleic acid--RNA
Journal Article
Cell Host & Microbe, ISSN 1931-3128, 2011, Volume 10, Issue 4, pp. 348 - 358
Legume plants have an exceptional capacity for association with microorganisms, ranging from largely nonspecific to very specific interactions....
NODULE DEVELOPMENT | MESORHIZOBIUM-LOTI | ARABIDOPSIS-ROOT | F-BOX PROTEINS | MICROBIOLOGY | TRANSGENIC LOTUS-JAPONICUS | CELL-DIVISION | VIROLOGY | MEDICAGO-TRUNCATULA | RECEPTOR-LIKE KINASES | GENE-EXPRESSION | ARBUSCULAR MYCORRHIZA FUNGI | PARASITOLOGY | Plant Roots - physiology | Symbiosis | Bacteria - growth & development | Bacteria - metabolism | Indoleacetic Acids - metabolism | Plant Root Nodulation | Cytokinins - metabolism | Plant Roots - microbiology | Fabaceae - physiology | Ethylenes - metabolism | Fabaceae - microbiology | Plant hormones
NODULE DEVELOPMENT | MESORHIZOBIUM-LOTI | ARABIDOPSIS-ROOT | F-BOX PROTEINS | MICROBIOLOGY | TRANSGENIC LOTUS-JAPONICUS | CELL-DIVISION | VIROLOGY | MEDICAGO-TRUNCATULA | RECEPTOR-LIKE KINASES | GENE-EXPRESSION | ARBUSCULAR MYCORRHIZA FUNGI | PARASITOLOGY | Plant Roots - physiology | Symbiosis | Bacteria - growth & development | Bacteria - metabolism | Indoleacetic Acids - metabolism | Plant Root Nodulation | Cytokinins - metabolism | Plant Roots - microbiology | Fabaceae - physiology | Ethylenes - metabolism | Fabaceae - microbiology | Plant hormones
Journal Article
Journal of Experimental Botany, ISSN 0022-0957, 04/2018, Volume 69, Issue 8, pp. 1829 - 1836
CEP peptide hormones have key roles in nitrogen-demand signalling, root nodulation, and lateral root development. We highlight recent advances in our...
signalling peptide | nitrogen | proteolytic processing | nodulation | mobile signals | post-translational modification | root system architecture | CEP | PATHWAYS | NODULE NUMBERS | REGULATE ROOT | CLE PEPTIDES | IDENTIFICATION | PLANT SCIENCES | MEDICAGO | GROWTH | GENES | MERISTEM | ARABIDOPSIS
signalling peptide | nitrogen | proteolytic processing | nodulation | mobile signals | post-translational modification | root system architecture | CEP | PATHWAYS | NODULE NUMBERS | REGULATE ROOT | CLE PEPTIDES | IDENTIFICATION | PLANT SCIENCES | MEDICAGO | GROWTH | GENES | MERISTEM | ARABIDOPSIS
Journal Article
Current Opinion in Plant Biology, ISSN 1369-5266, 10/2014, Volume 21, pp. 16 - 22
Root nodulation is a unique developmental process that predominantly occurs in leguminous plants. In this process, signaling initiated by symbiotic bacterial...
LOTUS-JAPONICUS | LATERAL ROOT | NODULE DEVELOPMENT | RHIZOBIAL INFECTION | FUNGAL | GENE-EXPRESSION | DEPENDENT PROTEIN-KINASE | CALCIUM SPIKING | CYTOKININ | GRAS FAMILY | PLANT SCIENCES | Plant Root Nodulation - physiology | Gene Expression Regulation, Plant - physiology | Plant Growth Regulators - physiology | Root Nodules, Plant - microbiology | Symbiosis - physiology | Cytokinins - physiology | Plant Roots - microbiology | Rhizobium - physiology | Plant Roots - growth & development | Root Nodules, Plant - physiology | Health aspects | Bacterial infections | Cytokinins | Developmental biology
LOTUS-JAPONICUS | LATERAL ROOT | NODULE DEVELOPMENT | RHIZOBIAL INFECTION | FUNGAL | GENE-EXPRESSION | DEPENDENT PROTEIN-KINASE | CALCIUM SPIKING | CYTOKININ | GRAS FAMILY | PLANT SCIENCES | Plant Root Nodulation - physiology | Gene Expression Regulation, Plant - physiology | Plant Growth Regulators - physiology | Root Nodules, Plant - microbiology | Symbiosis - physiology | Cytokinins - physiology | Plant Roots - microbiology | Rhizobium - physiology | Plant Roots - growth & development | Root Nodules, Plant - physiology | Health aspects | Bacterial infections | Cytokinins | Developmental biology
Journal Article
Physiologia Plantarum, ISSN 0031-9317, 07/2018, Volume 163, Issue 3, pp. 372 - 385
Magnesium (Mg) is an essential element for the growth of both plants and bacteria. Low availability of Mg in agriculture can limit crop productivity and...
LEAF SENESCENCE | LOTUS-JAPONICUS | ENHANCED SUCROSE SYNTHASE | N-2 FIXATION | MEDICAGO-TRUNCATULA | CRYSTAL-STRUCTURE | NODULE FORMATION | ALUMINUM TOXICITY | PHASEOLUS-VULGARIS | BIOLOGICAL NITROGEN-FIXATION | PLANT SCIENCES | Physiological aspects | Bacteria | Soybean | Nitrogen | Nitrogenation | Legumes | Carbohydrates | Soybeans | Sucrose | Starch | Crop production | Homeostasis | Nodulation | Nodules | Leaves | Fixation | Plant growth | Magnesium | Sugars | Enlargement
LEAF SENESCENCE | LOTUS-JAPONICUS | ENHANCED SUCROSE SYNTHASE | N-2 FIXATION | MEDICAGO-TRUNCATULA | CRYSTAL-STRUCTURE | NODULE FORMATION | ALUMINUM TOXICITY | PHASEOLUS-VULGARIS | BIOLOGICAL NITROGEN-FIXATION | PLANT SCIENCES | Physiological aspects | Bacteria | Soybean | Nitrogen | Nitrogenation | Legumes | Carbohydrates | Soybeans | Sucrose | Starch | Crop production | Homeostasis | Nodulation | Nodules | Leaves | Fixation | Plant growth | Magnesium | Sugars | Enlargement
Journal Article
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Full Text
Effects of bamboo biochar on soybean root nodulation in multi-elements contaminated soils
Ecotoxicology and Environmental Safety, ISSN 0147-6513, 04/2018, Volume 150, pp. 62 - 69
Improvements in plant physiological performance by means of biochar application in soils contaminated by multi-elements are determinants of agroecosystem...
Immobilization | Nodulation | Trace elements | Soybean | Bamboo biochar | Soil contamination | YIELD | RETENTION | MECHANISMS | BIOAVAILABILITY | BIOLOGICAL NITROGEN-FIXATION | ENVIRONMENTAL SCIENCES | MANURE | AVAILABILITY | TOXICOLOGY | PLANT-GROWTH | LEAD | AMENDMENTS | Plant Root Nodulation - drug effects | Trace Elements - analysis | Adsorption | Soybeans - drug effects | Soil - chemistry | Soybeans - physiology | Biological Availability | Biomass | Charcoal - chemistry | Sasa | Soil Pollutants - analysis | Index Medicus
Immobilization | Nodulation | Trace elements | Soybean | Bamboo biochar | Soil contamination | YIELD | RETENTION | MECHANISMS | BIOAVAILABILITY | BIOLOGICAL NITROGEN-FIXATION | ENVIRONMENTAL SCIENCES | MANURE | AVAILABILITY | TOXICOLOGY | PLANT-GROWTH | LEAD | AMENDMENTS | Plant Root Nodulation - drug effects | Trace Elements - analysis | Adsorption | Soybeans - drug effects | Soil - chemistry | Soybeans - physiology | Biological Availability | Biomass | Charcoal - chemistry | Sasa | Soil Pollutants - analysis | Index Medicus
Journal Article
Annual Reviews in Microbiology, ISSN 0066-4227, 10/2000, Volume 54, Issue 1, pp. 257 - 288
Rhizobia are soil bacteria that can engage in a symbiosis with leguminous plants that produces nitrogen-fixing root nodules. This symbiosis is based on...
plant-microbe interactions | host specificity | Nod factors | carbohydrate signal molecules | glycobiology | Plant-microbe interactions | Glycobiology | Carbohydrate signal molecules | Host specificity | LIPO-CHITIN OLIGOSACCHARIDES | SINORHIZOBIUM-MELILOTI | HOST-RANGE | MICROBIOLOGY | AZORHIZOBIAL NOD FACTORS | LEGUMINOSARUM BIOVAR PHASEOLI | FATTY-ACIDS | BRADYRHIZOBIUM-JAPONICUM BACTEROIDS | LIPOCHITIN OLIGOSACCHARIDES | SP. STRAIN NGR234 | MOLECULAR-WEIGHT SUCCINOGLYCAN | Carbohydrate Sequence | Symbiosis | Polysaccharides, Bacterial | Species Specificity | Cell Communication | Molecular Sequence Data | Plant Roots - microbiology | Rhizobiaceae - physiology | Plants, Medicinal | Fabaceae - microbiology | Carbohydrates | Plant-pathogen relationships | Analysis | Plant parasites | Rhizobium | Research | Bacteria | Lipids | Flowers & plants | Microbiology
plant-microbe interactions | host specificity | Nod factors | carbohydrate signal molecules | glycobiology | Plant-microbe interactions | Glycobiology | Carbohydrate signal molecules | Host specificity | LIPO-CHITIN OLIGOSACCHARIDES | SINORHIZOBIUM-MELILOTI | HOST-RANGE | MICROBIOLOGY | AZORHIZOBIAL NOD FACTORS | LEGUMINOSARUM BIOVAR PHASEOLI | FATTY-ACIDS | BRADYRHIZOBIUM-JAPONICUM BACTEROIDS | LIPOCHITIN OLIGOSACCHARIDES | SP. STRAIN NGR234 | MOLECULAR-WEIGHT SUCCINOGLYCAN | Carbohydrate Sequence | Symbiosis | Polysaccharides, Bacterial | Species Specificity | Cell Communication | Molecular Sequence Data | Plant Roots - microbiology | Rhizobiaceae - physiology | Plants, Medicinal | Fabaceae - microbiology | Carbohydrates | Plant-pathogen relationships | Analysis | Plant parasites | Rhizobium | Research | Bacteria | Lipids | Flowers & plants | Microbiology
Journal Article