Compounds > 2,2-bis(bromomethyl)-1,3-propanediol
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2,2-bis(bromomethyl)-1,3-propanediol and cyclopentane

2,2-bis(bromomethyl)-1,3-propanediol has been researched along with cyclopentane in 12 studies

Research

Studies (12)

TimeframeStudies, this research(%)All Research%
pre-19900 (0.00)18.7374
1990's2 (16.67)18.2507
2000's2 (16.67)29.6817
2010's8 (66.67)24.3611
2020's0 (0.00)2.80

Authors

AuthorsStudies
Klausner, RD; Shah, N1
Emr, SD; Gaynor, EC1
Gupta, M; Krischke, M; Loeffler, C; Mueller, MJ; Roitsch, T; Sinha, AK; Steffan, B; Thoma, I1
Délano-Frier, JP; Martínez de la Vega, O; Tejeda-Sartorius, M1
Abdelmohsen, UR; Engelke, T; Griebel, T; Grosskinsky, DK; Naseem, M; Novák, O; Pfeifhofer, H; Plickert, N; Roitsch, T; Simon, U; Strnad, M; van der Graaff, E; Zeier, J1
Arnaut, HA; Castrillón-Arbeláez, PA; Délano-Frier, JP; Martínez-Gallardo, N; Tiessen, A1
Agtuca, B; Appel, HM; Ferrieri, AP; Ferrieri, RA; Schultz, JC1
Heil, M; Millán-Cañongo, C; Orona-Tamayo, D1
Arce, CCM; Baldwin, IT; Erb, M; Ferrieri, AP; Machado, RAR1
Arce, CC; Baldwin, IT; Erb, M; Ferrieri, AP; Lima, E; Machado, RA; Meza-Canales, ID1
Ruan, YL; Wang, L1
Cheng, T; Dai, CC; Song, SL; Sun, K; Tang, MJ; Xu, FJ; Yuan, J; Zhang, W1

Other Studies

12 other study(ies) available for 2,2-bis(bromomethyl)-1,3-propanediol and cyclopentane

ArticleYear
Brefeldin A reversibly inhibits secretion in Saccharomyces cerevisiae.
    The Journal of biological chemistry, 1993, Mar-15, Volume: 268, Issue:8

    Topics: Antifungal Agents; beta-Fructofuranosidase; Brefeldin A; Cyclopentanes; Electrophoresis, Polyacrylamide Gel; Glycoside Hydrolases; Microbial Sensitivity Tests; Precipitin Tests; Saccharomyces cerevisiae

1993
COPI-independent anterograde transport: cargo-selective ER to Golgi protein transport in yeast COPI mutants.
    The Journal of cell biology, 1997, Feb-24, Volume: 136, Issue:4

    Topics: Alleles; beta-Fructofuranosidase; Biological Transport; Brefeldin A; Carboxypeptidases; Cathepsin A; Coated Vesicles; Cyclopentanes; Endoplasmic Reticulum; Glycoproteins; Glycoside Hydrolases; Glycosylation; Golgi Apparatus; Heat-Shock Proteins; Mutation; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins; Temperature

1997
Cyclopentenone isoprostanes induced by reactive oxygen species trigger defense gene activation and phytoalexin accumulation in plants.
    The Plant journal : for cell and molecular biology, 2003, Volume: 34, Issue:3

    Topics: Arabidopsis; beta-Fructofuranosidase; Botrytis; Cells, Cultured; Cyclopentanes; Enzyme Activation; Enzyme Induction; Gene Expression Regulation, Plant; Glutathione Transferase; Glycoside Hydrolases; Immunity, Innate; Isoprostanes; Mitogen-Activated Protein Kinases; Molecular Structure; Nicotiana; Oxylipins; Peroxides; Phenylalanine Ammonia-Lyase; Phytoalexins; Plant Extracts; Plants; Reactive Oxygen Species; Scopoletin; Sesquiterpenes; Solanum lycopersicum; Terpenes; Transcriptional Activation

2003
Jasmonic acid influences mycorrhizal colonization in tomato plants by modifying the expression of genes involved in carbohydrate partitioning.
    Physiologia plantarum, 2008, Volume: 133, Issue:2

    Topics: Acetates; beta-Fructofuranosidase; Carbohydrate Metabolism; Cell Wall; Cyclopentanes; Fatty Acids; Gene Expression Regulation, Plant; Genes, Plant; Glucosyltransferases; Mycorrhizae; Oxylipins; Plant Proteins; Plant Roots; Solanum lycopersicum; Starch; Sucrose

2008
Cytokinins mediate resistance against Pseudomonas syringae in tobacco through increased antimicrobial phytoalexin synthesis independent of salicylic acid signaling.
    Plant physiology, 2011, Volume: 157, Issue:2

    Topics: Anti-Infective Agents; beta-Fructofuranosidase; Cyclopentanes; Cytokinins; Disease Resistance; Host-Pathogen Interactions; Nicotiana; Oxylipins; Phytoalexins; Plant Diseases; Plant Immunity; Plant Leaves; Plants, Genetically Modified; Pseudomonas syringae; Salicylic Acid; Scopoletin; Sesquiterpenes

2011
Metabolic and enzymatic changes associated with carbon mobilization, utilization and replenishment triggered in grain amaranth (Amaranthus cruentus) in response to partial defoliation by mechanical injury or insect herbivory.
    BMC plant biology, 2012, Sep-12, Volume: 12

    Topics: Amaranthus; Amino Acid Sequence; Animals; beta-Fructofuranosidase; Carbohydrate Metabolism; Carbon; Cloning, Molecular; Cyclopentanes; Fructose; Gene Expression Regulation, Plant; Genes, Plant; Glucose; Glucosyltransferases; Herbivory; Insecta; Molecular Sequence Data; Oxylipins; Plant Leaves; Plant Proteins; Plant Roots; Plant Stems; RNA, Messenger; Seeds; Starch; Stress, Mechanical; Sucrose

2012
Temporal changes in allocation and partitioning of new carbon as (11)C elicited by simulated herbivory suggest that roots shape aboveground responses in Arabidopsis.
    Plant physiology, 2013, Volume: 161, Issue:2

    Topics: Acetates; Animals; Anthocyanins; Arabidopsis; beta-Fructofuranosidase; Biological Transport; Carbon Dioxide; Carbon Radioisotopes; Cinnamates; Cyclopentanes; Herbivory; Host-Parasite Interactions; Membrane Transport Proteins; Mutation; Oxylipins; Phenol; Phloem; Photosynthesis; Plant Growth Regulators; Plant Leaves; Plant Proteins; Plant Roots; Time Factors

2013
Phloem sugar flux and jasmonic acid-responsive cell wall invertase control extrafloral nectar secretion in Ricinus communis.
    Journal of chemical ecology, 2014, Volume: 40, Issue:7

    Topics: beta-Fructofuranosidase; Carbohydrate Metabolism; Cell Wall; Cyclopentanes; Light; Oxylipins; Phloem; Plant Leaves; Plant Nectar; Ricinus; Time Factors

2014
Jasmonate-dependent depletion of soluble sugars compromises plant resistance to Manduca sexta.
    The New phytologist, 2015, Volume: 207, Issue:1

    Topics: Animals; beta-Fructofuranosidase; Carbohydrates; Circadian Rhythm; Cyclopentanes; Disease Resistance; Fructose; Genotype; Glucose; Herbivory; Manduca; Nicotiana; Oxylipins; Plant Diseases; Plant Leaves; Plant Proteins; Plants, Genetically Modified; Ribulose-Bisphosphate Carboxylase; Secondary Metabolism; Signal Transduction; Solubility; Weight Gain

2015
A Nicotiana attenuata cell wall invertase inhibitor (NaCWII) reduces growth and increases secondary metabolite biosynthesis in herbivore-attacked plants.
    The New phytologist, 2015, Volume: 208, Issue:2

    Topics: Amino Acid Sequence; Animals; beta-Fructofuranosidase; Carbohydrate Metabolism; Cell Wall; Cloning, Molecular; Cyclopentanes; DNA, Complementary; Gene Silencing; Herbivory; Larva; Manduca; Molecular Sequence Data; Nicotiana; Oxylipins; Plant Growth Regulators; Plant Proteins; Secondary Metabolism; Up-Regulation

2015
Critical Roles of Vacuolar Invertase in Floral Organ Development and Male and Female Fertilities Are Revealed through Characterization of GhVIN1-RNAi Cotton Plants.
    Plant physiology, 2016, Volume: 171, Issue:1

    Topics: beta-Fructofuranosidase; Cyclopentanes; Flowers; Gene Expression Regulation, Plant; Gossypium; Indoleacetic Acids; Oxylipins; Plant Infertility; Plant Proteins; Plants, Genetically Modified; Pollen; RNA Interference; Seeds; Signal Transduction; Starch; Trehalose; Vacuoles

2016
Flowering-mediated root-fungus symbiosis loss is related to jasmonate-dependent root soluble sugar deprivation.
    Plant, cell & environment, 2019, Volume: 42, Issue:12

    Topics: Arabidopsis; Ascomycota; beta-Fructofuranosidase; Biological Transport; Circadian Rhythm; Cyclopentanes; Flowers; Fructose; Glucose; Oxylipins; Phloem; Plant Roots; Signal Transduction; Solubility; Sugars; Symbiosis

2019