Acclimation to soil flooding - sensing and signal-transduction
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[1] R. Sederoff,et al. Microarray Analyses of Gene Expression during Adventitious Root Development in Pinus contorta1[w] , 2004, Plant Physiology.
[2] P. Benfey,et al. Editorial overviewGrowth and development: Something old, something new…. , 2004 .
[3] J. Ecker,et al. The ethylene signaling pathway: new insights. , 2004, Current opinion in plant biology.
[4] T. V. Bragina,et al. Ethylene Production and Activation of Hydrolytic Enzymes during Acclimation of Maize Seedlings to Partial Flooding , 2003, Russian Journal of Plant Physiology.
[5] H. Greenway,et al. Review: Mechanisms of anoxia tolerance in plants. II. Energy requirements for maintenance and energy distribution to essential processes. , 2003, Functional plant biology : FPB.
[6] D. Evans,et al. Aerenchyma formation: Tansley review , 2003 .
[7] H. Lambers,et al. Aerenchyma formation and radial O2 loss along adventitious roots of wheat with only the apical root portion exposed to O2 deficiency , 2003 .
[8] D. Luu,et al. Cytosolic pH regulates root water transport during anoxic stress through gating of aquaporins , 2003, Nature.
[9] J. Kieber,et al. Localization of the Raf-like Kinase CTR1 to the Endoplasmic Reticulum of Arabidopsis through Participation in Ethylene Receptor Signaling Complexes* , 2003, Journal of Biological Chemistry.
[10] M. P. McDonald,et al. A Study of the Interaction between Auxin and Ethylene in Wild Type and Transgenic Ethylene‐Insensitive Tobacco during Adventitious Root Formation Induced by Stagnant Root Zone Conditions , 2003 .
[11] J. Tumlinson,et al. Nitrogen Deficiency Increases Volicitin-Induced Volatile Emission, Jasmonic Acid Accumulation, and Ethylene Sensitivity in Maize1 , 2003, Plant Physiology.
[12] T. Colmer,et al. Diversity in root aeration traits associated with waterlogging tolerance in the genus Hordeum. , 2003, Functional plant biology : FPB.
[13] G. Boru,et al. Oxygen use from solution by wheat genotypes differing in tolerance to waterlogging , 2003, Euphytica.
[14] J. Lynch,et al. Physiological roles for aerenchyma in phosphorus-stressed roots. , 2003, Functional plant biology : FPB.
[15] P. Geigenberger,et al. Response of plant metabolism to too little oxygen. , 2003, Current opinion in plant biology.
[16] E. Woltering,et al. A tomato metacaspase gene is upregulated during programmed cell death in Botrytis cinerea-infected leaves , 2003, Planta.
[17] M. Hawkesford,et al. Aerenchyma formation in roots of maize during sulphate starvation , 2003, Planta.
[18] T. Baskin,et al. Regulation of Root Elongation under Phosphorus Stress Involves Changes in Ethylene Responsiveness1 , 2003, Plant Physiology.
[19] H. Greenway,et al. Review: Mechanisms of anoxia tolerance in plants. I. Growth, survival and anaerobic catabolism. , 2003, Functional plant biology : FPB.
[20] M. Sachs,et al. Molecular and cellular adaptations of maize to flooding stress. , 2003, Annals of botany.
[21] L. Voesenek,et al. Flooding and Plant Growth , 2003 .
[22] C. Dordas,et al. Plant haemoglobins, nitric oxide and hypoxic stress. , 2003, Annals of botany.
[23] R. Brouquisse,et al. Assessment of enzyme induction and aerenchyma formation as mechanisms for flooding tolerance in Trifolium subterraneum 'Park'. , 2003, Annals of botany.
[24] P. Hunt,et al. Increased level of hemoglobin 1 enhances survival of hypoxic stress and promotes early growth in Arabidopsis thaliana , 2002, Proceedings of the National Academy of Sciences of the United States of America.
[25] E. Woltering,et al. Do Plant Caspases Exist? , 2002, Plant Physiology.
[26] S. Chapman,et al. Expression Profile Analysis of the Low-Oxygen Response in Arabidopsis Root Cultures Online version contains Web-only data. Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.004747. , 2002, The Plant Cell Online.
[27] S. Davis. Allocation to floral structures in Thalictrum pubescens (Ranunculaceae), a cryptically dioecious species. , 2002, Annals of botany.
[28] P. Springer,et al. RopGAP4-Dependent Rop GTPase Rheostat Control of Arabidopsis Oxygen Deprivation Tolerance , 2002, Science.
[29] G. E. Schaller,et al. Localization of the Ethylene Receptor ETR1 to the Endoplasmic Reticulum of Arabidopsis * , 2002, The Journal of Biological Chemistry.
[30] Huanming Yang,et al. A Draft Sequence of the Rice Genome (Oryza sativa L. ssp. indica) , 2002, Science.
[31] M. Jackson. Long-distance signalling from roots to shoots assessed: the flooding story. , 2002, Journal of experimental botany.
[32] N. Galwey,et al. Evaluation of Lophopyrum elongatum as a source of genetic diversity to increase the waterlogging tolerance of hexaploid wheat (Triticum aestivum) , 2001 .
[33] N. Galwey,et al. Waterlogging tolerance in the tribe Triticeae: the adventitious roots of Critesion marinum have a relatively high porosity and a barrier to radial oxygen loss , 2001 .
[34] W. Schmidt,et al. Different pathways are involved in phosphate and iron stress-induced alterations of root epidermal cell development. , 2001, Plant physiology.
[35] B. Tudzynski. Plant Responses to Environmental Stresses: From Phytohormones to Genome Reorganization , 2001 .
[36] L. Voesenek,et al. Changes in growth, porosity, and radial oxygen loss from adventitious roots of selected mono‐ and dicotyledonous wetland species with contrasting types of aerenchyma , 2000 .
[37] E. Koonin,et al. Identification of paracaspases and metacaspases: two ancient families of caspase-like proteins, one of which plays a key role in MALT lymphoma. , 2000, Molecular cell.
[38] M. Sauter,et al. Ethylene induces epidermal cell death at the site of adventitious root emergence in rice. , 2000, Plant physiology.
[39] M. Drew,et al. Programmed cell death and aerenchyma formation in roots. , 2000, Trends in plant science.
[40] L. Gälweiler,et al. PIN-pointing the molecular basis of auxin transport. , 1999, Current opinion in plant biology.
[41] H. Klee,et al. Root formation in ethylene-insensitive plants. , 1999, Plant physiology.
[42] I. Zhulin,et al. PAS Domains: Internal Sensors of Oxygen, Redox Potential, and Light , 1999, Microbiology and Molecular Biology Reviews.
[43] W. Armstrong,et al. Formation of Aerenchyma and the Processes of Plant Ventilation in Relation to Soil Flooding and Submergence , 1999 .
[44] Kristian Borch,et al. Ethylene: a regulator of root architectural responses to soil phosphorus availability , 1999 .
[45] M. Gilles-Gonzalez,et al. Structure of a biological oxygen sensor: a new mechanism for heme-driven signal transduction. , 1998, Proceedings of the National Academy of Sciences of the United States of America.
[46] J. Ecker,et al. Nuclear events in ethylene signaling: a transcriptional cascade mediated by ETHYLENE-INSENSITIVE3 and ETHYLENE-RESPONSE-FACTOR1. , 1998, Genes & development.
[47] Bush,et al. Mitochondrial contribution to the anoxic Ca2+ signal in maize suspension-cultured cells , 1998, Plant physiology.
[48] R. Hill,et al. Altering hemoglobin levels changes energy status in maize cells under hypoxia. , 1998, Proceedings of the National Academy of Sciences of the United States of America.
[49] J. Gray,et al. Cell-death mechanisms in maize , 1998 .
[50] W. Peacock,et al. Evidence for a role for AtMYB2 in the induction of the Arabidopsis alcohol dehydrogenase gene (ADH1) by low oxygen. , 1998, Genetics.
[51] H. Tomassen,et al. Sulfate-Induced Eutrophication and Phytotoxicity in Freshwater Wetlands , 1998 .
[52] H. Greenway,et al. The Use of Agar Nutrient Solution to Simulate Lack of Convection in Waterlogged Soils , 1997 .
[53] C. Lamb,et al. Programmed Cell Death in Plants. , 1997, The Plant cell.
[54] R. Hill,et al. Mitochondrial Respiration and Hemoglobin Gene Expression in Barley Aleurone Tissue , 1997, Plant physiology.
[55] Malcolm C. Drew,et al. OXYGEN DEFICIENCY AND ROOT METABOLISM: Injury and Acclimation Under Hypoxia and Anoxia. , 1997, Annual review of plant physiology and plant molecular biology.
[56] L. Voesenek,et al. Elongation by primary lateral roots and adventitious roots during conditions of hypoxia and high ethylene concentrations , 1997 .
[57] M. Drew,et al. Ethylene Biosynthesis during Aerenchyma Formation in Roots of Maize Subjected to Mechanical Impedance and Hypoxia , 1996, Plant physiology.
[58] J. Cohen,et al. An Ethylene-Mediated Increase in Sensitivity to Auxin Induces Adventitious Root Formation in Flooded Rumex palustris Sm. , 1996, Plant physiology.
[59] M. Drew,et al. Transduction of an Ethylene Signal Is Required for Cell Death and Lysis in the Root Cortex of Maize during Aerenchyma Formation Induced by Hypoxia , 1996, Plant physiology.
[60] T. Setter,et al. The beneficial effect of reduced elongation growth on submergence tolerance of rice , 1996 .
[61] M. Sachs,et al. A Flooding-Induced Xyloglucan Endo-Transglycosylase Homolog in Maize Is Responsive to Ethylene and Associated with Aerenchyma , 1996, Plant physiology.
[62] R. O. Poyton,et al. Oxygen sensing and molecular adaptation to hypoxia. , 1996, Physiological reviews.
[63] L. Voesenek,et al. Ethylene accumulation in waterlogged Rumex plants promotes formation of adventitious roots , 1996 .
[64] L. Voesenek,et al. Flooding‐induced adventitious rooting in Rumex: morphology and development in an ecological perspective , 1996 .
[65] M. Sachs,et al. Elevation of cytosolic calcium precedes anoxic gene expression in maize suspension-cultured cells. , 1994, The Plant cell.
[66] M. Drew,et al. Induction of Enzymes Associated with Lysigenous Aerenchyma Formation in Roots of Zea mays during Hypoxia or Nitrogen Starvation , 1994, Plant physiology.
[67] M. Oliver,et al. Alteration in gene expression in hypocotyls of sunflower (Helianthus annuus) seedlings associated with derooting and formation of adventitious root primordia , 1994 .
[68] Bingru Huang,et al. Growth, physiological and anatomical responses of two wheat genotypes to waterlogging and nutrient supply , 1994 .
[69] M. Jackson,et al. Polyamine Content and Action in Roots of Zea mays L. in Relation to Aerenchyma Development , 1993 .
[70] C. Blom,et al. Root porosities and radial oxygen losses of Rumex and Plantago species as influenced by soil pore diameter and soil aeration. , 1993, The New phytologist.
[71] E. Meyerowitz,et al. Arabidopsis ethylene-response gene ETR1: similarity of product to two-component regulators. , 1993, Science.
[72] A. A. Hadid. THE RELATIONSHIP BETWEEN ETHYLENE AND AUXIN ON ADVENTITIOUS ROOT INITIATION IN CUTTINGS OF CUCUMBER , 1992 .
[73] D. M. Reid,et al. Adventitious rooting in hypocotyls of sunflower (Helianthus annuus) seedlings. IV. The role of changes in endogenous free and conjugated indole‐3‐acetic acid , 1992 .
[74] W. Armstrong,et al. Evidence for the involvement of ethene in aerenchyma formation in adventitious roots of rice (Oryza sativa L.) , 1991 .
[75] W. Armstrong,et al. A reassessment of the influence of NAA on aerenchyma formation in maize roots , 1991 .
[76] L. Eliasson,et al. Ethylene accelerates the breakdown of cytokinins and thereby stimulates rooting in Norway spruce hypocotyl cuttings , 1990 .
[77] H. J. Laanbroek. Bacterial cycling of minerals that affect plant growth in waterlogged soils: a review , 1990 .
[78] W. Ernst. Ecophysiology of plants in waterlogged and flooded environments , 1990 .
[79] L. Eliasson,et al. Factors increasing ethylene production enhance the sensitivity of root growth to auxins , 1990 .
[80] H. Greenway,et al. Aerenchyma formation and associated oxygen movement in seminal and nodal roots of wheat. , 1990 .
[81] P. Cohen,et al. Okadaic acid: a new probe for the study of cellular regulation. , 1990, Trends in biochemical sciences.
[82] S. Biondi,et al. Polyamines and ethylene in relation to adventitious root formation in Prunus avium shoot cultures , 1990 .
[83] M. Drew,et al. Decreased Ethylene Biosynthesis, and Induction of Aerenchyma, by Nitrogen- or Phosphate-Starvation in Adventitious Roots of Zea mays L. , 1989, Plant physiology.
[84] W. Armstrong,et al. Root morphology and aerenchyma formation as indicators for the flood-tolerance of Rumex species , 1989 .
[85] J. Suttle. Effect of Ethylene Treatment on Polar IAA Transport, Net IAA Uptake and Specific Binding of N-1-Naphthylphthalamic Acid in Tissues and Microsomes Isolated from Etiolated Pea Epicotyls. , 1988, Plant physiology.
[86] K. McLeod,et al. Promotion of aerenchyma formation in Pinusserotina seedlings by ethylene , 1988 .
[87] W. Armstrong,et al. THE ANATOMICAL CHARACTERISTICS OF ROOTS AND PLANT RESPONSE TO SOIL FLOODING , 1987 .
[88] T. Kozlowski,et al. Regulation by auxin and ethylene of responses of Acer negundo seedlings to flooding of soil , 1987 .
[89] A. Bleecker,et al. An evaluation of 2,5-norbornadiene as a reversible inhibitor of ethylene action in deepwater rice. , 1987, Plant physiology.
[90] K. McLeod,et al. Responses of Pinus clausa, Pinus serotina and Pinus taeda seedlings to anaerobic solution culture. I. Changes in growth and root morphology , 1986 .
[91] H. Aarnes,et al. Response of Young Barley Plants to Waterlogging, as Related to Concentration of Ethylene and Ethane , 1986 .
[92] M. Jackson,et al. Aerenchyma (Gas-space) Formation in Adventitious Roots of Rice (Oryza sativa L.) is not Controlled by Ethylene or Small Partial Pressures of Oxygen , 1985 .
[93] M. Jackson,et al. Stimulation of ethylene production and gas-space (aerenchyma) formation in adventitious roots of Zea mays L. by small partial pressures of oxygen , 1985, Planta.
[94] H. Suge. Ethylene and Gibberellin : Regulation of Internodal Elongation and Nodal Root Development in Floating Rice , 1985 .
[95] L. Eliasson,et al. Regulation of root formation by auxin‐ethylene interaction in pea stem cuttings , 1984 .
[96] H. Konings,et al. Promotion and inhibition by plant growth regulators of aerenchyma formation in seedling roots of Zea mays , 1984 .
[97] J. Etherington. Control of Germination and Seedling Morphology by Ethene: Differential Responses, Related to Habitat of Epilobium hirsutum L. and Chamerion angustifolium (L.) J. Holub , 1983 .
[98] M. Drew,et al. Electron microscopy of gas space (aerenchyma) formation in adventitious roots of Zea mays L. subjected to oxygen shortage , 1983, Planta.
[99] R. Crawford,et al. Variation in the Structure and Response to Flooding of Root Aerenchyma in some Wetland Plants , 1983 .
[100] E. Yeung,et al. Adventitious rooting in hypocotyls of sunflower (Helianthus annuus) seedlings , 1981 .
[101] J. Taylor,et al. Adventitious rooting in hypocotyls of sunflower (Helianthus annuus) seedlings. II. Action of gibberellins, cytokinins, auxins and ethylene , 1981 .
[102] M. Jackson,et al. Inhibition by silver ions of gas space (aerenchyma) formation in adventitious roots of Zea mays L. subjected to exogenous ethylene or to oxygen deficiency , 1981, Planta.
[103] M. Kawase. EFFECT OF ETHYLENE ON AERENCHYMA DEVELOPMENT , 1981 .
[104] H. Konings,et al. Formation of aerenchyma in roots of Zea mays in aerated solutions, and its relation to nutrient supply , 1980 .
[105] M. Jackson,et al. Ethylene-promoted adventitious rooting and development of cortical air spaces (aerenchyma) in roots may be adaptive responses to flooding in Zea mays L , 1979, Planta.
[106] M. Jackson,et al. A Relationship between Rates of Ethylene Production by Roots and the Promoting or Inhibiting Effects of Exogenous Ethylene and Water on Root Elongation , 1979 .
[107] D. M. Reid,et al. The Role of Endogenous Auxins and Ethylene in the Formation of Adventitious Roots and Hypocotyl Hypertrophy in Flooded Sunflower Plants (Helianthus annuus) , 1979 .
[108] M. Kawase. ROLE OF CELLULASE IN AERENCHYMA DEVELOPMENT IN SUNFLOWER , 1979 .
[109] A. Watanabe,et al. Role of oxygen in auxin-induced ethylene production , 1977 .
[110] M. Kawase. Role of Ethylene in Induction of Flooding Damage in Sunflower , 1974 .
[111] A. Musgrave,et al. ETHYLENE-STIMULATED GROWTH AND AUXIN ANSPORT IN RANUNCULUS SCELERATUS PETIOLES , 1973 .
[112] P. Morgan,et al. Ethylene modification of an auxin pulse in cotton stem sections. , 1969, Plant physiology.
[113] K. A. Smith,et al. Occurrence of Ethylene, and its Significance, in Anaerobic Soil , 1969, Nature.
[114] P J Kramer,et al. CAUSES OF INJURY TO PLANTS RESULTING FROM FLOODING OF THE SOIL. , 1951, Plant physiology.
[115] D. Mcpherson,et al. CORTICAL AIR SPACES IN THE ROOTS OF ZEA MAYS L. , 1939 .
[116] A. Bryant. COMPARISON OF ANATOMICAL AND HISTOLOGICAL DIFFERENCES BETWEEN ROOTS OF BARLEY GROWN IN AERATED AND IN NON-AERATED CULTURE SOLUTIONS. , 1934, Plant physiology.
[117] M. Cox. Plant movement; kinetics and hormonal regulation of hyponastic growth and petiole elongation , 2004 .
[118] M. Jackson,et al. Physiology, Biochemistry and Molecular Biology of Plant Root Systems Subjected to Flooding of the Soil , 2003 .
[119] T. Colmer. Long-distance transport of gases in plants: a perspective on internal aeration and radial oxygen loss from roots , 2003 .
[120] Yinggen Ke,et al. Effect of Polar Auxin Transport on Rice Root Development , 2003 .
[121] M. Jackson,et al. Characterisation of programmed cell death during aerenchyma formation induced by ethylene or hypoxia in roots of maize(Zea mays L.) , 2001, Planta.
[122] M. Sauter,et al. Adventitious root growth and cell-cycle induction in deepwater rice , 1999, Plant physiology.
[123] B. Trevaskis,et al. Strategies of Gene Action in Arabidopsis during Hypoxia , 1997 .
[124] L. Voesenek,et al. Regulatory role of auxin in adventitious root formation in two species of Rumex, differing in their sensitivity to waterlogging , 1995 .
[125] Tim D. Davis,et al. Biology of Adventitious Root Formation , 1994, Basic Life Sciences.
[126] Peter W. Barlow,et al. The Origin, Diversity and Biology of Shoot-Borne Roots , 1994 .
[127] M. Drew,et al. Enhanced Sensitivity to Ethylene in Nitrogen- or Phosphate-Starved Roots of Zea mays L. during Aerenchyma Formation. , 1992, Plant physiology.
[128] M. Jackson,et al. The influence of oxygen deficiency on ethylene synthesis, 1‐aminocyclopropane‐1‐carboxylic acid levels and aerenchyma formation in roots of Zea mays , 1988 .
[129] M. Jackson. Ethylene and responses of plants to soil waterlogging and submergence , 1985 .
[130] F. Ponnamperuma,et al. CHAPTER 2 – Effects of Flooding on Soils , 1984 .
[131] W. Armstrong. Aeration in Higher Plants , 1980 .
[132] I. D. Phillips. Root-shoot Hormone Relations II. Changes in Endogenous Auxin Concentration produced by Flooding of the Root System in Helianthus annuus , 1964 .