Wheat roots efflux a diverse array of organic N compounds and are highly proficient at their recapture
暂无分享,去创建一个
[1] Nadine Strehmel,et al. Profiling of secondary metabolites in root exudates of Arabidopsis thaliana. , 2014, Phytochemistry.
[2] L. Marcelis,et al. The importance of a sterile rhizosphere when phenotyping for root exudation , 2014, Plant and Soil.
[3] W. Wenzel,et al. Root exudation of phytosiderophores from soil-grown wheat , 2014, The New phytologist.
[4] C. Warren. Response of osmolytes in soil to drying and rewetting , 2014 .
[5] J. Abadía,et al. Involvement of the ABCG37 transporter in secretion of scopoletin and derivatives by Arabidopsis roots in response to iron deficiency. , 2014, The New phytologist.
[6] C. Warren. Organic N molecules in the soil solution: what is known, what is unknown and the path forwards , 2014, Plant and Soil.
[7] C. Warren. Development of a capillary electrophoresis–mass spectrometry method for small peptides in the soil solution , 2013 .
[8] C. Warren. Quaternary ammonium compounds can be abundant in some soils and are taken up as intact molecules by plants. , 2013, The New phytologist.
[9] C. Warren. High diversity of small organic N observed in soil water , 2013 .
[10] Matthew G. Bakker,et al. Root Exudation of Phytochemicals in Arabidopsis Follows Specific Patterns That Are Developmentally Programmed and Correlate with Soil Microbial Functions , 2013, PloS one.
[11] J. Vivanco,et al. Influence of ATP-Binding Cassette Transporters in Root Exudation of Phytoalexins, Signals, and in Disease Resistance , 2012, Frontiers in plant science.
[12] T. Näsholm,et al. The below-ground perspective of forest plants: soil provides mainly organic nitrogen for plants and mycorrhizal fungi. , 2012, The New phytologist.
[13] Davey L. Jones,et al. Microbial and plant uptake of free amino sugars in grassland soils , 2012 .
[14] C. Warren. Post-uptake metabolism affects quantification of amino acid uptake. , 2012, The New phytologist.
[15] I. Aranda,et al. Metabolomics demonstrates divergent responses of two Eucalyptus species to water stress , 2012, Metabolomics.
[16] David L. Jones,et al. Acquisition and Assimilation of Nitrogen as Peptide-Bound and D-Enantiomers of Amino Acids by Wheat , 2011, PloS one.
[17] K. Kashiwagi,et al. Characteristics of cellular polyamine transport in prokaryotes and eukaryotes. , 2010, Plant physiology and biochemistry : PPB.
[18] J. Cliquet,et al. Characterisation of root amino acid exudation in white clover (Trifolium repens L.) , 2010, Plant and Soil.
[19] K. Kielland,et al. Uptake of organic nitrogen by plants. , 2009, The New phytologist.
[20] J. Vivanco,et al. Regulation and function of root exudates. , 2008, Plant, cell & environment.
[21] U. Edlund,et al. Visualization of GC/TOF-MS-based metabolomics data for identification of biochemically interesting compounds using OPLS class models. , 2008, Analytical chemistry.
[22] S. Schmidt,et al. Transporters for uptake and allocation of organic nitrogen compounds in plants , 2007, FEBS letters.
[23] M. Bataillé,et al. Root amino acid exudation: measurement of high efflux rates of glycine and serine from six different plant species , 2007, Plant and Soil.
[24] K. Huss-Danell,et al. Characteristics of amino acid uptake in barley , 2007, Plant and Soil.
[25] C. Warren. Potential organic and inorganic N uptake by six Eucalyptus species. , 2006, Functional plant biology : FPB.
[26] J. Six,et al. Root exudation (net efflux of amino acids) may increase rhizodeposition under elevated CO2 , 2006 .
[27] A. Hodge,et al. Dissolved organic nitrogen uptake by plants—an important N uptake pathway? , 2005 .
[28] D. Phillips,et al. Microbial Products Trigger Amino Acid Exudation from Plant Roots1 , 2004, Plant Physiology.
[29] F. Dakora,et al. Root exudates as mediators of mineral acquisition in low-nutrient environments , 2002, Plant and Soil.
[30] H. Lambers,et al. Influx, efflux and net uptake of nitrate in Quercus suber seedlings , 2000, Plant and Soil.
[31] David L. Jones. Organic acids in the rhizosphere – a critical review , 1998, Plant and Soil.
[32] H. Kronzucker,et al. Compartmentation and flux characteristics of ammonium in spruce , 1995, Planta.
[33] D. Jones,et al. Amino-acid influx at the soil-root interface of Zea mays L. and its implications in the rhizosphere , 1994, Plant and Soil.
[34] D. Jones,et al. Influx and efflux of amino acids from Zea mays L. roots and their implications for N nutrition and the rhizosphere , 1993, Plant and Soil.
[35] H. Kronzucker,et al. Compartmentation and flux characteristics of nitrate in spruce , 2004, Planta.
[36] Richard D. Bardgett,et al. SOIL MICROBES COMPETE EFFECTIVELY WITH PLANTS FOR ORGANIC‐NITROGEN INPUTS TO TEMPERATE GRASSLANDS , 2003 .
[37] Davey L. Jones,et al. HOW ROOTS CONTROL THE FLUX OF CARBON TO THE RHIZOSPHERE , 2003 .
[38] J. Augustin,et al. Plant rhizodeposition — an important source for carbon turnover in soils , 2002 .
[39] W. Frommer,et al. Conservation of amino acid transporters in fungi, plants and animals. , 2002, Trends in biochemical sciences.
[40] J. Thomas-Oates,et al. Increased uptake of putrescine in the rhizosphere inhibits competitive root colonization by Pseudomonas fluorescens strain WCS365. , 2001, Molecular plant-microbe interactions : MPMI.
[41] T. Näsholm,et al. Amino acid uptake: a widespread ability among boreal forest plants , 2001 .
[42] A. Lane,et al. Comprehensive chemical profiling of gramineous plant root exudates using high-resolution NMR and MS. , 2001, Phytochemistry.
[43] D. T. Britto,et al. Futile transmembrane NH4+ cycling: A cellular hypothesis to explain ammonium toxicity in plants , 2001, Proceedings of the National Academy of Sciences of the United States of America.
[44] A. Hodge,et al. Are microorganisms more effective than plants at competing for nitrogen? , 2000, Trends in plant science.
[45] O. Geiger,et al. Plant-exuded Choline Is Used for Rhizobial Membrane Lipid Biosynthesis by Phosphatidylcholine Synthase* , 1999, The Journal of Biological Chemistry.
[46] B. Shelp,et al. Identification and characterization of GABA, proline and quaternary ammonium compound transporters from Arabidopsis thaliana , 1999, FEBS letters.
[47] edited by Toshimasa Toyo'oka. Modern Derivatization Methods for Separation Science , 1999 .
[48] 豊岡 利正. Modern derivatization methods for separation sciences , 1999 .
[49] S. Schmidt,et al. Glycine metabolism by plant roots and its occurrence in Australian plant communities , 1999 .
[50] D. Read,et al. The biology of mycorrhiza in the Ericaceae. XVIII. Chitin degradation by Hymenoscyphus ericae and transfer of chitin-nitrogen to the host plant. , 1995 .
[51] D. Deamer,et al. Permeability of lipid bilayers to amino acids and phosphate. , 1992, Biochimica et biophysica acta.
[52] C. Schobert,et al. Amino acid uptake by ricinus-communis roots : characterization and physiological significance , 1987 .
[53] A. Altman,et al. Presence and identification of polyamines in xylem and Phloem exudates of plants. , 1986, Plant physiology.
[54] Ingrid Kraffczyk,et al. Soluble root exudates of maize: Influence of potassium supply and rhizosphere microorganisms. , 1984 .
[55] S. Chapelle,et al. Abnormalities of erythrocyte stromal lipids in atresia of the intrahepatic bile ducts. , 1982, Archives internationales de physiologie et de biochimie.
[56] D. Knapp,et al. Handbook of Analytical Derivatization Reactions , 1980 .
[57] D. Read,et al. The biology of mycorrhiza in the Ericaceae , 1973 .
[58] D. J. Samborski,et al. Abnormal metabolites of wheat: Occurrence, isolation and biogenesis of 2-hydroxyputrescine amides , 1970 .
[59] C. Tan,et al. The uptake of ergothioneine from the soil into the latex of Hevea brasiliensis , 1968 .
[60] R. H. Miller,et al. UPTAKE AND ASSIMILATION OF AMINO ACIDS SUPPLIED TO THE STERILE SOIL: ROOT ENVIRONMENT OF THE BEAN PLANT (PHASEOLUS VULGARIS) , 1965 .
[61] N. H. J. Miller,et al. The Direct Assimilation of Inorganic and Organic Forms of Nitrogen by Higher Plants , 1912, The Journal of Agricultural Science.