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M. Darwent, E. Paterson, A. McDonald, A. Tomos (2003)
Biosensor reporting of root exudation from Hordeum vulgare in relation to shoot nitrate concentration.Journal of experimental botany, 54 381
E. Personeni, C. Nguyen, Patrice Marchal, L. Pagès (2007)
Experimental evaluation of an efflux-influx model of C exudation by individual apical root segments.Journal of experimental botany, 58 8
V. Allard, C. Robin, P. Newton, M. Lieffering, J. Soussana (2006)
Short and long-term effects of elevated CO2 on Lolium perenne rhizodeposition and its consequences on soil organic matter turnover and plant N yieldSoil Biology & Biochemistry, 38
R. Gill, R. Jackson (2000)
Global patterns of root turnover for terrestrial ecosystemsNew Phytologist, 147
David Jones, P. Darrah (1995)
Influx and efflux of organic acids across the soil-root interface of Zea mays L. and its implications in rhizosphere C flowPlant and Soil, 173
E. Kramer, N. Frazer, T. Baskin (2007)
Measurement of diffusion within the cell wall in living roots of Arabidopsis thaliana.Journal of experimental botany, 58 11
(1997)
Cytochemical localization of ATPase activity in roots of wheat (Triticum aestivum)
C. Nguyen, Fabienne Froux, S. Recous, T. Morvan, C. Robin (2007)
Net N immobilisation during the biodegradation of mucilage in soil as affected by repeated mineral and organic fertilisationNutrient Cycling in Agroecosystems, 80
V. Stubbs, D. Standing, O. Knox, K. Killham, A. Bengough, B. Griffiths (2004)
Root border cells take up and release glucose-C.Annals of botany, 93 2
J. Harley, R. Russell (1979)
The Soil-Root Interface
F. Henry, C. Nguyen, E. Paterson, A. Sim, C. Robin (2005)
How does nitrogen availability alter rhizodeposition in Lolium multiflorum Lam. during vegetative growth?Plant and Soil, 269
Miroslav Ovečka, Miroslav Ovečka, Ingeborg Lang, František Baluška, František Baluška, A. Ismail, Peter Illéš, I. Lichtscheidl (2005)
Endocytosis and vesicle trafficking during tip growth of root hairsProtoplasma, 226
Delphine Derrien, C. Marol, J. Balesdent (2004)
The dynamics of neutral sugars in the rhizosphere of wheat. An approach by13C pulse-labelling and GC/C/IRMSPlant and Soil, 267
D. Emerson, L. Agulto, Henry Liu, Liping Liu (2008)
Identifying and Characterizing Bacteria in an Era of Genomics and Proteomics, 58
P. Thaler, L. Pagès (1998)
Modelling the influence of assimilate availability on root growth and architecturePlant and Soil, 201
S. Roberts (2006)
Plasma membrane anion channels in higher plants and their putative functions in roots.The New phytologist, 169 4
G. Neumann, V. Römheld (2007)
The Release of Root Exudates as Affected by the Plant Physiological Status
B. Thornton (2001)
Uptake of glycine by non-mycorrhizal Lolium perenne.Journal of experimental botany, 52 359
David Jones, Peter Darah, L. Kochian (1996)
Critical evaluation of organic acid mediated iron dissolution in the rhizosphere and its potential role in root iron uptakePlant and Soil, 180
B. Amiro, L. Ewing (1992)
Physiological conditions and uptake of inorganic carbon-14 by plant rootsEnvironmental and Experimental Botany, 32
Robert Paull, Russell Jones (1976)
Studies on the Secretion of Maize Root Cap Slime V. The Cell Wall as a Barrier to SecretionZeitschrift für Pflanzenphysiologie, 79
R. Paull, Russell Jones (2004)
Studies on the secretion of maize root-cap slimePlanta, 127
L. Brigham, H. Woo, S. Nicoll, M. Hawes (1995)
Differential Expression of Proteins and mRNAs from Border Cells and Root Tips of Pea, 109
M. Dilworth (2007)
Nitrogen-fixing leguminous symbioses
M. Dimou, E. Flemetakis, C. Delis, G. Aivalakis, Karoline Spyropoulos, P. Katinakis (2005)
Genes coding for a putative cell-wall invertase and two putative monosaccharide/H+ transporters are expressed in roots of etiolated Glycine max seedlingsPlant Science, 169
H. Bais, Sang-Wook Park, T. Weir, R. Callaway, J. Vivanco (2004)
How plants communicate using the underground information superhighway.Trends in plant science, 9 1
S. Shishkova, J. Dubrovsky (2005)
Developmental programmed cell death in primary roots of Sonoran Desert Cactaceae.American journal of botany, 92 9
P. Högberg, M. Högberg, S. Göttlicher, N. Betson, S. Keel, Daniel Metcalfe, C. Campbell, A. Schindlbacher, V. Hurry, Thomas Lundmark, Sune Linder, T. Näsholm (2007)
High temporal resolution tracing of photosynthate carbon from the tree canopy to forest soil microorganisms.The New phytologist, 177 1
P. Vandenkoornhuyse, S. Mahé, P. Ineson, P. Staddon, N. Ostle, J. Cliquet, A. Francez, A. Fitter, J. Young (2007)
Active root-inhabiting microbes identified by rapid incorporation of plant-derived carbon into RNAProceedings of the National Academy of Sciences, 104
J. Patrick (1997)
PHLOEM UNLOADING: Sieve Element Unloading and Post-Sieve Element Transport.Annual review of plant physiology and plant molecular biology, 48
H. Lambers, C. Mougel, B. Jaillard, P. Hinsinger (2009)
Plant-microbe-soil interactions in the rhizosphere: an evolutionary perspectivePlant and Soil, 321
A. Fleischer, R. Ehwald (1995)
The free space of sugars in plant tissues6Journal of Experimental Botany, 46
Robert Paull
Studies on the Secretion of Maize Root Cap Slime
H. Lambers, J. Raven, G. Shaver, Sarah Smith (2008)
Plant nutrient-acquisition strategies change with soil age.Trends in ecology & evolution, 23 2
P. Hill, J. Farrar, David Jones (2008)
Decoupling of microbial glucose uptake and mineralization in soilSoil Biology & Biochemistry, 40
A. Bengough, J. Kirby (1999)
Tribology of the root cap in maize (Zea mays) and peas (Pisum sativum)New Phytologist, 142
Ingrid Kraffczyk, G. Trolldenier, H. Beringer (1984)
Soluble root exudates of maize: Influence of potassium supply and rhizosphere microorganisms.Soil Biology & Biochemistry, 16
A. Hirner, Friederike Ladwig, H. Stransky, Sakiko Okumoto, Melanie Keinath, A. Harms, W. Frommer, Wolfgang Koch (2006)
Arabidopsis LHT1 Is a High-Affinity Transporter for Cellular Amino Acid Uptake in Both Root Epidermis and Leaf Mesophyll[W]The Plant Cell Online, 18
Lorraine Williams, Rémi Lemoine, Norbert Sauer (2000)
Sugar transporters in higher plants--a diversity of roles and complex regulation.Trends in plant science, 5 7
D. Faure, D. Vereecke, J. Leveau (2009)
Molecular communication in the rhizospherePlant and Soil, 321
P. Darrah (1991)
Models of the rhizospherePlant and Soil, 133
D. Patel, P. Barlow, R. Lee (1990)
Development of vacuolar volume in the root tips of peaAnnals of Botany, 65
Michael Haydon, C. Cobbett (2007)
Transporters of ligands for essential metal ions in plants.The New phytologist, 174 3
C. Ford, N. Wurzburger, R. Hendrick, R. Teskey (2007)
Soil DIC uptake and fixation in Pinus taeda seedlings and its C contribution to plant tissues and ectomycorrhizal fungi.Tree physiology, 27 3
T. Boutton, S. Yamasaki (1996)
Stable carbon isotope ratios of soil organic matter and their use as indicators of vegetation and climate change.
I. Ciereszko, J. Farrar, A. Rychter (1999)
Compartmentation and Fluxes of Sugars in Roots of Phaseolus Vulgaris Under Phosphate DeficiencyBiologia Plantarum, 42
D. Meldrum (2000)
Automation for genomics, part two: sequencers, microarrays, and future trends.Genome research, 10 9
J. Rangel-Castro, J. Prosser, N. Ostle, C. Scrimgeour, K. Killham, A. Meharg (2005)
Flux and turnover of fixed carbon in soil microbial biomass of limed and unlimed plots of an upland grassland ecosystem.Environmental microbiology, 7 4
B. Singh, P. Millard, A. Whiteley, J. Murrell (2004)
Unravelling rhizosphere-microbial interactions: opportunities and limitations.Trends in microbiology, 12 8
R. Bardgett, T. Streeter, R. Bol (2003)
SOIL MICROBES COMPETE EFFECTIVELY WITH PLANTS FOR ORGANIC‐NITROGEN INPUTS TO TEMPERATE GRASSLANDSEcology, 84
A. Rovira (1965)
Interactions between plant roots and soil microorganisms.Annual review of microbiology, 19
F. Warembourg (1991)
2 – Photosynthesis/Translocation Studies in Terrestrial Ecosystems
L. Bidel, L. Pagès, L. Rivière, G. Pelloux, J. Lorendeau (2000)
MassFlowDyn I: A Carbon Transport and Partitioning Model for Root System ArchitectureAnnals of Botany, 85
E. Paterson, B. Thornton, A. Midwood, A. Sim (2005)
Defoliation alters the relative contributions of recent and non‐recent assimilate to root exudation from Festuca rubraPlant Cell and Environment, 28
G. Hertenberger, W. Wanek (2004)
Evaluation of methods to measure differential 15N labeling of soil and root N pools for studies of root exudation.Rapid communications in mass spectrometry : RCM, 18 20
David Jones, P. Darrah (2004)
Re-sorption of organic compounds by roots of Zea mays L. and its consequences in the rhizospherePlant and Soil, 178
H. Morel, A. Guckert, S. Plantureux, C. Chenu (1990)
Influence of root exudates on soil aggregation., 9
J. Qian, J. Doran, D. Walters (1997)
Maize plant contributions to root zone available carbon and microbial transformations of nitrogenSoil Biology & Biochemistry, 29
R. Francis, David Read (1984)
Direct transfer of carbon between plants connected by vesicular–arbuscular mycorrhizal myceliumNature, 307
A. Fußeder (1987)
The longevity and activity of the primary root of maizePlant and Soil, 101
R. Finlay, B. Söderström (1992)
Mycorrhiza and carbon flow to the soil
T. Zhu, T. Rost (2000)
Directional cell-to-cell communication in theArabidopsis root apical meristem III. Plasmodesmata turnover and apoptosis in meristem and root cap cells during four weeks after germinationProtoplasma, 213
A. Hodge, S. Grayston, B. Ord (1996)
A novel method for characterisation and quantification of plant root exudatesPlant and Soil, 184
T. Jahn, F. Baluška, W. Michalke, J. Harper, D. Volkmann (1998)
Plasma membrane H+-ATPase in the root apex: Evidence for strong expression in xylem parenchyma and asymmetric localization within cortical and epidermal cellsPhysiologia Plantarum, 104
G. Sacchi, A. Abruzzese, G. Lucchini, F. Fiorani, S. Cocucci (2000)
Efflux and active re-absorption of glucose in roots of cotton plants grown under saline conditionsPlant and Soil, 220
P. Darrah, Davey Jones, G. Kirk, T. Roose (2006)
Modelling the rhizosphere: a review of methods for ‘upscaling’ to the whole‐plant scaleEuropean Journal of Soil Science, 57
D. Wright, D. Read, J. Scholes (1998)
Mycorrhizal sink strength influences whole plant carbon balance of Trifolium repens LPlant Cell and Environment, 21
B. Lindahl, R. Finlay, J. Cairney (2005)
Enzymatic activities of mycelia in mycorrhizal fungal communities
A. Hodge, C. Campbell, A. Fitter (2001)
An arbuscular mycorrhizal fungus accelerates decomposition and acquires nitrogen directly from organic materialNature, 413
M. Högberg, P. Högberg (2002)
Extramatrical ectomycorrhizal mycelium contributes one-third of microbial biomass and produces, together with associated roots, half the dissolved organic carbon in a forest soil.The New phytologist, 154 3
M. Hawes, Uvini Gunawardena, S. Miyasaka, Xiaowen Zhao (2000)
The role of root border cells in plant defense.Trends in plant science, 5 3
M. Mccully, M. Canny (1985)
Localisation of translocated 14C in roots and root exudates of field-grown maizePhysiologia Plantarum, 65
P. Darrah
Models of the rhizosphere II. A quasi three-dimensional simulation of the microbial population dynamics around a growing root releasing soluble exudates
C. Yeomans, Fiona Porteous, E. Paterson, A. Meharg, K. Killham (1999)
Assessment of lux-marked Pseudomonas fluorescens for reporting on organic carbon compoundsFems Microbiology Letters, 176
A. Bengough, B. McKenzie (1997)
Sloughing of root cap cells decreases the frictional resistance to maize (Zea mays L.) root growthJournal of Experimental Botany, 48
Y. Kuzyakov, Davey Jones (2006)
Glucose uptake by maize roots and its transformation in the rhizosphereSoil Biology & Biochemistry, 38
B. Lindahl, K. Ihrmark, J. Boberg, S. Trumbore, P. Högberg, J. Stenlid, R. Finlay (2007)
Spatial separation of litter decomposition and mycorrhizal nitrogen uptake in a boreal forest.The New phytologist, 173 3
J. Leake (2004)
Myco-heterotroph/epiparasitic plant interactions with ectomycorrhizal and arbuscular mycorrhizal fungi.Current opinion in plant biology, 7 4
Ji Jun, Ji Jun, Elisa Fiume, Elisa Fiume, Jennifer Fletcher, Jennifer Fletcher (2008)
The CLE family of plant polypeptide signaling moleculesCellular and Molecular Life Sciences, 65
P. Leinweber, K. Eckhardt, H. Fischer, Y. Kuzyakov (2008)
A new rapid micro-method for the molecular-chemical characterization of rhizodeposits by field-ionization mass spectrometry.Rapid communications in mass spectrometry : RCM, 22 8
E. Gout, R. Bligny, Nadine Pascal, R. Douce (1993)
13C nuclear magnetic resonance studies of malate and citrate synthesis and compartmentation in higher plant cells.The Journal of biological chemistry, 268 6
Minita Shrestha, W. Abraham, P. Shrestha, M. Noll, R. Conrad (2008)
Activity and composition of methanotrophic bacterial communities in planted rice soil studied by flux measurements, analyses of pmoA gene and stable isotope probing of phospholipid fatty acids.Environmental microbiology, 10 2
S. Grayston, D. Vaughan, D. Jones (1997)
Rhizosphere carbon flow in trees, in comparison with annual plants: the importance of root exudation and its impact on microbial activity and nutrient availabilityApplied Soil Ecology, 5
M. Graaff, J. Six, C. Kessel (2007)
Elevated CO2 increases nitrogen rhizodeposition and microbial immobilization of root-derived nitrogen.The New phytologist, 173 4
M. Watt, P. Hugenholtz, R. White, Kerry Vinall (2006)
Numbers and locations of native bacteria on field-grown wheat roots quantified by fluorescence in situ hybridization (FISH).Environmental microbiology, 8 5
N. Wuyts, Z. Maung, R. Swennen, D. Waele (2006)
Banana Rhizodeposition: Characterization of Root Border Cell Production and Effects on Chemotaxis and Motility of the Parasitic Nematode Radopholus similisPlant and Soil, 283
A. Guckert, H. Breisch, O. Reisinger (1975)
Interface sol-racine—I: Etude au microscope electronique des relations mucigel-argile-microorganismesSoil Biology & Biochemistry, 7
E. Paterson, B. Thornton, A. Sim, S. Pratt (2003)
Effects of defoliation and atmospheric CO2 depletion on nitrate acquisition, and exudation of organic compounds by roots of Festuca rubraPlant and Soil, 250
R. Pinton, Z. Varanini, P. Nannipieri (2001)
The rhizosphere : biochemistry and organic substances at the soil-plant interface
L. Pagès, S. Pellerin (1996)
Study of differences between vertical root maps observed in a maize crop and simulated maps obtained using a model for the three-dimensional architecture of the root systemPlant and Soil, 182
A. Meharg (1994)
A critical review of labelling techniques used to quantify rhizosphere carbon-flowPlant and Soil, 166
O. Knox, V. Gupta, D. Nehl, W. Stiller (2007)
Constitutive expression of Cry proteins in roots and border cells of transgenic cottonEuphytica, 154
Smita Srivastava, A. Srivastava (2007)
Hairy Root Culture for Mass-Production of High-Value Secondary MetabolitesCritical Reviews in Biotechnology, 27
G. Beemster, T. Baskin (1998)
Analysis of cell division and elongation underlying the developmental acceleration of root growth in Arabidopsis thaliana.Plant physiology, 116 4
T. Negishi, H. Nakanishi, J. Yazaki, N. Kishimoto, F. Fujii, Kanako Shimbo, Kimiko Yamamoto, K. Sakata, Takuji Sasaki, S. Kikuchi, S. Mori, N. Nishizawa (2002)
cDNA microarray analysis of gene expression during Fe-deficiency stress in barley suggests that polar transport of vesicles is implicated in phytosiderophore secretion in Fe-deficient barley roots.The Plant journal : for cell and molecular biology, 30 1
M. Watt (2009)
The rhizosphere: biochemistry and organic substances at the soil–plant interface. 2nd edn.Annals of Botany, 104
David Jones, A. Hodge, Y. Kuzyakov (2004)
Plant and mycorrhizal regulation of rhizodeposition.The New phytologist, 163 3
R. Fulthorpe, Luiz Roesch, A. Riva, E. Triplett (2008)
Distantly sampled soils carry few species in commonThe ISME Journal, 2
T. Roose, A. Fowler (2004)
A mathematical model for water and nutrient uptake by plant root systems.Journal of theoretical biology, 228 2
C. Buer, G. Muday, M. Djordjevic (2007)
Flavonoids Are Differentially Taken Up and Transported Long Distances in Arabidopsis1[W][OA]Plant Physiology, 145
J. Martin (1975)
14C-labelled material leached from the rhizosphere of plants supplied continuously with 14CO2Soil Biology & Biochemistry, 7
K. Oksman‐Caldentey, D. Inzé (2004)
Plant cell factories in the post-genomic era: new ways to produce designer secondary metabolites.Trends in plant science, 9 9
J. Mayer, F. Buegger, E. Jensen, M. Schloter, J. Heß (2003)
Estimating N rhizodeposition of grain legumes using a 15N in situ stem labelling methodSoil Biology & Biochemistry, 35
M. Canny (1995)
Apoplastic Water and Solute Movement: New Rules for an Old Space, 46
P. Antunes, I. Rajcan, M. Goss (2006)
Specific flavonoids as interconnecting signals in the tripartite symbiosis formed by arbuscular mycorrhizal fungi, Bradyrhizobium japonicum (Kirchner) Jordan and soybean (Glycine max (L.) Merr.)Soil Biology & Biochemistry, 38
J. Vessey (2003)
Plant growth promoting rhizobacteria as biofertilizersPlant and Soil, 255
I. Scheunert, E. Topp, A. Attar, F. Korte (1994)
Uptake pathways of chlorobenzenes in plants and their correlation with N-octanol/water partition coefficients.Ecotoxicology and environmental safety, 27 1
David Johnson, M. Krsek, E. Wellington, A. Stott, L. Cole, R. Bardgett, D. Read, J. Leake (2005)
Soil Invertebrates Disrupt Carbon Flow Through Fungal NetworksScience, 309
B. Mary, C. Fresneau, J. Morel, A. Mariotti (1993)
C and N cycling during decomposition of root mucilage, roots and glucose in soilSoil Biology & Biochemistry, 25
A. Hartmann, M. Schmid, D. Tuinen, G. Berg (2009)
Plant-driven selection of microbesPlant and Soil, 321
A. Herrmann, H. Felle (1995)
Tip growth in root hair cells of Sinapis alba L.: significance of internal and external Ca2+ and pHNew Phytologist, 129
J. Šamaj, N. Read, D. Volkmann, D. Menzel, F. Baluška (2005)
The endocytic network in plants.Trends in cell biology, 15 8
David Jones, David Jones, P. Darrah, P. Darrah (1994)
Amino-acid influx at the soil-root interface of Zea mays L. and its implications in the rhizospherePlant and Soil, 163
H. Wallander, L. Nilsson, David Hagerberg, E. Bååth (2001)
Estimation of the biomass and seasonal growth of external mycelium of ectomycorrhizal fungi in the field.The New phytologist, 151 3
M. Mench, J. Morel, A. Guckert (1987)
Metal binding properties of high molecular weight soluble exudates from maize (Zea mays L.) rootsBiology and Fertility of Soils, 3
B. McDougall, A. Rovira (1970)
Sites of exudation of 14C-labelled compounds from wheat roots.New Phytologist, 69
N. Dilkes, David Jones, J. Farrar (2004)
Temporal Dynamics of Carbon Partitioning and Rhizodeposition in Wheat1Plant Physiology, 134
S. Czarnes, P. Hallett, A. Bengough, I. Young (2000)
Root‐ and microbial‐derived mucilages affect soil structure and water transportEuropean Journal of Soil Science, 51
W. Cheng, D. Coleman, C. Carroll, C. Hoffman (1993)
In situ measurement of root respiration and soluble C concentrations in the rhizosphereSoil Biology & Biochemistry, 25
F. Wichern, J. Mayer, R. Joergensen, T. Müller (2007)
Rhizodeposition of C and N in peas and oats after 13C–15N double labelling under field conditionsSoil Biology & Biochemistry, 39
Robert Paull, Russell Jones (1976)
Studies on the Secretion of Maize Root Cap Slime: IV. Evidence for the Involvement of Dictyosomes.Plant physiology, 57 2
R. Abuzinadah, D. Read (1989)
Carbon transfer associated with assimilation of organic nitrogen sources by silver birch (Betula pendula Roth.)Trees, 3
D. Hukin, C. Doering-Saad, C. Thomas, J. Pritchard (2002)
Sensitivity of cell hydraulic conductivity to mercury is coincident with symplasmic isolation and expression of plasmalemma aquaporin genes in growing maize rootsPlanta, 215
J. Johnson, D. Allan, C. Vance, G. Weiblen (1996)
Root Carbon Dioxide Fixation by Phosphorus-Deficient Lupinus albus (Contribution to Organic Acid Exudation by Proteoid Roots), 112
R. Finlay (2007)
Ecological aspects of mycorrhizal symbiosis: with special emphasis on the functional diversity of interactions involving the extraradical mycelium.Journal of experimental botany, 59 5
D. Lipson, T. Näsholm (2001)
The unexpected versatility of plants: organic nitrogen use and availability in terrestrial ecosystemsOecologia, 128
M. Filion, M. St-Arnaud, J. Fortin (1999)
Direct interaction between the arbuscular mycorrhizal fungus Glomus intraradices and different rhizosphere microorganismsNew Phytologist, 141
W. Cram (1974)
Effects of Cl− on HCO3− and Malate Fluxes and CO2 Fixation in Carrot and Barley Root CellsJournal of Experimental Botany, 25
M. Bidartondo, D. Redecker, Isabelle Hijri, A. Wiemken, T. Bruns, L. Domínguez, A. Sérsic, J. Leake, D. Read (2002)
Epiparasitic plants specialized on arbuscular mycorrhizal fungiNature, 419
R. Paull, C. Johnson, R. Jones (1975)
Studies on the secretion of maize root cap slime: I. Some properties of the secreted polymer.Plant physiology, 56 2
J. Dighton, James White, Peter Oudemans (2005)
The fungal community : its organization and role in the ecosystem
A. Rovira, R. Foster, J. Martin (1979)
NOTE ON TERMINOLOGY: ORIGIN, NATURE AND NOMENCLATURE OF THE ORGANIC MATERIALS IN THE RHIZOSPHERE
Fushi Wen, H. Vanetten, G. Tsaprailis, M. Hawes (2006)
Extracellular Proteins in Pea Root Tip and Border Cell Exudates1[OA]Plant Physiology, 143
J. Zheng, J. Sutton, H. Yu (2000)
Interactions among Pythium aphanidermatum, roots, root mucilage, and microbial agents in hydroponic cucumbersCanadian Journal of Plant Pathology, 22
Jinan Feng, R. Volk, W. Jackson (1994)
Inward and outward transport of ammonium in roots of maize and sorghum: contrasting effects of methionine sulphoximineJournal of Experimental Botany, 45
E. Hoffland, G. Findenegg, J. Nelemans (2005)
Solubilization of rock phosphate by rapePlant and Soil, 113
J. Johansson, L. Paul, R. Finlay (2004)
Microbial interactions in the mycorrhizosphere and their significance for sustainable agriculture.FEMS microbiology ecology, 48 1
D. Phillips, T. Fox, J. Six (2006)
Root exudation (net efflux of amino acids) may increase rhizodeposition under elevated CO2Global Change Biology, 12
(2007)
Fa r r a r JF (2007 ) The f a t e o f
P. Offre, B. Pivato, S. Mazurier, S. Siblot, G. Berta, P. Lemanceau, C. Mougel (2008)
Microdiversity of Burkholderiales associated with mycorrhizal and nonmycorrhizal roots of Medicago truncatula.FEMS microbiology ecology, 65 2
David Johnson, J. Leake, N. Ostle, P. Ineson, D. Read (2002)
In situ13CO2 pulse-labelling of upland grassland demonstrates a rapid pathway of carbon flux from arbuscular mycorrhizal mycelia to the soilNew Phytologist, 153
V. Matiru, F. Dakora (2005)
The rhizosphere signal molecule lumichrome alters seedling development in both legumes and cereals.The New phytologist, 166 2
U. Nehls (2008)
Mastering ectomycorrhizal symbiosis: the impact of carbohydrates.Journal of experimental botany, 59 5
C. Nguyen, A. Guckert (2001)
Short-term utilisation of 14C-[U]glucose by soil microorganisms in relation to carbon availabilitySoil Biology & Biochemistry, 33
H. Bouwmeester, C. Roux, J. López-Ráez, G. Bécard (2007)
Rhizosphere communication of plants, parasitic plants and AM fungi.Trends in plant science, 12 5
A. Bahyrycz, D. Konopińska (2007)
Plant signalling peptides: some recent developmentsJournal of Peptide Science, 13
S. Simard, D. Perry, Melanie Jones, D. Myrold, D. Durall, R. Molina (1997)
Net transfer of carbon between ectomycorrhizal tree species in the fieldNature, 388
J. Ditomaso, J. Hart, L. Kochian (1992)
Transport kinetics and metabolism of exogenously applied putrescine in roots of intact maize seedlings.Plant physiology, 98 2
E. Paterson, A. Sim, D. Standing, M. Dorward, A. McDonald (2006)
Root exudation from Hordeum vulgare in response to localized nitrate supply.Journal of experimental botany, 57 10
(1996)
Model Geo-Biosph Process
K. Treseder, Katie Turner (2007)
Glomalin in EcosystemsSoil Science Society of America Journal, 71
A. Stewart, D. Frank (2008)
Short sampling intervals reveal very rapid root turnover in a temperate grasslandOecologia, 157
C. Mcclaugherty, J. Aber, J. Melillo (1982)
The Role of Fine Roots in the Organic Matter and Nitrogen Budgets of Two Forested EcosystemsEcology, 63
S. Roux, I. Steinebrunner (2007)
Extracellular ATP: an unexpected role as a signaler in plants.Trends in plant science, 12 11
M. Hawes, L. Brigham, Fushi Wen, H. Woo, Y. Zhu (1998)
Function of root border cells in plant health: pioneers in the rhizosphere.Annual review of phytopathology, 36
J. Morel, M. Mench, A. Guckert (1986)
Measurement of Pb2+, Cu2+ and Cd2+ binding with mucilage exudates from maize (Zea mays L.) rootsBiology and Fertility of Soils, 2
F. Chapin, Lori Moilanen, K. Kielland (1993)
Preferential use of organic nitrogen for growth by a non-mycorrhizal arctic sedgeNature, 361
T. Boutton, 山崎慎一 (1996)
Mass spectrometry of soils
Susan Miyasaka, Martha Hawes (2001)
Possible role of root border cells in detection and avoidance of aluminum toxicity.Plant physiology, 125 4
G. Gadd (2006)
Fungi in biogeochemical cycles
K. Oksman‐Caldentey, R. Verpoorte, R. Heijden, J. Memelink (2004)
Engineering the plant cell factory for secondary metabolite productionTransgenic Research, 9
G. Welbaum, A. Sturz, Z. Dong, J. Nowak (2004)
Managing Soil Microorganisms to Improve Productivity of Agro-EcosystemsCritical Reviews in Plant Sciences, 23
A. Schnepf, T. Roose (2006)
Modelling the contribution of arbuscular mycorrhizal fungi to plant phosphate uptake.The New phytologist, 171 3
B. Mary, A. Mariotti, J. Morel (1992)
Use ofr 13C variations at natural abundance for studying the biodegradation of root mucilage, roots and glucose in soilSoil Biology & Biochemistry, 24
P. Ryan, E. Delhaize, D. Jones (2001)
FUNCTION AND MECHANISM OF ORGANIC ANION EXUDATION FROM PLANT ROOTS.Annual review of plant physiology and plant molecular biology, 52
P. Hinsinger (2001)
Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes: a reviewPlant and Soil, 237
J. Whipps (2001)
Microbial interactions and biocontrol in the rhizosphere.Journal of experimental botany, 52 Spec Issue
E. Newman, A. Watson (1977)
Microbial abundance in the rhizosphere: A computer modelPlant and Soil, 48
D. Jones, P. Darrah (1992)
Re-sorption of organic components by roots of Zea mays L. and its consequences in the rhizospherePlant and Soil, 143
E. Boddy, P. Hill, J. Farrar, David Jones (2007)
Fast turnover of low molecular weight components of the dissolved organic carbon pool of temperate grassland field soilsSoil Biology & Biochemistry, 39
Li-Fen Huang, Philip Bocock, J. Davis, K. Koch (2007)
Regulation of invertase: a 'suite' of transcriptional and post-transcriptional mechanisms.Functional plant biology : FPB, 34 6
E. Paterson, A. Sim (1999)
Rhizodeposition and C-partitioning of Lolium perenne in axenic culture affected by nitrogen supply and defoliationPlant and Soil, 216
D. Godbold, M. Hoosbeek, M. Lukac, M. Cotrufo, Ivan Janssens, R. Ceulemans, A. Polle, E. Velthorst, G. Scarascia-Mugnozza, P. Angelis, F. Miglietta, A. Peressotti (2006)
Mycorrhizal Hyphal Turnover as a Dominant Process for Carbon Input into Soil Organic MatterPlant and Soil, 281
A. Hodge, E. Paterson, B. Thornton, P. Millard, K. Killham (1997)
Effects of photon flux density on carbon partitioning and rhizosphere carbon flow of Lolium perenneJournal of Experimental Botany, 48
C. Todorovic, C. Nguyen, C. Robin, A. Guckert (2004)
Root and microbial involvement in the kinetics of 14C-partitioning to rhizosphere respiration after a pulse labelling of maize assimilatesPlant and Soil, 228
C. Körner, R. Asshoff, Olivier Bignucolo, S. Hättenschwiler, S. Keel, S. Peláez-Riedl, S. Pepin, R. Siegwolf, G. Zotz (2005)
Carbon Flux and Growth in Mature Deciduous Forest Trees Exposed to Elevated CO2Science, 309
M. Iijima, B. Griffiths, A. Bengough (2000)
Sloughing of cap cells and carbon exudation from maize seedling roots in compacted sand.The New phytologist, 145 3
A. Rosling, B. Lindahl, R. Finlay (2004)
Carbon allocation to ectomycorrhizal roots and mycelium colonising different mineral substrates.The New phytologist, 162 3
E. Paterson, G. Osler, L. Dawson, T. Gebbing, A. Sim, B. Ord (2008)
Labile and recalcitrant plant fractions are utilised by distinct microbial communities in soil: Independent of the presence of roots and mycorrhizal fungiSoil Biology & Biochemistry, 40
C. Nguyen (2003)
Rhizodeposition of organic C by plants: mechanisms and controlsAgronomie, 23
J. Hart, J. Ditomaso, D. Linscott, L. Kochian (1992)
Transport Interactions between Paraquat and Polyamines in Roots of Intact Maize Seedlings.Plant physiology, 99 4
Kawak Volcano, L. Jones, S. Depositional (1998)
Boreal forest plants take up organic nitrogen
Ayalew Ligaba, M. Katsuhara, P. Ryan, M. Shibasaka, H. Matsumoto (2006)
The BnALMT1 and BnALMT2 Genes from Rape Encode Aluminum-Activated Malate Transporters That Enhance the Aluminum Resistance of Plant Cells1Plant Physiology, 142
Jane Johnson, Carroll Vance, D. Allan (1996)
Phosphorus Deficiency in Lupinus albus (Altered Lateral Root Development and Enhanced Expression of Phosphoenolpyruvate Carboxylase), 112
J. Torrey, D. Clarkson (1975)
The Development and function of roots : third Cabot symposium
H. Yamasaki, M. Cohen (2006)
NO signal at the crossroads: polyamine-induced nitric oxide synthesis in plants?Trends in plant science, 11 11
G. Bending, David Read (1995)
The structure and function of the vegetative mycelium of ectomycorrhizal plantsNew Phytologist, 130
M. Mccully, J. Boyer (1997)
The expansion of maize root‐cap mucilage during hydration. 3. Changes in water potential and water contentPhysiologia Plantarum, 99
Robert Paull, Russell Jones (1975)
Studies on the Secretion of Maize Root Cap Slime: II. Localization of Slime Production.Plant physiology, 56 2
J. Swinnen (1994)
Rhizodeposition and turnover of root-derived organic material in barley and wheat under conventional and integrated managementAgriculture, Ecosystems & Environment, 51
A. Sugiyama, N. Shitan, K. Yazaki (2007)
Involvement of a Soybean ATP-Binding Cassette-Type Transporter in the Secretion of Genistein, a Signal Flavonoid in Legume-Rhizobium Symbiosis1Plant Physiology, 144
A. Fleischer, R. Ehwald (1995)
The free space of sugars in plant tissues - external film and apoplastic volumeJournal of Experimental Botany, 46
P. Hill, C. Marshall, G. Williams, H. Blum, H. Harmens, D. Jones, J. Farrar (2007)
The fate of photosynthetically-fixed carbon in Lolium perenne grassland as modified by elevated CO2 and sward management.The New phytologist, 173 4
P. Högberg, D. Read (2006)
Towards a more plant physiological perspective on soil ecology.Trends in ecology & evolution, 21 10
D. Read, J. Pérez‐Moreno (2003)
Mycorrhizas and nutrient cycling in ecosystems - a journey towards relevance?The New phytologist, 157 3
Daniela Schraut, C. Ullrich, W. Hartung (2004)
Lateral ABA transport in maize roots (Zea mays): visualization by immunolocalization.Journal of experimental botany, 55 403
Yu Sun, T. Unestam, S. Lucas, K. Johanson, L. Kenne, R. Finlay (1999)
Exudation-reabsorption in a mycorrhizal fungus, the dynamic interface for interaction with soil and soil microorganismsMycorrhiza, 9
A. Rothe, D. Binkley (2001)
Nutritional interactions in mixed species forests: a synthesisCanadian Journal of Forest Research, 31
A. Bacic, S. Moody, J. McComb, J. Hinch, A. Clarke (1987)
Extracellular polysaccharides from shaken liquid cultures of Zea maysAustralian Journal of Plant Physiology, 14
Y. Kuzyakov (2002)
Separating microbial respiration of exudates from root respiration in non-sterile soils: A comparison of four methodsSoil Biology & Biochemistry, 34
R. H, D. H, Y. Y (2005)
Patterns of rhizosphere carbon flux in sugar maple ( Acer saccharum ) and yellow birch ( Betula allegheniensis ) saplings
F. Clark (1949)
Soil Microorganisms and Plant RootsAdvances in Agronomy, 1
J. Farrar, M. Hawes, Davey Jones, S. Lindow (2003)
HOW ROOTS CONTROL THE FLUX OF CARBON TO THE RHIZOSPHEREEcology, 84
I. Scheurwater, D. Clarkson, J. Purves, Geraldine Rijt, L. Saker, R. Welschen, H. Lambers (1999)
Relatively large nitrate efflux can account for the high specific respiratory costs for nitrate transport in slow-growing grass speciesPlant and Soil, 215
A. Owen, Davey Jones (2001)
Competition for amino acids between wheat roots and rhizosphere microorganisms and the role of amino acids in plant N acquisitionSoil Biology & Biochemistry, 33
P. Staddon, C. Ramsey, N. Ostle, P. Ineson, A. Fitter (2003)
Rapid Turnover of Hyphae of Mycorrhizal Fungi Determined by AMS Microanalysis of 14CScience, 300
P. Rochette, L. Flanagan, E. Gregorich (1999)
Separating Soil Respiration into Plant and Soil Components Using Analyses of the Natural Abundance of Carbon‐13Soil Science Society of America Journal, 63
R. Finlay, A. Rosling (2006)
Fungi in Biogeochemical Cycles: Integrated nutrient cycles in boreal forest ecosystems – the role of mycorrhizal fungi
A. Rosling, B. Lindahl, Andy Taylor, R. Finlay (2004)
Mycelial growth and substrate acidification of ectomycorrhizal fungi in response to different minerals.FEMS microbiology ecology, 47 1
Xiaowen Zhao, M. Schmitt, M. Hawes (2000)
Species-dependent effects of border cell and root tip exudates on nematode behavior.Phytopathology, 90 11
J. Balesdent, M. Balabane (1992)
Maize root-derived soil organic carbon estimated by natural 15c abundanceSoil Biology & Biochemistry, 24
David Jones, J. Healey, V. Willett, J. Farrar, A. Hodge (2005)
Dissolved organic nitrogen uptake by plants—an important N uptake pathway?Soil Biology & Biochemistry, 37
David Jones, D. Shannon, Thippaya Junvee-Fortune, J. Farrar (2005)
Plant capture of free amino acids is maximized under high soil amino acid concentrationsSoil Biology & Biochemistry, 37
A. Quadt-Hallmann, J. Hallmann, J. Kloepper (1997)
Bacterial endophytes in cotton: location and interaction with other plant-associated bacteriaCanadian Journal of Microbiology, 43
F. Dakora, D. Phillips (2002)
Root exudates as mediators of mineral acquisition in low-nutrient environmentsPlant and Soil, 245
W. Cheng, R. Virginia (1993)
Measurement of microbial biomass in arctic tundra soils using fumigation-extraction and substrate-induced respiration proceduresSoil Biology & Biochemistry, 25
B. Lindahl, J. Stenlid, R. Finlay (2001)
Effects of resource availability on mycelial interactions and 32P transfer between a saprotrophic and an ectomycorrhizal fungus in soil microcosmsFEMS Microbiology Ecology, 38
M. Lasat (2002)
Phytoextraction of toxic metals: a review of biological mechanisms.Journal of environmental quality, 31 1
P. Hees, David Jones, R. Finlay, D. Godbold, U. Lundström (2005)
The carbon we do not see : The impact of low molecular weight compounds on carbon dynamics and respiration in forest soils - A reviewSoil Biology & Biochemistry, 37
D. Robinson, A. Fitter (1999)
The magnitude and control of carbon transfer between plants linked by a common mycorrhizal networkJournal of Experimental Botany, 50
D. Read, A. Bengough, Peter Gregory, J. Crawford, D. Robinson, C. Scrimgeour, I. Young, K. Zhang, Xiaoxian Zhang (2003)
Plant roots release phospholipid surfactants that modify the physical and chemical properties of soil.The New phytologist, 157 2
P. Andersson, D. Berggren (2005)
Amino Acids, Total Organic and Inorganic Nitrogen in Forest Floor Soil Solution at Low and High Nitrogen InputWater, Air, and Soil Pollution, 162
P. Pfeffer, D. Douds, H. Bücking, D. Schwartz, Y. Shachar-Hill (2004)
The fungus does not transfer carbon to or between roots in an arbuscular mycorrhizal symbiosis.The New phytologist, 163 3
Y. Kuzyakov (2006)
Sources of CO2 efflux from soil and review of partitioning methodsSoil Biology & Biochemistry, 38
D. Morré, Daniel Jones, H. Mollenhauer (1967)
Golgi apparatus mediated polysaccharide secretion by outer root cap cells of Zea maysPlanta, 74
A. Samuels, M. Fernando, A. Glass (1992)
Immunofluorescent Localization of Plasma Membrane H-ATPase in Barley Roots and Effects of K Nutrition.Plant physiology, 99 4
B. Singh, N. Nunan, K. Ridgway, J. McNicol, J. Young, T. Daniell, J. Prosser, P. Millard (2008)
Relationship between assemblages of mycorrhizal fungi and bacteria on grass roots.Environmental microbiology, 10 2
P. Högberg, A. Nordgren, N. Buchmann, Andrew Taylor, A. Ekblad, M. Högberg, G. Nyberg, M. Ottosson‐Löfvenius, D. Read (2001)
Large-scale forest girdling shows that current photosynthesis drives soil respirationNature, 411
U. Ahonen-Jonnarth, P. Hees, U. Lundström, R. Finlay (2000)
Organic acids produced by mycorrhizal Pinus sylvestris exposed to elevated aluminium and heavy metal concentrationsNew Phytologist, 146
A. Rovira (2008)
Plant root exudatesThe Botanical Review, 35
(1995)
Soil nutrient bioavailability
(1986)
The rhizosphere. Advanced series in agricultural science
K. Nadelhoffer, J. Raich (1992)
Fine Root Production Estimates and Belowground Carbon Allocation in Forest EcosystemsEcology, 73
J. Leake, David Johnson, D. Donnelly, G. Muckle, L. Boddy, D. Read (2004)
Networks of power and influence: the role of mycorrhizal mycelium in controlling plant communities and agroecosystem functioningBotany, 82
N. Ostle, A. Whiteley, M. Bailey, D. Sleep, P. Ineson, M. Manefield (2003)
Active microbial RNA turnover in a grassland soil estimated using a 13CO2 spikeSoil Biology & Biochemistry, 35
D. Sapronov, Y. Kuzyakov (2007)
Separation of root and microbial respiration: Comparison of three methodsEurasian Soil Science, 40
S. Rodger, A. Bengough, B. Griffiths, V. Stubbs, I. Young (2003)
Does the Presence of Detached Root Border Cells of Zea mays Alter the Activity of the Pathogenic Nematode Meloidogyne incognita?Phytopathology, 93 9
E. Paterson (2003)
Importance of rhizodeposition in the coupling of plant and microbial productivityEuropean Journal of Soil Science, 54
H. Høgh-Jensen, J. Schjoerring (2001)
Rhizodeposition of nitrogen by red clover, white clover and ryegrass leysSoil Biology & Biochemistry, 33
J. Leake, D. Donnelly, E. Saunders, L. Boddy, D. Read (2001)
Rates and quantities of carbon flux to ectomycorrhizal mycelium following 14C pulse labeling of Pinus sylvestris seedlings: effects of litter patches and interaction with a wood-decomposer fungus.Tree physiology, 21 2-3
D. Coleman, B. Fry (1991)
Carbon isotope techniques
K. Jiang, Shibo Zhang, Stanley Lee, George Tsai, Kyungpil Kim, Haiyan Huang, C. Chilcott, T. Zhu, L. Feldman (2006)
Transcription Profile Analyses Identify Genes and Pathways Central to Root Cap Functions in MaizePlant Molecular Biology, 60
M. Iijima, T. Higuchi, P. Barlow (2004)
Contribution of root cap mucilage and presence of an intact root cap in maize (Zea mays) to the reduction of soil mechanical impedance.Annals of botany, 94 3
J. Rangel-Castro, K. Killham, N. Ostle, G. Nicol, I. Anderson, C. Scrimgeour, P. Ineson, A. Meharg, J. Prosser (2005)
Stable isotope probing analysis of the influence of liming on root exudate utilization by soil microorganisms.Environmental microbiology, 7 6
D. Phillips, T. Fox, M. King, T. Bhuvaneswari, L. Teuber (2004)
Microbial Products Trigger Amino Acid Exudation from Plant Roots1Plant Physiology, 136
P. Tinker, P. Nye (2000)
Solute Movement in the Rhizosphere
M. Brown (1972)
Plant growth substances produced by micro‐organisms of soil and rhizosphereJournal of Applied Microbiology, 35
J. Swinnen, J. Veen, R. Merckx (1995)
Root decay and turnover of rhizodeposits in field-grown winter wheat and spring barley estimated by 14C pulse-labellingSoil Biology & Biochemistry, 27
S. Sherson, H. Alford, Susan Forbes, G. Wallace, Steven M. L. Smith (2003)
Roles of cell-wall invertases and monosaccharide transporters in the growth and development of Arabidopsis.Journal of experimental botany, 54 382
J. Toljander, Veronica Artursson, L. Paul, J. Jansson, R. Finlay (2006)
Attachment of different soil bacteria to arbuscular mycorrhizal fungal extraradical hyphae is determined by hyphal vitality and fungal species.FEMS microbiology letters, 254 1
E. Jensen (1996)
Rhizodeposition of N by pea and barley and its effect on soil N dynamicsSoil Biology & Biochemistry, 28
Y. Kuzyakov, G. Domański (2000)
Carbon input by plants into the soil. Review.Journal of Plant Nutrition and Soil Science, 163
E. Paterson, T. Gebbing, C. Abel, A. Sim, G. Telfer (2007)
Rhizodeposition shapes rhizosphere microbial community structure in organic soil.The New phytologist, 173 3
Uvini Gunawardena, M. Hawes (2002)
Tissue specific localization of root infection by fungal pathogens: role of root border cells.Molecular plant-microbe interactions : MPMI, 15 11
A. Bockenhoff, D. Prior, FMW. Grundler, K. Oparka (1996)
Induction of Phloem Unloading in Arabidopsis thaliana Roots by the Parasitic Nematode Heterodera schachtii, 112
B. Thornton, E. Paterson, A. Midwood, A. Sim, S. Pratt (2004)
Contribution of current carbon assimilation in supplying root exudates of Lolium perenne measured using steady-state C labelling.Physiologia plantarum, 120 3
V. Sobolev, T. Potter, B. Horn (2006)
Prenylated stilbenes from peanut root mucilage.Phytochemical analysis : PCA, 17 5
M. Bidartondo (2005)
The evolutionary ecology of myco-heterotrophy.The New phytologist, 167 2
S. Akao (1991)
Nitrogen Fixation and Metabolism in Soybean PlantsJarq-japan Agricultural Research Quarterly, 25
Wen‐Hao Zhang, P. Ryan, S. Tyerman (2004)
Citrate-Permeable Channels in the Plasma Membrane of Cluster Roots from White Lupin1Plant Physiology, 136
D. Read, Peter Gregory (1997)
Surface tension and viscosity of axenic maize and lupin root mucilagesNew Phytologist, 137
J. Toljander, B. Lindahl, L. Paul, M. Elfstrand, R. Finlay (2007)
Influence of arbuscular mycorrhizal mycelial exudates on soil bacterial growth and community structure.FEMS microbiology ecology, 61 2
P. Hinsinger, A. Bengough, D. Vetterlein, I. Young (2009)
Rhizosphere: biophysics, biogeochemistry and ecological relevancePlant and Soil, 321
W. Fischer, B. André, D. Rentsch, Sylvia Krolkiewicz, M. Tegeder, K. Breitkreuz, W. Frommer (1998)
Amino acid transport in plantsTrends in Plant Science, 3
M. Mccully (1999)
ROOTS IN SOIL: Unearthing the Complexities of Roots and Their Rhizospheres.Annual review of plant physiology and plant molecular biology, 50
The loss of organic and inorganic carbon from roots into soil underpins nearly all the major changes that occur in the rhizosphere. In this review we explore the mechanistic basis of organic carbon and nitrogen flow in the rhizosphere. It is clear that C and N flow in the rhizosphere is extremely complex, being highly plant and environment dependent and varying both spatially and temporally along the root. Consequently, the amount and type of rhizodeposits (e.g. exudates, border cells, mucilage) remains highly context specific. This has severely limited our capacity to quantify and model the amount of rhizodeposition in ecosystem processes such as C sequestration and nutrient acquisition. It is now evident that C and N flow at the soil–root interface is bidirectional with C and N being lost from roots and taken up from the soil simultaneously. Here we present four alternative hypotheses to explain why high and low molecular weight organic compounds are actively cycled in the rhizosphere. These include: (1) indirect, fortuitous root exudate recapture as part of the root’s C and N distribution network, (2) direct re-uptake to enhance the plant’s C efficiency and to reduce rhizosphere microbial growth and pathogen attack, (3) direct uptake to recapture organic nutrients released from soil organic matter, and (4) for inter-root and root–microbial signal exchange. Due to severe flaws in the interpretation of commonly used isotopic labelling techniques, there is still great uncertainty surrounding the importance of these individual fluxes in the rhizosphere. Due to the importance of rhizodeposition in regulating ecosystem functioning, it is critical that future research focuses on resolving the quantitative importance of the different C and N fluxes operating in the rhizosphere and the ways in which these vary spatially and temporally.
Plant and Soil – Springer Journals
Published: Aug 1, 2009
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