It's time to make changes: modulation of root system architecture by nutrient signals.

Root growth and development are of outstanding importance for the plant's ability to acquire water and nutrients from different soil horizons. To cope with fluctuating nutrient availabilities, plants integrate systemic signals pertaining to their nutritional status into developmental pathways that regulate the spatial arrangement of roots. Changes in the plant nutritional status and external nutrient supply modulate root system architecture (RSA) over time and determine the degree of root plasticity which is based on variations in the number, extension, placement, and growth direction of individual components of the root system. Roots also sense the local availability of some nutrients, thereby leading to nutrient-specific modifications in RSA, that result from the integration of systemic and local signals into the root developmental programme at specific steps. An in silico analysis of nutrient-responsive genes involved in root development showed that the majority of these specifically responded to the deficiency of individual nutrients while a minority responded to more than one nutrient deficiency. Such an analysis provides an interesting starting point for the identification of the molecular players underlying the sensing and transduction of the nutrient signals that mediate changes in the development and architecture of root systems.

[1]  G. Krouk,et al.  Nitrate signaling: adaptation to fluctuating environments. , 2010, Current opinion in plant biology.

[2]  Guohua Yang,et al.  A negative regulatory role for auxin in sulphate deficiency response in Arabidopsis thaliana , 2006, Plant Molecular Biology.

[3]  J. Chory,et al.  The Arabidopsis det3 mutant reveals a central role for the vacuolar H(+)-ATPase in plant growth and development. , 1999, Genes & development.

[4]  P. Zimmermann,et al.  GENEVESTIGATOR. Arabidopsis Microarray Database and Analysis Toolbox1[w] , 2004, Plant Physiology.

[5]  Renze Heidstra,et al.  PLETHORA proteins as dose-dependent master regulators of Arabidopsis root development , 2007, Nature.

[6]  Renze Heidstra,et al.  Cytokinins Determine Arabidopsis Root-Meristem Size by Controlling Cell Differentiation , 2007, Current Biology.

[7]  L. Herrera-Estrella,et al.  Phosphate Availability Alters Lateral Root Development in Arabidopsis by Modulating Auxin Sensitivity via a Mechanism Involving the TIR1 Auxin Receptor[C][W][OA] , 2008, The Plant Cell Online.

[8]  J. Reed,et al.  Control of auxin-regulated root development by the Arabidopsis thaliana SHY2/IAA3 gene. , 1999, Development.

[9]  M. Fuentes,et al.  Auxin: a major player in the shoot-to-root regulation of root Fe-stress physiological responses to Fe deficiency in cucumber plants. , 2011, Plant physiology and biochemistry : PPB.

[10]  P. B. Tinker,et al.  Solute Movement in the Rhizosphere , 2000 .

[11]  M. Estelle,et al.  The IAA1 protein is encoded by AXR5 and is a substrate of SCF(TIR1). , 2004, The Plant journal : for cell and molecular biology.

[12]  Daniel R. Lewis,et al.  Mutations in Arabidopsis Multidrug Resistance-Like ABC Transporters Separate the Roles of Acropetal and Basipetal Auxin Transport in Lateral Root Development[W][OA] , 2007, The Plant Cell Online.

[13]  I. Burns Short‐ and long‐term effects of a change in the spatial distribution of nitrate in the root zone on N uptake, growth and root development of young lettuce plants , 1991 .

[14]  Ariel Novoplansky,et al.  Developmental plasticity in plants: implications of non-cognitive behavior , 2002, Evolutionary Ecology.

[15]  J. G. Dubrovsky,et al.  Auxin acts as a local morphogenetic trigger to specify lateral root founder cells , 2008, Proceedings of the National Academy of Sciences.

[16]  N. von Wirén,et al.  Localized Iron Supply Triggers Lateral Root Elongation in Arabidopsis by Altering the AUX1-Mediated Auxin Distribution[C][W][OA] , 2012, Plant Cell.

[17]  P. Benfey,et al.  Spatiotemporal regulation of cell-cycle genes by SHORTROOT links patterning and growth , 2010, Nature.

[18]  Philip N Benfey,et al.  The SHORT-ROOT Gene Controls Radial Patterning of the Arabidopsis Root through Radial Signaling , 2000, Cell.

[19]  Rehema M. White,et al.  Frequency distributions and spatially dependent variability of ammonium and nitrate concentrations in soil under grazed and ungrazed grassland , 1987, Fertilizer research.

[20]  R. B. Jackson,et al.  The timing and degree of root proliferation in fertile-soil microsites for three cold-desert perennials , 1989, Oecologia.

[21]  I. Burns INFLUENCE OF THE SPATIAL DISTRIBUTION OF NITRATE ON THE UPTAKE OF N BY PLANTS: A REVIEW AND A MODEL FOR ROOTING DEPTH , 1980 .

[22]  S. Chaillou,et al.  Plant response to nitrate starvation is determined by N storage capacity matched by nitrate uptake capacity in two Arabidopsis genotypes. , 2008, Journal of experimental botany.

[23]  P. Hogeweg,et al.  Root System Architecture from Coupling Cell Shape to Auxin Transport , 2008, PLoS biology.

[24]  Tom Beeckman,et al.  Auxin-dependent regulation of lateral root positioning in the basal meristem of Arabidopsis , 2007, Development.

[25]  Jonathan P Lynch,et al.  Steep, cheap and deep: an ideotype to optimize water and N acquisition by maize root systems. , 2013, Annals of botany.

[26]  Takashi Aoyama,et al.  A Genetic Framework for the Control of Cell Division and Differentiation in the Root Meristem , 2008, Science.

[27]  B. Forde,et al.  The nutritional control of root development , 2001 .

[28]  Swetlana Friedel,et al.  Plasticity of the Arabidopsis Root System under Nutrient Deficiencies1[C][W][OPEN] , 2013, Plant Physiology.

[29]  Jonathan P. Lynch,et al.  Roots of the Second Green Revolution , 2007 .

[30]  Wei Wei Chen,et al.  Nitric Oxide Acts Downstream of Auxin to Trigger Root Ferric-Chelate Reductase Activity in Response to Iron Deficiency in Arabidopsis1[C][W][OA] , 2010, Plant Physiology.

[31]  Fumihiko Sato,et al.  PGP4, an ATP Binding Cassette P-Glycoprotein, Catalyzes Auxin Transport in Arabidopsis thaliana Rootsw⃞ , 2005, The Plant Cell Online.

[32]  Christian Hermans,et al.  How do plants respond to nutrient shortage by biomass allocation? , 2006, Trends in plant science.

[33]  T. Goh,et al.  The establishment of asymmetry in Arabidopsis lateral root founder cells is regulated by LBD16/ASL18 and related LBD/ASL proteins , 2012, Development.

[34]  Tom Beeckman,et al.  The auxin influx carrier LAX3 promotes lateral root emergence , 2008, Nature Cell Biology.

[35]  I. Smet Lateral root initiation: one step at a time , 2012 .

[36]  P. Tillard,et al.  The Arabidopsis NRT1.1 transporter participates in the signaling pathway triggering root colonization of nitrate-rich patches , 2006, Proceedings of the National Academy of Sciences.

[37]  D J Cosgrove,et al.  Expansive growth of plant cell walls. , 2000, Plant physiology and biochemistry : PPB.

[38]  M. Drew,et al.  COMPARISON OF THE EFFECTS OF A LOCALISED SUPPLY OF PHOSPHATE, NITRATE, AMMONIUM AND POTASSIUM ON THE GROWTH OF THE SEMINAL ROOT SYSTEM, AND THE SHOOT, IN BARLEY , 1975 .

[39]  X. Draye,et al.  Root system architecture: opportunities and constraints for genetic improvement of crops. , 2007, Trends in plant science.

[40]  J. Mullen,et al.  Genetic analysis of the gravitropic set-point angle in lateral roots of Arabidopsis. , 2003, Advances in space research : the official journal of the Committee on Space Research.

[41]  J. Malamy,et al.  Intrinsic and environmental response pathways that regulate root system architecture. , 2005, Plant, cell & environment.

[42]  L. Herrera-Estrella,et al.  Phosphate starvation induces a determinate developmental program in the roots of Arabidopsis thaliana. , 2005, Plant & cell physiology.

[43]  Fabian Kellermeier,et al.  Natural Variation of Arabidopsis Root Architecture Reveals Complementing Adaptive Strategies to Potassium Starvation1[C][W][OA] , 2013, Plant Physiology.

[44]  J. Lynch,et al.  Topsoil foraging – an architectural adaptation of plants to low phosphorus availability , 2001, Plant and Soil.

[45]  A. Theologis,et al.  Tissue-specific expression of stabilized SOLITARY-ROOT/IAA14 alters lateral root development in Arabidopsis. , 2005, The Plant journal : for cell and molecular biology.

[46]  C. Curie,et al.  High-Affinity Manganese Uptake by the Metal Transporter NRAMP1 Is Essential for Arabidopsis Growth in Low Manganese Conditions[C][W] , 2010, Plant Cell.

[47]  Gabriel Krouk,et al.  Nitrate-regulated auxin transport by NRT1.1 defines a mechanism for nutrient sensing in plants. , 2010, Developmental cell.

[48]  J. Lynch,et al.  Topsoil foraging and phosphorus acquisition efficiency in maize (Zea mays). , 2005, Functional plant biology : FPB.

[49]  J. Lynch Root Architecture and Plant Productivity , 1995, Plant physiology.

[50]  C. Dean,et al.  Embryonic origin of the Arabidopsis primary root and root meristem initials , 1994 .

[51]  H. Leyser,et al.  Phosphate availability regulates root system architecture in Arabidopsis. , 2001, Plant physiology.

[52]  L. Herrera-Estrella,et al.  The role of nutrient availability in regulating root architecture. , 2003, Current opinion in plant biology.

[53]  Guislaine Refregier,et al.  PROCUSTE1 Encodes a Cellulose Synthase Required for Normal Cell Elongation Specifically in Roots and Dark-Grown Hypocotyls of Arabidopsis , 2000, Plant Cell.

[54]  P W Barlow,et al.  Dual pathways for regulation of root branching by nitrate. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[55]  P. Benfey,et al.  Oscillating Gene Expression Determines Competence for Periodic Arabidopsis Root Branching , 2010, Science.

[56]  K. Palme,et al.  Arabidopsis ASA1 Is Important for Jasmonate-Mediated Regulation of Auxin Biosynthesis and Transport during Lateral Root Formation[W][OA] , 2009, The Plant Cell Online.

[57]  Zheng-Hui He,et al.  Antisense Expression of a Cell Wall–Associated Protein Kinase, WAK4, Inhibits Cell Elongation and Alters Morphology , 2001, The Plant Cell Online.

[58]  D. Inzé,et al.  Receptor-Like Kinase ACR4 Restricts Formative Cell Divisions in the Arabidopsis Root , 2008, Science.

[59]  C. Ticconi,et al.  ER-resident proteins PDR2 and LPR1 mediate the developmental response of root meristems to phosphate availability , 2009, Proceedings of the National Academy of Sciences.

[60]  N. von Wirén,et al.  Ammonium Triggers Lateral Root Branching in Arabidopsis in an AMMONIUM TRANSPORTER1;3-Dependent Manner[W] , 2010, Plant Cell.

[61]  Jan Petrásek,et al.  Cytokinin regulates root meristem activity via modulation of the polar auxin transport , 2009, Proceedings of the National Academy of Sciences.

[62]  I. Desmet,et al.  Lateral root initiation: one step at a time. , 2012, The New phytologist.

[63]  G. Fink,et al.  A pathway for lateral root formation in Arabidopsis thaliana. , 1995, Genes & development.

[64]  H. Leyser,et al.  Nitrate and phosphate availability and distribution have different effects on root system architecture of Arabidopsis. , 2002, The Plant journal : for cell and molecular biology.

[65]  B. Griffiths,et al.  Plant root proliferation in nitrogen–rich patches confers competitive advantage , 1999, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[66]  E. Benková,et al.  An Auxin Transport Mechanism Restricts Positive Orthogravitropism in Lateral Roots , 2013, Current Biology.

[67]  T. Baskin,et al.  Analysis of cell division and elongation underlying the developmental acceleration of root growth in Arabidopsis thaliana. , 1998, Plant physiology.

[68]  S. Sabatini,et al.  SCARECROW is involved in positioning the stem cell niche in the Arabidopsis root meristem. , 2003, Genes & development.

[69]  W. Horst,et al.  Root growth and nitrate utilization of maize cultivars under field conditions , 1994, Plant and Soil.

[70]  Philip N Benfey,et al.  Control of Arabidopsis root development. , 2012, Annual review of plant biology.

[71]  H. Fukaki,et al.  The Auxin-Regulated AP2/EREBP Gene PUCHI Is Required for Morphogenesis in the Early Lateral Root Primordium of Arabidopsis[W] , 2007, The Plant Cell Online.

[72]  A. Theologis,et al.  ARF7 and ARF19 Regulate Lateral Root Formation via Direct Activation of LBD/ASL Genes in Arabidopsis[W] , 2007, The Plant Cell Online.

[73]  Teva Vernoux,et al.  An Evolutionarily Conserved Mechanism Delimiting SHR Movement Defines a Single Layer of Endodermis in Plants , 2007, Science.

[74]  D. Schachtman,et al.  Ethylene Mediates Response and Tolerance to Potassium Deprivation in Arabidopsis[W] , 2009, The Plant Cell Online.

[75]  G. McNickle,et al.  Plant root growth and the marginal value theorem , 2009, Proceedings of the National Academy of Sciences.

[76]  Tom Beeckman,et al.  Arabidopsis lateral root development: an emerging story. , 2009, Trends in plant science.

[77]  D. Schachtman Recent advances in nutrient sensing and signaling. , 2012, Molecular Plant.

[78]  B. Lahner,et al.  The Effect of Iron on the Primary Root Elongation of Arabidopsis during Phosphate Deficiency1[W][OA] , 2008, Plant Physiology.

[79]  D. Robinson The responses of plants to non-uniform supplies of nutrients. , 1994, The New phytologist.

[80]  N. von Wirén,et al.  Regulatory components involved in altering lateral root development in response to localized iron: Evidence for natural genetic variation , 2012, Plant signaling & behavior.

[81]  R. Amasino,et al.  The PLETHORA Genes Mediate Patterning of the Arabidopsis Root Stem Cell Niche , 2004, Cell.

[82]  L. Saker,et al.  Nutrient Supply and the Growth of the Seminal Root System in Barley II. LOCALIZED, COMPENSATORY INCREASES IN LATERAL ROOT GROWTH AND RATES OP NITRATE UPTAKE WHEN NITRATE SUPPLY IS RESTRICTED TO ONLY PART OF THE ROOT SYSTEM , 1975 .

[83]  G. Wilkerson,et al.  Respiration rate in maize roots is related to concentration of reduced nitrogen and proliferation of lateral roots. , 1989, Physiologia plantarum.

[84]  B. Forde,et al.  An Arabidopsis MADS box gene that controls nutrient-induced changes in root architecture. , 1998, Science.

[85]  R. Gutiérrez,et al.  Integration of local and systemic signaling pathways for plant N responses. , 2012, Current opinion in plant biology.

[86]  Alastair Fitter,et al.  Why plants bother: root proliferation results in increased nitrogen capture from an organic patch when two grasses compete , 1999 .

[87]  Luis Herrera-Estrella,et al.  Phosphate Availability Alters Architecture and Causes Changes in Hormone Sensitivity in the Arabidopsis Root System1 , 2002, Plant Physiology.

[88]  Topsoil foraging and its role in plant competitiveness for phosphorus in common bean , 2003 .

[89]  D. Inzé,et al.  Auxin Transport Promotes Arabidopsis Lateral Root Initiation , 2001, Plant Cell.

[90]  C. Hermans,et al.  Physiological characterization of Mg deficiency in Arabidopsis thaliana. , 2005, Journal of experimental botany.

[91]  H. Fukaki,et al.  Hormone interactions during lateral root formation , 2009, Plant Molecular Biology.

[92]  Ottoline Leyser,et al.  An Auxin-Dependent Distal Organizer of Pattern and Polarity in the Arabidopsis Root , 1999, Cell.

[93]  A. Müller,et al.  A role for nitrilase 3 in the regulation of root morphology in sulphur-starving Arabidopsis thaliana. , 2002, The Plant journal : for cell and molecular biology.

[94]  Karen S. Osmont,et al.  Hidden branches: developments in root system architecture. , 2007, Annual review of plant biology.