Your search keyword '"Swarup, Ranjan"' showing total 36 results

1. Hydraulic flux-responsive hormone redistribution determines root branching.

Author

Mehra P, Pandey BK, Melebari D, Banda J, Leftley N, Couvreur V, Rowe J, Anfang M, De Gernier H, Morris E, Sturrock CJ, Mooney SJ, Swarup R, Faulkner C, Beeckman T, Bhalerao RP, Shani E, Jones AM, Dodd IC, Sharp RE, Sadanandom A, Draye X, and Bennett MJ

Subjects

Soil, Plasmodesmata metabolism, Arabidopsis growth & development, Arabidopsis metabolism, Abscisic Acid metabolism, Plant Roots growth & development, Water metabolism, Plant Growth Regulators, Phloem metabolism, Indoleacetic Acids metabolism

Abstract

Plant roots exhibit plasticity in their branching patterns to forage efficiently for heterogeneously distributed resources, such as soil water. The xerobranching response represses lateral root formation when roots lose contact with water. Here, we show that xerobranching is regulated by radial movement of the phloem-derived hormone abscisic acid, which disrupts intercellular communication between inner and outer cell layers through plasmodesmata. Closure of these intercellular pores disrupts the inward movement of the hormone signal auxin, blocking lateral root branching. Once root tips regain contact with moisture, the abscisic acid response rapidly attenuates. Our study reveals how roots adapt their branching pattern to heterogeneous soil water conditions by linking changes in hydraulic flux with dynamic hormone redistribution.

Published

2022

2. Root angle is controlled by EGT1 in cereal crops employing an antigravitropic mechanism.

Author

Fusi R, Rosignoli S, Lou H, Sangiorgi G, Bovina R, Pattem JK, Borkar AN, Lombardi M, Forestan C, Milner SG, Davis JL, Lale A, Kirschner GK, Swarup R, Tassinari A, Pandey BK, York LM, Atkinson BS, Sturrock CJ, Mooney SJ, Hochholdinger F, Tucker MR, Himmelbach A, Stein N, Mascher M, Nagel KA, De Gara L, Simmonds J, Uauy C, Tuberosa R, Lynch JP, Yakubov GE, Bennett MJ, Bhosale R, and Salvi S

Subjects

Cell Wall chemistry, Microscopy, Atomic Force, Reactive Oxygen Species metabolism, Transcription, Genetic, Crops, Agricultural chemistry, Crops, Agricultural genetics, Crops, Agricultural growth & development, Gravitropism genetics, Hordeum chemistry, Hordeum genetics, Hordeum growth & development, Plant Proteins genetics, Plant Proteins physiology, Plant Roots chemistry, Plant Roots genetics, Plant Roots growth & development

Abstract

Root angle in crops represents a key trait for efficient capture of soil resources. Root angle is determined by competing gravitropic versus antigravitropic offset (AGO) mechanisms. Here we report a root angle regulatory gene termed ENHANCED GRAVITROPISM1 ( EGT1 ) that encodes a putative AGO component, whose loss-of-function enhances root gravitropism. Mutations in barley and wheat EGT1 genes confer a striking root phenotype, where every root class adopts a steeper growth angle. EGT1 encodes an F-box and Tubby domain-containing protein that is highly conserved across plant species. Haplotype analysis found that natural allelic variation at the barley EGT1 locus impacts root angle. Gravitropic assays indicated that Hvegt1 roots bend more rapidly than wild-type. Transcript profiling revealed Hvegt1 roots deregulate reactive oxygen species (ROS) homeostasis and cell wall-loosening enzymes and cofactors. ROS imaging shows that Hvegt1 root basal meristem and elongation zone tissues have reduced levels. Atomic force microscopy measurements detected elongating Hvegt1 root cortical cell walls are significantly less stiff than wild-type. In situ analysis identified HvEGT1 is expressed in elongating cortical and stele tissues, which are distinct from known root gravitropic perception and response tissues in the columella and epidermis, respectively. We propose that EGT1 controls root angle by regulating cell wall stiffness in elongating root cortical tissue, counteracting the gravitropic machinery's known ability to bend the root via its outermost tissues. We conclude that root angle is controlled by EGT1 in cereal crops employing an antigravitropic mechanism.

Published

2022

3. Role of cis-zeatin in root responses to phosphate starvation.

Author

Silva-Navas J, Conesa CM, Saez A, Navarro-Neila S, Garcia-Mina JM, Zamarreño AM, Baigorri R, Swarup R, and Del Pozo JC

Subjects

Arabidopsis drug effects, Arabidopsis metabolism, Arabidopsis radiation effects, Cell Proliferation drug effects, Cell Proliferation radiation effects, Gene Expression Regulation, Plant drug effects, Gene Expression Regulation, Plant radiation effects, Light, Plant Growth Regulators pharmacology, Plant Roots drug effects, Plant Roots growth & development, Plant Roots radiation effects, Plant Shoots drug effects, Plant Shoots metabolism, Plant Shoots radiation effects, Zeatin pharmacology, Phosphates deficiency, Plant Roots metabolism, Zeatin metabolism

Abstract

Phosphate (Pi) is an essential nutrient for all organisms. Roots are underground organs, but the majority of the root biology studies have been done on root systems growing in the presence of light. Root illumination alters the Pi starvation response (PSR) at different intensities. Thus, we have analyzed morphological, transcriptional and physiological responses to Pi starvation in dark-grown roots. We have identified new genes and pathways regulated by Pi starvation that were not described previously. We also show that Pi-starved plants increase the cis-zeatin (cZ) : trans-zeatin (tZ) ratio. Transcriptomic analyses show that tZ preferentially represses cell cycle and PSR genes, whereas cZ induces genes involved in cell and root hair elongation and differentiation. In fact, cZ-treated seedlings show longer root system as well as longer root hairs compared with tZ-treated seedlings, increasing the total absorbing surface. Mutants with low cZ concentrations do not allocate free Pi in roots during Pi starvation. We propose that Pi-starved plants increase the cZ : tZ ratio to maintain basal cytokinin responses and allocate Pi in the root system to sustain its growth. Therefore, cZ acts as a PSR hormone that stimulates root and root hair elongation to enlarge the root absorbing surface and to increase Pi concentrations in roots., (© 2019 The Authors. New Phytologist © 2019 New Phytologist Trust.)

Published

2019

4. Rice auxin influx carrier OsAUX1 facilitates root hair elongation in response to low external phosphate.

Author

Giri J, Bhosale R, Huang G, Pandey BK, Parker H, Zappala S, Yang J, Dievart A, Bureau C, Ljung K, Price A, Rose T, Larrieu A, Mairhofer S, Sturrock CJ, White P, Dupuy L, Hawkesford M, Perin C, Liang W, Peret B, Hodgman CT, Lynch J, Wissuwa M, Zhang D, Pridmore T, Mooney SJ, Guiderdoni E, Swarup R, and Bennett MJ

Subjects

Gravitropism physiology, Indoleacetic Acids metabolism, Membrane Transport Proteins genetics, Membrane Transport Proteins metabolism, Organogenesis, Plant genetics, Oryza genetics, Oryza growth & development, Oryza metabolism, Phosphates deficiency, Plant Growth Regulators metabolism, Plant Roots genetics, Plant Roots growth & development, Plant Roots metabolism, Plants, Genetically Modified, Stress, Physiological, Gene Expression Regulation, Plant, Organogenesis, Plant drug effects, Oryza drug effects, Phosphates pharmacology, Plant Roots drug effects

Abstract

Root traits such as root angle and hair length influence resource acquisition particularly for immobile nutrients like phosphorus (P). Here, we attempted to modify root angle in rice by disrupting the OsAUX1 auxin influx transporter gene in an effort to improve rice P acquisition efficiency. We show by X-ray microCT imaging that root angle is altered in the osaux1 mutant, causing preferential foraging in the top soil where P normally accumulates, yet surprisingly, P acquisition efficiency does not improve. Through closer investigation, we reveal that OsAUX1 also promotes root hair elongation in response to P limitation. Reporter studies reveal that auxin response increases in the root hair zone in low P environments. We demonstrate that OsAUX1 functions to mobilize auxin from the root apex to the differentiation zone where this signal promotes hair elongation when roots encounter low external P. We conclude that auxin and OsAUX1 play key roles in promoting root foraging for P in rice.

Published

2018

5. A mechanistic framework for auxin dependent Arabidopsis root hair elongation to low external phosphate.

Author

Bhosale R, Giri J, Pandey BK, Giehl RFH, Hartmann A, Traini R, Truskina J, Leftley N, Hanlon M, Swarup K, Rashed A, Voß U, Alonso J, Stepanova A, Yun J, Ljung K, Brown KM, Lynch JP, Dolan L, Vernoux T, Bishopp A, Wells D, von Wirén N, Bennett MJ, and Swarup R

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Gravitropism physiology, Indoleacetic Acids metabolism, Organogenesis, Plant genetics, Phosphates deficiency, Plant Growth Regulators metabolism, Plant Roots genetics, Plant Roots growth & development, Plant Roots metabolism, Plants, Genetically Modified, Stress, Physiological, Transcription Factors genetics, Transcription Factors metabolism, Arabidopsis drug effects, Arabidopsis Proteins genetics, Gene Expression Regulation, Plant, Organogenesis, Plant drug effects, Phosphates pharmacology, Plant Roots drug effects

Abstract

Phosphate (P) is an essential macronutrient for plant growth. Roots employ adaptive mechanisms to forage for P in soil. Root hair elongation is particularly important since P is immobile. Here we report that auxin plays a critical role promoting root hair growth in Arabidopsis in response to low external P. Mutants disrupting auxin synthesis (taa1) and transport (aux1) attenuate the low P root hair response. Conversely, targeting AUX1 expression in lateral root cap and epidermal cells rescues this low P response in aux1. Hence auxin transport from the root apex to differentiation zone promotes auxin-dependent hair response to low P. Low external P results in induction of root hair expressed auxin-inducible transcription factors ARF19, RSL2, and RSL4. Mutants lacking these genes disrupt the low P root hair response. We conclude auxin synthesis, transport and response pathway components play critical roles regulating this low P root adaptive response.

Published

2018

6. The Auxin-Regulated CrRLK1L Kinase ERULUS Controls Cell Wall Composition during Root Hair Tip Growth.

Author

Schoenaers S, Balcerowicz D, Breen G, Hill K, Zdanio M, Mouille G, Holman TJ, Oh J, Wilson MH, Nikonorova N, Vu LD, De Smet I, Swarup R, De Vos WH, Pintelon I, Adriaensen D, Grierson C, Bennett MJ, and Vissenberg K

Subjects

Arabidopsis growth & development, Catharanthus metabolism, Cell Differentiation, Cell Wall chemistry, Cell Wall genetics, Indoleacetic Acids metabolism, Organogenesis, Plant genetics, Plant Growth Regulators metabolism, Plant Proteins metabolism, Plant Roots genetics, Plants, Genetically Modified genetics, Plants, Genetically Modified growth & development, Arabidopsis genetics, Catharanthus genetics, Gene Expression Regulation, Plant, Plant Proteins genetics, Plant Roots growth & development

Abstract

Root hairs facilitate a plant's ability to acquire soil anchorage and nutrients. Root hair growth is regulated by the plant hormone auxin and dependent on localized synthesis, secretion, and modification of the root hair tip cell wall. However, the exact cell wall regulators in root hairs controlled by auxin have yet to be determined. In this study, we describe the characterization of ERULUS (ERU), an auxin-induced Arabidopsis receptor-like kinase, whose expression is directly regulated by ARF7 and ARF19 transcription factors. ERU belongs to the Catharanthus roseus RECEPTOR-LIKE KINASE 1-LIKE (CrRLK1L) subfamily of putative cell wall sensor proteins. Imaging of a fluorescent fusion protein revealed that ERU is localized to the apical root hair plasma membrane. ERU regulates cell wall composition in root hairs and modulates pectin dynamics through negative control of pectin methylesterase (PME) activity. Mutant eru (-/-) root hairs accumulate de-esterified homogalacturonan and exhibit aberrant pectin Ca 2+ -binding site oscillations and increased PME activity. Up to 80% of the eru root hair phenotype is rescued by pharmacological supplementation with a PME-inhibiting catechin extract. ERU transcription is altered in specific cell wall-related root hair mutants, suggesting that it is a target for feedback regulation. Loss of ERU alters the phosphorylation status of FERONIA and H + -ATPases 1/2, regulators of apoplastic pH. Furthermore, H + -ATPases 1/2 and ERU are differentially phosphorylated in response to auxin. We conclude that ERULUS is a key auxin-controlled regulator of cell wall composition and pectin dynamics during root hair tip growth., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

7. Root Gravitropism: Quantification, Challenges, and Solutions.

Author

Muller L, Bennett MJ, French A, Wells DM, and Swarup R

Subjects

Arabidopsis anatomy & histology, Arabidopsis enzymology, Phenotype, Plant Roots anatomy & histology, Gravitropism, Plant Roots growth & development

Abstract

Better understanding of root traits such as root angle and root gravitropism will be crucial for development of crops with improved resource use efficiency. This chapter describes a high-throughput, automated image analysis method to trace Arabidopsis (Arabidopsis thaliana) seedling roots grown on agar plates. The method combines a "particle-filtering algorithm with a graph-based method" to trace the center line of a root and can be adopted for the analysis of several root parameters such as length, curvature, and stimulus from original root traces.

Published

2018

8. Cytokinin acts through the auxin influx carrier AUX1 to regulate cell elongation in the root.

Author

Street IH, Mathews DE, Yamburkenko MV, Sorooshzadeh A, John RT, Swarup R, Bennett MJ, Kieber JJ, and Schaller GE

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Arabidopsis metabolism, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Benzyl Compounds pharmacology, Biological Transport drug effects, Biological Transport genetics, Cell Proliferation drug effects, Cell Proliferation genetics, Cytokinins metabolism, DNA-Binding Proteins genetics, Ethylenes pharmacology, Gene Expression Regulation, Plant drug effects, Plant Growth Regulators pharmacology, Plant Roots drug effects, Plant Roots genetics, Plant Roots metabolism, Plants, Genetically Modified, Purines pharmacology, Arabidopsis Proteins physiology, Cytokinins physiology, Indoleacetic Acids metabolism, Plant Roots growth & development

Abstract

Hormonal interactions are crucial for plant development. In Arabidopsis, cytokinins inhibit root growth through effects on cell proliferation and cell elongation. Here, we define key mechanistic elements in a regulatory network by which cytokinin inhibits root cell elongation in concert with the hormones auxin and ethylene. The auxin importer AUX1 functions as a positive regulator of cytokinin responses in the root; mutation of AUX1 specifically affects the ability of cytokinin to inhibit cell elongation but not cell proliferation. AUX1 is required for cytokinin-dependent changes of auxin activity in the lateral root cap associated with the control of cell elongation. Cytokinin regulates root cell elongation through ethylene-dependent and -independent mechanisms, both hormonal signals converging on AUX1 as a regulatory hub. An autoregulatory circuit is identified involving the control of ARR10 and AUX1 expression by cytokinin and auxin, this circuit potentially functioning as an oscillator to integrate the effects of these two hormones. Taken together, our results uncover several regulatory circuits controlling interactions of cytokinin with auxin and ethylene, and support a model in which cytokinin regulates shootward auxin transport to control cell elongation and root growth., Competing Interests: The authors declare no competing or financial interests., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

9. Lateral root emergence in Arabidopsis is dependent on transcription factor LBD29 regulation of auxin influx carrier LAX3.

Author

Porco S, Larrieu A, Du Y, Gaudinier A, Goh T, Swarup K, Swarup R, Kuempers B, Bishopp A, Lavenus J, Casimiro I, Hill K, Benkova E, Fukaki H, Brady SM, Scheres B, Péret B, and Bennett MJ

Subjects

Arabidopsis Proteins genetics, Gene Expression Regulation, Plant genetics, Gene Expression Regulation, Plant physiology, Membrane Transport Proteins genetics, Signal Transduction genetics, Signal Transduction physiology, Transcription Factors genetics, Arabidopsis metabolism, Arabidopsis physiology, Arabidopsis Proteins metabolism, Indoleacetic Acids metabolism, Membrane Transport Proteins metabolism, Plant Roots metabolism, Plant Roots physiology, Transcription Factors metabolism

Abstract

Lateral root primordia (LRP) originate from pericycle stem cells located deep within parental root tissues. LRP emerge through overlying root tissues by inducing auxin-dependent cell separation and hydraulic changes in adjacent cells. The auxin-inducible auxin influx carrier LAX3 plays a key role concentrating this signal in cells overlying LRP. Delimiting LAX3 expression to two adjacent cell files overlying new LRP is crucial to ensure that auxin-regulated cell separation occurs solely along their shared walls. Multiscale modeling has predicted that this highly focused pattern of expression requires auxin to sequentially induce auxin efflux and influx carriers PIN3 and LAX3, respectively. Consistent with model predictions, we report that auxin-inducible LAX3 expression is regulated indirectly by AUXIN RESPONSE FACTOR 7 (ARF7). Yeast one-hybrid screens revealed that the LAX3 promoter is bound by the transcription factor LBD29, which is a direct target for regulation by ARF7. Disrupting auxin-inducible LBD29 expression or expressing an LBD29-SRDX transcriptional repressor phenocopied the lax3 mutant, resulting in delayed lateral root emergence. We conclude that sequential LBD29 and LAX3 induction by auxin is required to coordinate cell separation and organ emergence., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

10. New insights into root gravitropic signalling.

Author

Sato EM, Hijazi H, Bennett MJ, Vissenberg K, and Swarup R

Subjects

Biological Transport, Indoleacetic Acids metabolism, Models, Biological, Gravitropism physiology, Plant Roots physiology, Signal Transduction

Abstract

An important feature of plants is the ability to adapt their growth towards or away from external stimuli such as light, water, temperature, and gravity. These responsive plant growth movements are called tropisms and they contribute to the plant's survival and reproduction. Roots modulate their growth towards gravity to exploit the soil for water and nutrient uptake, and to provide anchorage. The physiological process of root gravitropism comprises gravity perception, signal transmission, growth response, and the re-establishment of normal growth. Gravity perception is best explained by the starch-statolith hypothesis that states that dense starch-filled amyloplasts or statoliths within columella cells sediment in the direction of gravity, resulting in the generation of a signal that causes asymmetric growth. Though little is known about the gravity receptor(s), the role of auxin linking gravity sensing to the response is well established. Auxin influx and efflux carriers facilitate creation of a differential auxin gradient between the upper and lower side of gravistimulated roots. This asymmetric auxin gradient causes differential growth responses in the graviresponding tissue of the elongation zone, leading to root curvature. Cell biological and mathematical modelling approaches suggest that the root gravitropic response begins within minutes of a gravity stimulus, triggering genomic and non-genomic responses. This review discusses recent advances in our understanding of root gravitropism in Arabidopsis thaliana and identifies current challenges and future perspectives., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2015

11. The ASH1-RELATED3 SET-domain protein controls cell division competence of the meristem and the quiescent center of the Arabidopsis primary root.

Author

Kumpf R, Thorstensen T, Rahman MA, Heyman J, Nenseth HZ, Lammens T, Herrmann U, Swarup R, Veiseth SV, Emberland G, Bennett MJ, De Veylder L, and Aalen RB

Subjects

Arabidopsis cytology, Arabidopsis Proteins genetics, DNA Replication, DNA, Plant biosynthesis, Mutation, S Phase, Arabidopsis physiology, Arabidopsis Proteins physiology, Cell Division physiology, Meristem cytology, Plant Roots cytology

Abstract

The stem cell niche of the Arabidopsis (Arabidopsis thaliana) primary root apical meristem is composed of the quiescent (or organizing) center surrounded by stem (initial) cells for the different tissues. Initial cells generate a population of transit-amplifying cells that undergo a limited number of cell divisions before elongating and differentiating. It is unclear whether these divisions occur stochastically or in an orderly manner. Using the thymidine analog 5-ethynyl-2'-deoxyuridine to monitor DNA replication of cells of Arabidopsis root meristems, we identified a pattern of two, four, and eight neighboring cells with synchronized replication along the cortical, epidermal, and endodermal cell files, suggested to be daughters, granddaughters, and great-granddaughters of the direct progeny of each stem cell. Markers of mitosis and cytokinesis were not present in the region closest to the transition zone where the cells start to elongate, suggesting that great-granddaughter cells switch synchronously from the mitotic cell cycle to endoreduplication. Mutations in the stem cell niche-expressed ASH1-RELATED3 (ASHR3) gene, encoding a SET-domain protein conferring histone H3 lysine-36 methylation, disrupted this pattern of coordinated DNA replication and cell division and increased the cell division rate in the quiescent center. E2Fa/E2Fb transcription factors controlling the G1-to-S-phase transition regulate ASHR3 expression and bind to the ASHR3 promoter, substantiating a role for ASHR3 in cell division control. The reduced length of the root apical meristem and primary root of the mutant ashr3-1 indicate that synchronization of replication and cell divisions is required for normal root growth and development., (© 2014 American Society of Plant Biologists. All Rights Reserved.)

Published

2014

12. Systems analysis of auxin transport in the Arabidopsis root apex.

Author

Band LR, Wells DM, Fozard JA, Ghetiu T, French AP, Pound MP, Wilson MH, Yu L, Li W, Hijazi HI, Oh J, Pearce SP, Perez-Amador MA, Yun J, Kramer E, Alonso JM, Godin C, Vernoux T, Hodgman TC, Pridmore TP, Swarup R, King JR, and Bennett MJ

Subjects

Biological Transport, Subcellular Fractions metabolism, Arabidopsis metabolism, Indoleacetic Acids metabolism, Plant Roots metabolism

Abstract

Auxin is a key regulator of plant growth and development. Within the root tip, auxin distribution plays a crucial role specifying developmental zones and coordinating tropic responses. Determining how the organ-scale auxin pattern is regulated at the cellular scale is essential to understanding how these processes are controlled. In this study, we developed an auxin transport model based on actual root cell geometries and carrier subcellular localizations. We tested model predictions using the DII-VENUS auxin sensor in conjunction with state-of-the-art segmentation tools. Our study revealed that auxin efflux carriers alone cannot create the pattern of auxin distribution at the root tip and that AUX1/LAX influx carriers are also required. We observed that AUX1 in lateral root cap (LRC) and elongating epidermal cells greatly enhance auxin's shootward flux, with this flux being predominantly through the LRC, entering the epidermal cells only as they enter the elongation zone. We conclude that the nonpolar AUX1/LAX influx carriers control which tissues have high auxin levels, whereas the polar PIN carriers control the direction of auxin transport within these tissues.

Published

2014

13. Root gravitropism is regulated by a transient lateral auxin gradient controlled by a tipping-point mechanism.

Author

Band LR, Wells DM, Larrieu A, Sun J, Middleton AM, French AP, Brunoud G, Sato EM, Wilson MH, Péret B, Oliva M, Swarup R, Sairanen I, Parry G, Ljung K, Beeckman T, Garibaldi JM, Estelle M, Owen MR, Vissenberg K, Hodgman TC, Pridmore TP, King JR, Vernoux T, and Bennett MJ

Subjects

Arabidopsis growth & development, Dose-Response Relationship, Drug, Environment, Gravitropism physiology, Kinetics, Models, Biological, Models, Theoretical, Plant Physiological Phenomena, Plant Roots growth & development, Plant Roots physiology, Signal Transduction, Systems Biology methods, Time Factors, Arabidopsis metabolism, Indoleacetic Acids metabolism, Plant Roots metabolism

Abstract

Gravity profoundly influences plant growth and development. Plants respond to changes in orientation by using gravitropic responses to modify their growth. Cholodny and Went hypothesized over 80 years ago that plants bend in response to a gravity stimulus by generating a lateral gradient of a growth regulator at an organ's apex, later found to be auxin. Auxin regulates root growth by targeting Aux/IAA repressor proteins for degradation. We used an Aux/IAA-based reporter, domain II (DII)-VENUS, in conjunction with a mathematical model to quantify auxin redistribution following a gravity stimulus. Our multidisciplinary approach revealed that auxin is rapidly redistributed to the lower side of the root within minutes of a 90° gravity stimulus. Unexpectedly, auxin asymmetry was rapidly lost as bending root tips reached an angle of 40° to the horizontal. We hypothesize roots use a "tipping point" mechanism that operates to reverse the asymmetric auxin flow at the midpoint of root bending. These mechanistic insights illustrate the scientific value of developing quantitative reporters such as DII-VENUS in conjunction with parameterized mathematical models to provide high-resolution kinetics of hormone redistribution.

Published

2012

14. Short-Root regulates primary, lateral, and adventitious root development in Arabidopsis.

Author

Lucas M, Swarup R, Paponov IA, Swarup K, Casimiro I, Lake D, Peret B, Zappala S, Mairhofer S, Whitworth M, Wang J, Ljung K, Marchant A, Sandberg G, Holdsworth MJ, Palme K, Pridmore T, Mooney S, and Bennett MJ

Subjects

Arabidopsis cytology, Arabidopsis ultrastructure, Arabidopsis Proteins genetics, Body Patterning, Cell Division, Germination, Indoleacetic Acids metabolism, Membrane Transport Proteins metabolism, Mutation genetics, Plant Roots cytology, Plant Roots ultrastructure, Transcription Factors genetics, Arabidopsis growth & development, Arabidopsis Proteins metabolism, Plant Roots growth & development, Transcription Factors metabolism

Abstract

Short-Root (SHR) is a well-characterized regulator of radial patterning and indeterminacy of the Arabidopsis (Arabidopsis thaliana) primary root. However, its role during the elaboration of root system architecture remains unclear. We report that the indeterminate wild-type Arabidopsis root system was transformed into a determinate root system in the shr mutant when growing in soil or agar. The root growth behavior of the shr mutant results from its primary root apical meristem failing to initiate cell division following germination. The inability of shr to reactivate mitotic activity in the root apical meristem is associated with the progressive reduction in the abundance of auxin efflux carriers, PIN-FORMED1 (PIN1), PIN2, PIN3, PIN4, and PIN7. The loss of primary root growth in shr is compensated by the activation of anchor root primordia, whose tissues are radially patterned like the wild type. However, SHR function is not restricted to the primary root but is also required for the initiation and patterning of lateral root primordia. In addition, SHR is necessary to maintain the indeterminate growth of lateral and anchor roots. We conclude that SHR regulates a wide array of Arabidopsis root-related developmental processes.

Published

2011

15. The AUX1 LAX family of auxin influx carriers is required for the establishment of embryonic root cell organization in Arabidopsis thaliana.

Author

Ugartechea-Chirino Y, Swarup R, Swarup K, Péret B, Whitworth M, Bennett M, and Bougourd S

Subjects

Arabidopsis cytology, Arabidopsis Proteins genetics, Embryonic Development genetics, Embryonic Development physiology, Meristem cytology, Meristem genetics, Microscopy, Confocal, Plant Roots cytology, Arabidopsis embryology, Arabidopsis Proteins metabolism, Plant Roots embryology

Abstract

Background and Aims: The root meristem of the Arabidopsis thaliana mature embryo is a highly organized structure in which individual cell shape and size must be regulated in co-ordination with the surrounding cells. The objective of this study was to determine the role of the AUX1 LAX family of auxin import carriers during the establishment of the embryonic root cell pattern., Methods: The radicle apex of single and multiple aux1 lax mutant mature embryos was used to evaluate the effect of this gene family upon embryonic root organization and root cap size, cell number and cell size., Key Results: It was demonstrated here that mutations within the AUX1 LAX family are associated with changes in cell pattern establishment in the embryonic quiescent centre and columella. aux1 lax mutants have a larger radicle root cap than the wild type and this is associated with a significant increase in the root-cap cell number, average cell size, or both. Extreme disorganization of the radicle apex was observed among quadruple aux1 lax1 lax2 lax3 mutant embryos, but not in single aux1 null or in lax1, lax2 and lax3 single mutants, indicating redundancy within the AUX1 LAX family., Conclusions: It was determined that the AUX1 LAX family of auxin influx facilitators participates in the establishment of cell pattern within the apex of the embryonic root in a gene-redundant fashion. It was demonstrated that aux1 lax mutants are affected in cell proliferation and cell growth within the radicle tip. Thus AUX1 LAX auxin importers emerge as new players in morphogenetic processes involved in patterning during embryonic root formation.

Published

2010

16. Arabidopsis lateral root development: an emerging story.

Author

Péret B, De Rybel B, Casimiro I, Benková E, Swarup R, Laplaze L, Beeckman T, and Bennett MJ

Subjects

Arabidopsis cytology, Arabidopsis embryology, Body Patterning, Indoleacetic Acids metabolism, Plant Roots cytology, Signal Transduction, Xylem cytology, Xylem growth & development, Arabidopsis growth & development, Plant Roots growth & development

Abstract

Lateral root formation is a major determinant of root systems architecture. The degree of root branching impacts the efficiency of water uptake, acquisition of nutrients and anchorage by plants. Understanding the regulation of lateral root development is therefore of vital agronomic importance. The molecular and cellular basis of lateral root formation has been most extensively studied in the plant model Arabidopsis thaliana (Arabidopsis). Significant progress has recently been made in identifying many new Arabidopsis genes that regulate lateral root initiation, patterning and emergence processes. We review how these studies have revealed that the plant hormone auxin represents a common signal that integrates these distinct yet interconnected developmental processes.

Published

2009

17. Auxin transport through non-hair cells sustains root-hair development.

Author

Jones AR, Kramer EM, Knox K, Swarup R, Bennett MJ, Lazarus CM, Leyser HM, and Grierson CS

Subjects

Arabidopsis cytology, Arabidopsis Proteins metabolism, Biological Transport, Active physiology, Cell Differentiation physiology, Computer Simulation, Plant Epidermis cytology, Plant Epidermis growth & development, Plant Epidermis metabolism, Plant Roots cytology, Arabidopsis growth & development, Arabidopsis metabolism, Indoleacetic Acids metabolism, Plant Roots growth & development, Plant Roots metabolism

Abstract

The plant hormone auxin controls root epidermal cell development in a concentration-dependent manner. Root hairs are produced on a subset of epidermal cells as they increase in distance from the root tip. Auxin is required for their initiation and continued growth, but little is known about its distribution in this region of the root. Contrary to the expectation that hair cells might require active auxin influx to ensure auxin supply, we did not detect the auxin-influx transporter AUX1 in root-hair cells. A high level of AUX1 expression was detected in adjacent non-hair cell files. Non-hair cells were necessary to achieve wild-type root-hair length, although an auxin response was not required in these cells. Three-dimensional modelling of auxin flow in the root tip suggests that AUX1-dependent transport through non-hair cells maintains an auxin supply to developing hair cells as they increase in distance from the root tip, and sustains root-hair outgrowth. Experimental data support the hypothesis that instead of moving uniformly though the epidermal cell layer, auxin is mainly transported through canals that extend longitudinally into the tissue.

Published

2009

18. The auxin influx carrier LAX3 promotes lateral root emergence.

Author

Swarup K, Benková E, Swarup R, Casimiro I, Péret B, Yang Y, Parry G, Nielsen E, De Smet I, Vanneste S, Levesque MP, Carrier D, James N, Calvo V, Ljung K, Kramer E, Roberts R, Graham N, Marillonnet S, Patel K, Jones JD, Taylor CG, Schachtman DP, May S, Sandberg G, Benfey P, Friml J, Kerr I, Beeckman T, Laplaze L, and Bennett MJ

Subjects

Arabidopsis, Carrier Proteins genetics, Gene Expression Regulation, Plant, Plant Growth Regulators pharmacology, Plant Roots cytology, Arabidopsis Proteins physiology, Carrier Proteins physiology, Indoleacetic Acids pharmacology, Membrane Transport Proteins physiology, Plant Roots growth & development

Abstract

Lateral roots originate deep within the parental root from a small number of founder cells at the periphery of vascular tissues and must emerge through intervening layers of tissues. We describe how the hormone auxin, which originates from the developing lateral root, acts as a local inductive signal which re-programmes adjacent cells. Auxin induces the expression of a previously uncharacterized auxin influx carrier LAX3 in cortical and epidermal cells directly overlaying new primordia. Increased LAX3 activity reinforces the auxin-dependent induction of a selection of cell-wall-remodelling enzymes, which are likely to promote cell separation in advance of developing lateral root primordia.

Published

2008

19. Root growth in Arabidopsis requires gibberellin/DELLA signalling in the endodermis.

Author

Ubeda-Tomás S, Swarup R, Coates J, Swarup K, Laplaze L, Beemster GT, Hedden P, Bhalerao R, and Bennett MJ

Subjects

Arabidopsis Proteins genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Transgenes, Arabidopsis anatomy & histology, Arabidopsis physiology, Arabidopsis Proteins metabolism, Gibberellins metabolism, Plant Roots anatomy & histology, Plant Roots physiology, Signal Transduction physiology

Abstract

Gibberellins (GAs) are key regulators of plant growth and development. They promote growth by targeting the degradation of DELLA repressor proteins; however, their site of action at the cellular, tissue or organ levels remains unknown. To map the site of GA action in regulating root growth, we expressed gai, a non-degradable, mutant DELLA protein, in selected root tissues. Root growth was retarded specifically when gai was expressed in endodermal cells. Our results demonstrate that the endodermis represents the primary GA-responsive tissue regulating organ growth and that endodermal cell expansion is rate-limiting for elongation of other tissues and therefore of the root as a whole.

Published

2008

20. Cytokinins act directly on lateral root founder cells to inhibit root initiation.

Author

Laplaze L, Benkova E, Casimiro I, Maes L, Vanneste S, Swarup R, Weijers D, Calvo V, Parizot B, Herrera-Rodriguez MB, Offringa R, Graham N, Doumas P, Friml J, Bogusz D, Beeckman T, and Bennett M

Subjects

Agrobacterium tumefaciens genetics, Alkyl and Aryl Transferases genetics, Alkyl and Aryl Transferases metabolism, Arabidopsis embryology, Arabidopsis genetics, Arabidopsis Proteins genetics, Benzyl Compounds, Gene Expression Regulation, Plant drug effects, Indoleacetic Acids pharmacology, Kinetin pharmacology, Models, Biological, Plant Roots embryology, Plant Roots genetics, Plants, Genetically Modified, Purines, Reverse Transcriptase Polymerase Chain Reaction, Xylem genetics, Xylem metabolism, Arabidopsis drug effects, Arabidopsis Proteins metabolism, Cytokinins pharmacology, Plant Roots drug effects

Abstract

In Arabidopsis thaliana, lateral roots are formed from root pericycle cells adjacent to the xylem poles. Lateral root development is regulated antagonistically by the plant hormones auxin and cytokinin. While a great deal is known about how auxin promotes lateral root development, the mechanism of cytokinin repression is still unclear. Elevating cytokinin levels was observed to disrupt lateral root initiation and the regular pattern of divisions that characterizes lateral root development in Arabidopsis. To identify the stage of lateral root development that is sensitive to cytokinins, we targeted the expression of the Agrobacterium tumefaciens cytokinin biosynthesis enzyme isopentenyltransferase to either xylem-pole pericycle cells or young lateral root primordia using GAL4-GFP enhancer trap lines. Transactivation experiments revealed that xylem-pole pericycle cells are sensitive to cytokinins, whereas young lateral root primordia are not. This effect is physiologically significant because transactivation of the Arabidopsis cytokinin degrading enzyme cytokinin oxidase 1 in lateral root founder cells results in increased lateral root formation. We observed that cytokinins perturb the expression of PIN genes in lateral root founder cells and prevent the formation of an auxin gradient that is required to pattern lateral root primordia.

Published

2007

21. Ethylene upregulates auxin biosynthesis in Arabidopsis seedlings to enhance inhibition of root cell elongation.

Author

Swarup R, Perry P, Hagenbeek D, Van Der Straeten D, Beemster GT, Sandberg G, Bhalerao R, Ljung K, and Bennett MJ

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Biological Transport drug effects, Gene Expression Regulation, Plant drug effects, Genes, Plant, Glucuronidase metabolism, Models, Biological, Plant Roots drug effects, Plant Roots growth & development, Seedlings drug effects, Arabidopsis drug effects, Arabidopsis metabolism, Ethylenes pharmacology, Indoleacetic Acids metabolism, Plant Roots cytology, Seedlings metabolism, Up-Regulation drug effects

Abstract

Ethylene represents an important regulatory signal for root development. Genetic studies in Arabidopsis thaliana have demonstrated that ethylene inhibition of root growth involves another hormone signal, auxin. This study investigated why auxin was required by ethylene to regulate root growth. We initially observed that ethylene positively controls auxin biosynthesis in the root apex. We subsequently demonstrated that ethylene-regulated root growth is dependent on (1) the transport of auxin from the root apex via the lateral root cap and (2) auxin responses occurring in multiple elongation zone tissues. Detailed growth studies revealed that the ability of the ethylene precursor 1-aminocyclopropane-1-carboxylic acid to inhibit root cell elongation was significantly enhanced in the presence of auxin. We conclude that by upregulating auxin biosynthesis, ethylene facilitates its ability to inhibit root cell expansion.

Published

2007

22. Auxin-dependent regulation of lateral root positioning in the basal meristem of Arabidopsis.

Author

De Smet I, Tetsumura T, De Rybel B, Frei dit Frey N, Laplaze L, Casimiro I, Swarup R, Naudts M, Vanneste S, Audenaert D, Inzé D, Bennett MJ, and Beeckman T

Subjects

Arabidopsis growth & development, Biological Clocks, Gravitropism, Plant Growth Regulators pharmacology, Arabidopsis Proteins physiology, Indoleacetic Acids pharmacology, Meristem physiology, Plant Roots growth & development

Abstract

In plants, the developmental mechanisms that regulate the positioning of lateral organs along the primary root are currently unknown. We present evidence on how lateral root initiation is controlled in a spatiotemporal manner in the model plant Arabidopsis thaliana. First, lateral roots are spaced along the main axis in a regular left-right alternating pattern that correlates with gravity-induced waving and depends on AUX1, an auxin influx carrier essential for gravitropic response. Second, we found evidence that the priming of pericycle cells for lateral root initiation might take place in the basal meristem, correlating with elevated auxin sensitivity in this part of the root. This local auxin responsiveness oscillates with peaks of expression at regular intervals of 15 hours. Each peak in the auxin-reporter maximum correlates with the formation of a consecutive lateral root. Third, auxin signaling in the basal meristem triggers pericycle cells for lateral root initiation prior to the action of INDOLE-3-ACETIC ACID14 (SOLITARY ROOT).

Published

2007

23. Root gravitropism requires lateral root cap and epidermal cells for transport and response to a mobile auxin signal.

Author

Swarup R, Kramer EM, Perry P, Knox K, Leyser HM, Haseloff J, Beemster GT, Bhalerao R, and Bennett MJ

Subjects

Arabidopsis cytology, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Arabidopsis Proteins pharmacokinetics, Computer Simulation, Models, Biological, Mutant Proteins, Plant Roots cytology, Plants, Genetically Modified, Protein Transport, Signal Transduction, Arabidopsis Proteins physiology, Gravitropism, Plant Growth Regulators metabolism, Plant Proteins metabolism, Plant Roots growth & development

Abstract

Re-orientation of Arabidopsis seedlings induces a rapid, asymmetric release of the growth regulator auxin from gravity-sensing columella cells at the root apex. The resulting lateral auxin gradient is hypothesized to drive differential cell expansion in elongation-zone tissues. We mapped those root tissues that function to transport or respond to auxin during a gravitropic response. Targeted expression of the auxin influx facilitator AUX1 demonstrated that root gravitropism requires auxin to be transported via the lateral root cap to all elongating epidermal cells. A three-dimensional model of the root elongation zone predicted that AUX1 causes the majority of auxin to accumulate in the epidermis. Selectively disrupting the auxin responsiveness of expanding epidermal cells by expressing a mutant form of the AUX/IAA17 protein, axr3-1, abolished root gravitropism. We conclude that gravitropic curvature in Arabidopsis roots is primarily driven by the differential expansion of epidermal cells in response to an influx-carrier-dependent auxin gradient.

Published

2005

24. Auxin transport: the fountain of life in plants?

Author

Swarup R and Bennett M

Subjects

Indoleacetic Acids physiology, Plant Roots embryology, Plant Roots physiology, Plant Shoots embryology, Plant Shoots physiology

Published

2003

25. Structure-Function Analysis of the Presumptive Arabidopsis Auxin Permease AUX1

Author

Swarup, Ranjan, Kargul, Joanna, Marchant, Alan, Zadik, Daniel, Rahman, Abidur, Mills, Rebecca, Yemm, Anthony, May, Sean, Williams, Lorraine, Millner, Paul, Tsurumi, Seiji, Moore, Ian, Napier, Richard, Kerr, Ian D., and Bennett, Malcolm J.

Published

2004

26. Auxin Transport Promotes Arabidopsis Lateral Root Initiation

Author

Casimiro, Ilda, Marchant, Alan, Bhalerao, Rishikesh P., Beeckman, Tom, Dhooge, Sandra, Swarup, Ranjan, Graham, Neil, Inzé, Dirk, Sandberg, Goran, Casero, Pedro J., and Bennett, Malcolm

Published

2001

27. Going the Distance with Auxin: Unravelling the Molecular Basis of Auxin Transport

Author

Bennett, Malcolm J., Marchant, Alan, May, Sean T., and Swarup, Ranjan

Published

1998

28. ERFVII action and modulation through oxygen-sensing in Arabidopsis thaliana.

Author

Zubrycka, Agata, Dambire, Charlene, Dalle Carbonare, Laura, Sharma, Gunjan, Boeckx, Tinne, Swarup, Kamal, Sturrock, Craig J., Atkinson, Brian S., Swarup, Ranjan, Corbineau, Françoise, Oldham, Neil J., and Holdsworth, Michael J.

Subjects

SULFONIC acids, ROOT development, PLANT roots, PLANT extracts, GENE expression, ARABIDOPSIS thaliana

Abstract

Oxygen is a key signalling component of plant biology, and whilst an oxygen-sensing mechanism was previously described in Arabidopsis thaliana, key features of the associated PLANT CYSTEINE OXIDASE (PCO) N-degron pathway and Group VII ETHYLENE RESPONSE FACTOR (ERFVII) transcription factor substrates remain untested or unknown. We demonstrate that ERFVIIs show non-autonomous activation of root hypoxia tolerance and are essential for root development and survival under oxygen limiting conditions in soil. We determine the combined effects of ERFVIIs in controlling gene expression and define genetic and environmental components required for proteasome-dependent oxygen-regulated stability of ERFVIIs through the PCO N-degron pathway. Using a plant extract, unexpected amino-terminal cysteine sulphonic acid oxidation level of ERFVIIs was observed, suggesting a requirement for additional enzymatic activity within the pathway. Our results provide a holistic understanding of the properties, functions and readouts of this oxygen-sensing mechanism defined through its role in modulating ERFVII stability. Oxygen is essential for plant life. Here the authors define new functions and components of the plant oxygen sensing mechanism providing an understanding of the biochemistry of sensing and physiological responses allowing plant roots to survive in the soil. [ABSTRACT FROM AUTHOR]

Published

2023

29. ROOT ULTRAVIOLET B-SENSITIVE1/WEAK AUXIN RESPONSE3 Is Essential for Polar Auxin Transport in Arabidopsis

Author

Yu, Hong, Karampelias, Michael, Robert, Stephanie, Peer, Wendy Ann, Swarup, Ranjan, Ye, Songqing, Ge, Lei, Cohen, Jerry, Murphy, Angus, Friml, Jirí, and Estelle, Mark

Published

2013

30. Auxin Influx Activity Is Associated with Frankia Infection during Actinorhizal Nodule Formation in Casuarina glauca

Author

Péret, Benjamin, Swarup, Ranjan, Jansen, Leen, Devos, Gaëlle, Auguy, Florence, Collin, Myriam, Santi, Carole, Hocher, Valérie, Franche, Claudine, Bogusz, Didier, Bennett, Malcolm, and Laplaze, Laurent

Published

2007

31. MtLAX2, a Functional Homologue of the Arabidopsis Auxin Influx Transporter AUX1, Is Required for Nodule Organogenesis1[CC-BY]

Author

Roy, Sonali, Robson, Fran, Lilley, Jodi, Liu, Cheng-Wu, Cheng, Xiaofei, Wen, Jiangqi, Walker, Simon, Sun, Jongho, Cousins, Donna, Bone, Caitlin, Bennett, Malcolm J., Downie, J. Allan, Swarup, Ranjan, Oldroyd, Giles, and Murray, Jeremy D.

Subjects

Indoleacetic Acids, fungi, food and beverages, Membrane Transport Proteins, Biological Transport, Articles, biochemical phenomena, metabolism, and nutrition, Plants, Genetically Modified, Plant Root Nodulation, Plant Roots, Gravitropism, Gene Expression Regulation, Plant, Medicago truncatula, Mutation, Root Nodules, Plant, Symbiosis, Plant Proteins, Rhizobium

Abstract

Most legume plants can form nodules, specialized lateral organs that form on roots, and house nitrogen-fixing bacteria collectively called rhizobia. The uptake of the phytohormone auxin into cells is known to be crucial for development of lateral roots. To test the role of auxin influx in nodulation we used the auxin influx inhibitors 1-naphthoxyacetic acid (1-NOA) and 2-NOA, which we found reduced nodulation of

Published

2017

32. The ASH1-RELATED3 SET-Domain Protein Controls Cell Division Competence of the Meristem and the Quiescent Center of the Arabidopsis Primary Root1[W][OPEN]

Author

Kumpf, Robert, Thorstensen, Tage, Rahman, Mohummad Aminur, Heyman, Jefri, Nenseth, H. Zeynep, Lammens, Tim, Herrmann, Ullrich, Swarup, Ranjan, Veiseth, Silje Veie, Emberland, Gitika, Bennett, Malcolm J., De Veylder, Lieven, and Aalen, Reidunn B.

Subjects

DNA Replication, DNA, Plant, Arabidopsis Proteins, Research Articles - Focus Issue, Meristem, Mutation, Arabidopsis, Plant Roots, Cell Division, S Phase

Abstract

The stem cell niche of the Arabidopsis (Arabidopsis thaliana) primary root apical meristem is composed of the quiescent (or organizing) center surrounded by stem (initial) cells for the different tissues. Initial cells generate a population of transit-amplifying cells that undergo a limited number of cell divisions before elongating and differentiating. It is unclear whether these divisions occur stochastically or in an orderly manner. Using the thymidine analog 5-ethynyl-2'-deoxyuridine to monitor DNA replication of cells of Arabidopsis root meristems, we identified a pattern of two, four, and eight neighboring cells with synchronized replication along the cortical, epidermal, and endodermal cell files, suggested to be daughters, granddaughters, and great-granddaughters of the direct progeny of each stem cell. Markers of mitosis and cytokinesis were not present in the region closest to the transition zone where the cells start to elongate, suggesting that great-granddaughter cells switch synchronously from the mitotic cell cycle to endoreduplication. Mutations in the stem cell niche-expressed ASH1-RELATED3 (ASHR3) gene, encoding a SET-domain protein conferring histone H3 lysine-36 methylation, disrupted this pattern of coordinated DNA replication and cell division and increased the cell division rate in the quiescent center. E2Fa/E2Fb transcription factors controlling the G1-to-S-phase transition regulate ASHR3 expression and bind to the ASHR3 promoter, substantiating a role for ASHR3 in cell division control. The reduced length of the root apical meristem and primary root of the mutant ashr3-1 indicate that synchronization of replication and cell divisions is required for normal root growth and development.

Published

2014

33. Auxin transport through non-hair cells sustains root-hair development

Author

Jones, Angharad R, Kramer, Eric M, Knox, Kirsten, Swarup, Ranjan, Bennett, Malcolm J, Lazarus, Colin M, Leyser, HM Ottoline, Grierson, Claire S, Leyser, Ottoline [0000-0003-2161-3829], and Apollo - University of Cambridge Repository

Subjects

integumentary system, Indoleacetic Acids, Arabidopsis Proteins, fungi, Arabidopsis, food and beverages, Biological Transport, Active, heterocyclic compounds, Cell Differentiation, Computer Simulation, sense organs, Plant Roots, Plant Epidermis

Abstract

The plant hormone auxin controls root epidermal cell development in a concentration-dependent manner. Root hairs are produced on a subset of epidermal cells as they increase in distance from the root tip. Auxin is required for their initiation and continued growth, but little is known about its distribution in this region of the root. Contrary to the expectation that hair cells might require active auxin influx to ensure auxin supply, we did not detect the auxin-influx transporter AUX1 in root-hair cells. A high level of AUX1 expression was detected in adjacent non-hair cell files. Non-hair cells were necessary to achieve wild-type root-hair length, although an auxin response was not required in these cells. Three-dimensional modelling of auxin flow in the root tip suggests that AUX1-dependent transport through non-hair cells maintains an auxin supply to developing hair cells as they increase in distance from the root tip, and sustains root-hair outgrowth. Experimental data support the hypothesis that instead of moving uniformly though the epidermal cell layer, auxin is mainly transported through canals that extend longitudinally into the tissue.

Published

2009

34. Cytokinin Induces Cell Division in the Quiescent Center of the Arabidopsis Root Apical Meristem.

Author

Zhang, Wenjing, Swarup, Ranjan, Bennett, Malcolm, Schaller, G.?Eric, and Kieber, Joseph?J.

Subjects

*ARABIDOPSIS, *CYTOKININS, *CELL division, *PLANT roots, *APICAL meristems, *ROOT development

Abstract

Summary: Background: In the root apical meristem, which contains the stem cells that feed into root development, the phytohormones auxin and cytokinin play opposing roles, with auxin promoting cell division and cytokinin promoting cell differentiation. Cytokinin acts in the root tip in part by modulating auxin transport through regulation of the level of the PIN auxin efflux carriers. Auxin plays a key role in the specification of the quiescent center (QC), which is essential for maintaining the stem cell fate of the surrounding cells. Results: We demonstrate that cytokinin promotes cell division in the QC, which is generally mitotically inactive. Cytokinin downregulates the expression of several key regulatory genes in the root tip, including SCARECROW, WOX5, and the auxin influx carriers AUX1 and LAX2. The decrease in LAX2 expression in response to cytokinin requires ARR1 and ARR12, two type B ARRs that mediate the primary transcriptional response to cytokinin. ARR1 was found to bind directly to the LAX2 gene in vivo, which indicates that type B ARRs directly regulate genes that are repressed by cytokinin. Disruption of the LAX2 gene results in a phenotype similar to that observed in response to cytokinin, including increased division of the cells in the QC and decreased expression of WOX5 and the auxin response reporter DR5. Conclusions: Cytokinin acts to regulate auxin distribution in the root apical meristem by regulating both the PINs and LAX2. This redistribution of auxin, potentially coupled with other auxin-independent effects of cytokinin, regulates the mitotic activity in the QC. [ABSTRACT FROM AUTHOR]

Published

2013

35. One Gene, Many Proteins: Mapping Cell-Specific Alternative Splicing in Plants.

Author

Swarup, Ranjan, Crespi, Martin, and Bennett, Malcolm J.

Subjects

*ALTERNATIVE RNA splicing, *ARABIDOPSIS, *PLANT cells & tissues, *GENE expression in plants, *PLANT roots

Abstract

Pre-mRNA alternative splicing (AS) generates protein variants from a single gene that can create novel regulatory opportunities. In this issue of Developmental Cell , Li et al. (2016) present a high-resolution expression map of AS events in Arabidopsis root tissues, giving insight into cell-type- and stage-specific AS mechanisms in plants. [ABSTRACT FROM AUTHOR]

Published

2016

36. Root angle is controlled byEGT1in cereal crops employing an antigravitropic mechanism

Author

Riccardo Fusi, Serena Rosignoli, Haoyu Lou, Giuseppe Sangiorgi, Riccardo Bovina, Jacob K. Pattem, Aditi N. Borkar, Marco Lombardi, Cristian Forestan, Sara G. Milner, Jayne L. Davis, Aneesh Lale, Gwendolyn K. Kirschner, Ranjan Swarup, Alberto Tassinari, Bipin K. Pandey, Larry M. York, Brian S. Atkinson, Craig J. Sturrock, Sacha J. Mooney, Frank Hochholdinger, Matthew R. Tucker, Axel Himmelbach, Nils Stein, Martin Mascher, Kerstin A. Nagel, Laura De Gara, James Simmonds, Cristobal Uauy, Roberto Tuberosa, Jonathan P. Lynch, Gleb E. Yakubov, Malcolm J. Bennett, Rahul Bhosale, Silvio Salvi, Fusi, Riccardo, Rosignoli, Serena, Lou, Haoyu, Sangiorgi, Giuseppe, Bovina, Riccardo, Pattem, Jacob K, Borkar, Aditi N, Lombardi, Marco, Forestan, Cristian, Milner, Sara G, Davis, Jayne L, Lale, Aneesh, Kirschner, Gwendolyn K, Swarup, Ranjan, Tassinari, Alberto, Pandey, Bipin K, York, Larry M, Atkinson, Brian S, Sturrock, Craig J, Mooney, Sacha J, Hochholdinger, Frank, Tucker, Matthew R, Himmelbach, Axel, Stein, Nil, Mascher, Martin, Nagel, Kerstin A, De Gara, Laura, Simmonds, Jame, Uauy, Cristobal, Tuberosa, Roberto, Lynch, Jonathan P, Yakubov, Gleb E, Bennett, Malcolm J, Bhosale, Rahul, and Salvi, Silvio

Subjects

Crops, Agricultural, Multidisciplinary, Transcription, Genetic, barley, root angle, Plant Protein, Hordeum, Microscopy, Atomic Force, Plant Roots, antigravitropic, Gravitropism, cell-wall, Cell Wall, wheat, ddc:500, Reactive Oxygen Specie

Abstract

Root angle in crops represents a key trait for efficient capture of soil resources. Root angle is determined by competing gravitropic versus antigravitropic offset (AGO) mechanisms. Here we report a root angle regulatory gene termedENHANCED GRAVITROPISM1(EGT1) that encodes a putative AGO component, whose loss-of-function enhances root gravitropism. Mutations in barley and wheatEGT1genes confer a striking root phenotype, where every root class adopts a steeper growth angle.EGT1encodes an F-box and Tubby domain-containing protein that is highly conserved across plant species. Haplotype analysis found that natural allelic variation at the barleyEGT1locus impacts root angle. Gravitropic assays indicated thatHvegt1roots bend more rapidly than wild-type. Transcript profiling revealedHvegt1roots deregulate reactive oxygen species (ROS) homeostasis and cell wall-loosening enzymes and cofactors. ROS imaging shows thatHvegt1root basal meristem and elongation zone tissues have reduced levels. Atomic force microscopy measurements detected elongatingHvegt1root cortical cell walls are significantly less stiff than wild-type. In situ analysis identifiedHvEGT1is expressed in elongating cortical and stele tissues, which are distinct from known root gravitropic perception and response tissues in the columella and epidermis, respectively. We propose that EGT1 controls root angle by regulating cell wall stiffness in elongating root cortical tissue, counteracting the gravitropic machinery’s known ability to bend the root via its outermost tissues. We conclude that root angle is controlled byEGT1in cereal crops employing an antigravitropic mechanism.

Published

2022