<i>MASSUGU2</i> Encodes Aux/IAA19, an Auxin-Regulated Protein That Functions Together with the Transcriptional Activator NPH4/ARF7 to Regulate Differential Growth Responses of Hypocotyl and Formation of Lateral Roots in <i>Arabidopsis thaliana</i>

Tatematsu, Kiyoshi; Kumagai, Satoshi; Muto, Hideki; Sato, Atsuko; Watahiki, Masaaki K.; Harper, Reneeé M.; Liscum, Emmanuel; Yamamoto, Kotaro T.

doi:10.1105/tpc.018630

Cited by 396 publications

(471 citation statements)

References 84 publications

Supporting

Mentioning

439

Contrasting

Unclassified

Order By: Relevance

“…Quantitative real-time PCR analysis of these differentially expressed targets at various time points during the poplar-L. bicolor interaction identified genes, such as PtaIAA19.3 and PtaIAA28.1, whose transcript levels were modified early but only transiently. When defective or absent, homologs of the Arabidopsis auxin transcription regulators PtaIAA19.3 and PtaIAA28.1 are known to cause a strong LR phenotype (Tian and Reed, 1999;Rogg et al, 2001;Tatematsu et al, 2004;Muto et al, 2007). Strikingly, when NPA was applied during the poplar-L. bicolor interaction, PtaIAA19.3 transcript accumulation was repressed in the presence of the fungus and no LR stimulation was observed.…”

Section: Polar Auxin Transport Regulates Lr Induction During the Rootmentioning

confidence: 97%

The Ectomycorrhizal FungusLaccaria bicolorStimulates Lateral Root Formation in Poplar and Arabidopsis through Auxin Transport and Signaling

et al. 2009

View full text Add to dashboard Cite

The early phase of the interaction between tree roots and ectomycorrhizal fungi, prior to symbiosis establishment, is accompanied by a stimulation of lateral root (LR) development. We aimed to identify gene networks that regulate LR development during the early signal exchanges between poplar (Populus tremula 3 Populus alba) and the ectomycorrhizal fungus Laccaria bicolor with a focus on auxin transport and signaling pathways. Our data demonstrated that increased LR development in poplar and Arabidopsis (Arabidopsis thaliana) interacting with L. bicolor is not dependent on the ability of the plant to form ectomycorrhizae. LR stimulation paralleled an increase in auxin accumulation at root apices. Blocking plant polar auxin transport with 1-naphthylphthalamic acid inhibited LR development and auxin accumulation. An oligoarray-based transcript profile of poplar roots exposed to molecules released by L. bicolor revealed the differential expression of 2,945 genes, including several components of polar auxin transport (PtaPIN and PtaAUX genes), auxin conjugation (PtaGH3 genes), and auxin signaling (PtaIAA genes). Transcripts of PtaPIN9, the homolog of Arabidopsis AtPIN2, and several PtaIAAs accumulated specifically during the early interaction phase. Expression of these rapidly induced genes was repressed by 1-naphthylphthalamic acid. Accordingly, LR stimulation upon contact with L. bicolor in Arabidopsis transgenic plants defective in homologs of these genes was decreased or absent. Furthermore, in Arabidopsis pin2, the root apical auxin increase during contact with the fungus was modified. We propose a model in which fungus-induced auxin accumulation at the root apex stimulates LR formation through a mechanism involving PtaPIN9-dependent auxin redistribution together with PtaIAA-based auxin signaling.Most temperate forest trees develop a mutualistic root symbiosis with ectomycorrhizal soil fungi. During the establishment of ectomycorrhiza (ECM), fungal hyphae invade the root from root cap cells in and upwards to the epidermis (Horan et al., 1988). After attachment to epidermal cells, hyphae multiply to form a series of layers that differentiate to establish a mantle structure around the root (Horan et al., 1988). An internal network of hyphae between the epidermis and root cortex cells forms the Hartig net (Blasius et al., 1986), while extraradical hyphae prospect throughout the surrounding soil and gather nutrients. Morphological observations of forming ECMs have shown that in the vicinity of the fungus the root architecture of the host plant is profoundly modified. Interaction with hyphae stimulates lateral root (LR) formation, dichotomy of the root apical meristem in conifer species, and cytodifferentiation of root cells (radial elongation and root hair decay; Horan et al., 1988;Dexheimer and Pargney, 1991;. Even though several studies have focused on LR stimulation during ECM formation, it still remains unclear what the molecular mechanisms are that modify root development during contact with the fungus.In the ...

show abstract

Section: Polar Auxin Transport Regulates Lr Induction During the Rootmentioning

confidence: 97%

The Ectomycorrhizal FungusLaccaria bicolorStimulates Lateral Root Formation in Poplar and Arabidopsis through Auxin Transport and Signaling

et al. 2009

View full text Add to dashboard Cite

show abstract

“…In A. thaliana several genes involved in auxin homeostasis are known to contain auxin response elements in their promoters (Barlier et al 2000). Furthermore recent studies have revealed that speciWc auxin-mediated responses are controlled via a negative (auto)feedback loop (Tatematsu et al 2004). As APRX gene is auxin-inducible but that the protein is also an auxin oxidase, APRX may participate in the local negative feedback regulation of auxin levels.…”

Section: Aprx Is Involved In Auxin Catabolismmentioning

confidence: 99%

An anionic class III peroxidase from zucchini may regulate hypocotyl elongation through its auxin oxidase activity

Cosio

Vuillemin

Meyer

et al. 2009

Planta

View full text Add to dashboard Cite

The high number of peroxidase genes explains the description of numerous physiological functions and the fact that the in planta function of a single isoform has never been characterized yet. We analyzed in transgenic Arabidopsis thaliana the localization of a zucchini isoperoxidase (APRX), previously puriWed thanks to its pectin binding ability. We conWrmed that the protein is localized near the cell wall, mainly produced in the elongation area of the hypocotyls and respond to exogenous auxin. In addition, the ectopic overexpression of APRX induced changes in growth pattern and a signiWcant reduction of endogenous indole-3-acetic acid (IAA) level. In agreement with these observations APRX showed an elevated in vitro auxin oxidase activity. We propose that APRX participates in the negative feedback regulation of auxin level and consequently terminates the hypocotyl elongation process.

show abstract

“…The only exception was the report of Iino (1991), who found an asymmetry in maize coleoptiles. On the other hand, more recent studies with Arabidopsis have provided genetic evidence that auxin is involved in the process of phototropism (Harper et al, 2000;Blakeslee et al, 2004;Tatematsu et al, 2004). For resolving the signaling pathway for phototropism, it is required that the Cholodny-Went hypothesis is firmly established.…”

Section: Introductionmentioning

confidence: 99%

The Rice COLEOPTILE PHOTOTROPISM1 Gene Encoding an Ortholog of Arabidopsis NPH3 Is Required for Phototropism of Coleoptiles and Lateral Translocation of Auxin

et al. 2005

View full text Add to dashboard Cite

We isolated a mutant, named coleoptile phototropism1 (cpt1), from g-ray-mutagenized japonica-type rice (Oryza sativa). This mutant showed no coleoptile phototropism and severely reduced root phototropism after continuous stimulation. A map-based cloning strategy and transgenic complementation test were applied to demonstrate that a NPH3-like gene deleted in the mutant corresponds to CPT1. Phylogenetic analysis of putative CPT1 homologs of rice and related proteins indicated that CPT1 has an orthologous relationship with Arabidopsis thaliana NPH3. These results, along with those for Arabidopsis, demonstrate that NPH3/CPT1 is a key signal transduction component of higher plant phototropism. In an extended study with the cpt1 mutant, it was found that phototropic differential growth is accompanied by a CPT1-independent inhibition of net growth. Kinetic investigation further indicated that a small phototropism occurs in cpt1 coleoptiles. This response, induced only transiently, was thought to be caused by the CPT1-independent growth inhibition. The 3 H-indole-3-acetic acid applied to the coleoptile tip was asymmetrically distributed between the two sides of phototropically responding coleoptiles. However, no asymmetry was induced in cpt1 coleoptiles, indicating that lateral translocation of auxin occurs downstream of CPT1. It is concluded that the CPT1-dependent major phototropism of coleoptiles is achieved by lateral auxin translocation and subsequent growth redistribution.

show abstract

MASSUGU2 Encodes Aux/IAA19, an Auxin-Regulated Protein That Functions Together with the Transcriptional Activator NPH4/ARF7 to Regulate Differential Growth Responses of Hypocotyl and Formation of Lateral Roots in Arabidopsis thaliana

Cited by 396 publications

References 84 publications

The Ectomycorrhizal FungusLaccaria bicolorStimulates Lateral Root Formation in Poplar and Arabidopsis through Auxin Transport and Signaling

The Ectomycorrhizal FungusLaccaria bicolorStimulates Lateral Root Formation in Poplar and Arabidopsis through Auxin Transport and Signaling

An anionic class III peroxidase from zucchini may regulate hypocotyl elongation through its auxin oxidase activity

The Rice COLEOPTILE PHOTOTROPISM1 Gene Encoding an Ortholog of Arabidopsis NPH3 Is Required for Phototropism of Coleoptiles and Lateral Translocation of Auxin

Contact Info

Product

Resources

About