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Literature DB >> 21396817

The AFB4 auxin receptor is a negative regulator of auxin signaling in seedlings.

Katie Greenham¹, Aaron Santner, Cristina Castillejo, Sutton Mooney, Ilkka Sairanen, Karin Ljung, Mark Estelle.

Abstract

The plant hormone auxin is perceived by a family of F box proteins called the TIR1/auxin-signaling F box proteins (AFBs). Phylogenetic studies reveal that these proteins fall into four clades in flowering plants called TIR1, AFB2, AFB4, and AFB6. Genetic studies indicate that members of the TIR1 and AFB2 groups act as positive regulators of auxin signaling. In this report, we demonstrate a unique role for the AFB4 clade. Both AFB4 and AFB5 function as auxin receptors based on in vitro assays. However, unlike other members of the family, loss of AFB4 results in a range of growth defects that are consistent with auxin hypersensitivity, including increased hypocotyl and petiole elongation and increased numbers of lateral roots. Indeed, qRT-PCR experiments show that afb4-2 is hypersensitive to indole-3-acetic acid (IAA) in the hypocotyl, indicating that AFB4 is a negative regulator of auxin response. Furthermore, we show that AFB4 has a particularly important role in the response of seedlings to elevated temperature. Finally, we provide evidence that the AFB4 clade is the major target of the picloram family of auxinic herbicides. These results reveal a previously unknown aspect of auxin receptor function.

Entities: Chemical Disease Gene Species

Mesh：

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Year: 2011 PMID： 21396817 PMCID： PMC4295904 DOI： 10.1016/j.cub.2011.02.029

Source DB: PubMed Journal: Curr Biol ISSN： 0960-9822 Impact factor: 10.834

19 in total

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Authors: Bradley J Till; Steven H Reynolds; Elizabeth A Greene; Christine A Codomo; Linda C Enns; Jessica E Johnson; Chris Burtner; Anthony R Odden; Kim Young; Nicholas E Taylor; Jorja G Henikoff; Luca Comai; Steven Henikoff
Journal: Genome Res Date: 2003-03 Impact factor: 9.043

2. The power of auxin in plants.

Authors: Ottoline Leyser
Journal: Plant Physiol Date: 2010-10 Impact factor: 8.340

3. Quantitative distribution and metabolism of auxin herbicides in roots.

Authors: P C Scott; R O Morris
Journal: Plant Physiol Date: 1970-11 Impact factor: 8.340

4. Different plant hormones regulate similar processes through largely nonoverlapping transcriptional responses.

Authors: Jennifer L Nemhauser; Fangxin Hong; Joanne Chory
Journal: Cell Date: 2006-08-11 Impact factor: 41.582

5. Phytochrome interacting factors 4 and 5 redundantly limit seedling de-etiolation in continuous far-red light.

Authors: Séverine Lorrain; Martine Trevisan; Sylvain Pradervand; Christian Fankhauser
Journal: Plant J Date: 2009-07-08 Impact factor: 6.417

6. Identification of an SCF ubiquitin-ligase complex required for auxin response in Arabidopsis thaliana.

Authors: W M Gray; J C del Pozo; L Walker; L Hobbie; E Risseeuw; T Banks; W L Crosby; M Yang; H Ma; M Estelle
Journal: Genes Dev Date: 1999-07-01 Impact factor: 11.361

7. Mutations in an auxin receptor homolog AFB5 and in SGT1b confer resistance to synthetic picolinate auxins and not to 2,4-dichlorophenoxyacetic acid or indole-3-acetic acid in Arabidopsis.

Authors: Terence A Walsh; Roben Neal; Ann Owens Merlo; Mary Honma; Glenn R Hicks; Karen Wolff; Wendy Matsumura; John P Davies
Journal: Plant Physiol Date: 2006-08-18 Impact factor: 8.340

8. Circadian-controlled basic/helix-loop-helix factor, PIL6, implicated in light-signal transduction in Arabidopsis thaliana.

Authors: Toru Fujimori; Takafumi Yamashino; Takahiko Kato; Takeshi Mizuno
Journal: Plant Cell Physiol Date: 2004-08 Impact factor: 4.927

9. High temperature promotes auxin-mediated hypocotyl elongation in Arabidopsis.

Authors: W M Gray; A Ostin; G Sandberg; C P Romano; M Estelle
Journal: Proc Natl Acad Sci U S A Date: 1998-06-09 Impact factor: 11.205

10. New auxin analogs with growth-promoting effects in intact plants reveal a chemical strategy to improve hormone delivery.

Authors: Sigal Savaldi-Goldstein; Thomas J Baiga; Florence Pojer; Tsegeye Dabi; Cristina Butterfield; Geraint Parry; Aaron Santner; Nihal Dharmasiri; Yi Tao; Mark Estelle; Joseph P Noel; Joanne Chory
Journal: Proc Natl Acad Sci U S A Date: 2008-09-25 Impact factor: 11.205

34 in total

1. Phytochrome-interacting factor 4 (PIF4) regulates auxin biosynthesis at high temperature.

Authors: Keara A Franklin; Sang Ho Lee; Dhaval Patel; S Vinod Kumar; Angela K Spartz; Chen Gu; Songqing Ye; Peng Yu; Gordon Breen; Jerry D Cohen; Philip A Wigge; William M Gray
Journal: Proc Natl Acad Sci U S A Date: 2011-11-28 Impact factor: 11.205

2. F-box protein AFB4 plays a crucial role in plant growth, development and innate immunity.

Authors: Zhubing Hu; Mehmet Ali Keçeli; Maria Piisilä; Jingf Li; Mantas Survila; Pekka Heino; Günter Brader; E Tapio Palva; Jing Li
Journal: Cell Res Date: 2012-01-17 Impact factor: 25.617

3. Ubiquitin-mediated control of plant hormone signaling.

Authors: Dior R Kelley; Mark Estelle
Journal: Plant Physiol Date: 2012-06-21 Impact factor: 8.340

4. Exogenous Auxin Induces Transverse Microtubule Arrays Through TRANSPORT INHIBITOR RESPONSE1/AUXIN SIGNALING F-BOX Receptors.

Authors: Jillian H True; Sidney L Shaw
Journal: Plant Physiol Date: 2019-11-25 Impact factor: 8.340

10. Mutations in the TIR1 auxin receptor that increase affinity for auxin/indole-3-acetic acid proteins result in auxin hypersensitivity.

Authors: Hong Yu; Britney L Moss; Seunghee S Jang; Michael Prigge; Eric Klavins; Jennifer L Nemhauser; Mark Estelle
Journal: Plant Physiol Date: 2013-03-28 Impact factor: 8.340