Literature DB >> 25792146

The blue light-dependent phosphorylation of the CCE domain determines the photosensitivity of Arabidopsis CRY2.

Qin Wang1, William D Barshop2, Mingdi Bian3, Ajay A Vashisht2, Reqing He4, Xuhong Yu5, Bin Liu6, Paula Nguyen5, Xuanming Liu4, Xiaoying Zhao7, James A Wohlschlegel2, Chentao Lin8.   

Abstract

Arabidopsis cryptochrome 2 (CRY2) is a blue light receptor that mediates light inhibition of hypocotyl elongation and long-day promotion of floral initiation. CRY2 is known to undergo blue light-dependent phosphorylation, which is believed to serve regulatory roles in the function of CRY2. We report here on a biochemical and genetics study of CRY2 phosphorylation. Using mass spectrometry analysis, we identified three serine residues in the CCE domain of CRY2 (S598, S599, and S605) that undergo blue light-dependent phosphorylation in Arabidopsis seedlings. A study of serine-substitution mutations in the CCE domain of CRY2 demonstrates that CRY2 contains two types of phosphorylation in the CCE domain, one in the serine cluster that causes electrophoretic mobility upshift and the other outside the serine cluster that does not seem to cause mobility upshift. We showed that mutations in the serine residues within and outside the serine cluster diminished blue light-dependent CRY2 phosphorylation, degradation, and physiological activities. These results support the hypothesis that blue light-dependent phosphorylation of the CCE domain determines the photosensitivity of Arabidopsis CRY2.
Copyright © 2015 The Author. Published by Elsevier Inc. All rights reserved.

Entities:  

Keywords:  Arabidopsis; light regulation; light signaling; physiology of plant growth

Mesh:

Substances:

Year:  2015        PMID: 25792146      PMCID: PMC5219891          DOI: 10.1016/j.molp.2015.03.005

Source DB:  PubMed          Journal:  Mol Plant        ISSN: 1674-2052            Impact factor:   13.164


  53 in total

1.  Direct interaction of Arabidopsis cryptochromes with COP1 in light control development.

Authors:  H Wang; L G Ma; J M Li; H Y Zhao; X W Deng
Journal:  Science       Date:  2001-08-16       Impact factor: 47.728

2.  Blue light-dependent interaction of CRY2 with SPA1 regulates COP1 activity and floral initiation in Arabidopsis.

Authors:  Zecheng Zuo; Hongtao Liu; Bin Liu; Xuanming Liu; Chentao Lin
Journal:  Curr Biol       Date:  2011-04-21       Impact factor: 10.834

3.  Arabidopsis cryptochrome 1 interacts with SPA1 to suppress COP1 activity in response to blue light.

Authors:  Bin Liu; Zecheng Zuo; Hongtao Liu; Xuanming Liu; Chentao Lin
Journal:  Genes Dev       Date:  2011-04-21       Impact factor: 11.361

4.  Analysis of protein phosphorylation: methods and strategies for studying kinases and substrates.

Authors:  Scott C Peck
Journal:  Plant J       Date:  2006-02       Impact factor: 6.417

5.  Functional evolution of the photolyase/cryptochrome protein family: importance of the C terminus of mammalian CRY1 for circadian core oscillator performance.

Authors:  Inês Chaves; Kazuhiro Yagita; Sander Barnhoorn; Hitoshi Okamura; Gijsbertus T J van der Horst; Filippo Tamanini
Journal:  Mol Cell Biol       Date:  2006-03       Impact factor: 4.272

6.  The signaling mechanism of Arabidopsis CRY1 involves direct interaction with COP1.

Authors:  H Q Yang; R H Tang; A R Cashmore
Journal:  Plant Cell       Date:  2001-12       Impact factor: 11.277

7.  The CNT1 Domain of Arabidopsis CRY1 Alone Is Sufficient to Mediate Blue Light Inhibition of Hypocotyl Elongation.

Authors:  Sheng-Bo He; Wen-Xiu Wang; Jing-Yi Zhang; Feng Xu; Hong-Li Lian; Ling Li; Hong-Quan Yang
Journal:  Mol Plant       Date:  2015-02-24       Impact factor: 13.164

Review 8.  The action mechanisms of plant cryptochromes.

Authors:  Hongtao Liu; Bin Liu; Chenxi Zhao; Michael Pepper; Chentao Lin
Journal:  Trends Plant Sci       Date:  2011-10-07       Impact factor: 18.313

9.  Localization of ligand-induced phosphorylation sites to serine clusters in the C-terminal domain of the Dictyostelium cAMP receptor, cAR1.

Authors:  D Hereld; R Vaughan; J Y Kim; J Borleis; P Devreotes
Journal:  J Biol Chem       Date:  1994-03-04       Impact factor: 5.157

10.  Arabidopsis casein kinase1 proteins CK1.3 and CK1.4 phosphorylate cryptochrome2 to regulate blue light signaling.

Authors:  Shu-Tang Tan; Cheng Dai; Hong-Tao Liu; Hong-Wei Xue
Journal:  Plant Cell       Date:  2013-07-29       Impact factor: 11.277
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  23 in total

1.  Hyperactivity of the Arabidopsis cryptochrome (cry1) L407F mutant is caused by a structural alteration close to the cry1 ATP-binding site.

Authors:  Christian Orth; Nils Niemann; Lars Hennig; Lars-Oliver Essen; Alfred Batschauer
Journal:  J Biol Chem       Date:  2017-06-20       Impact factor: 5.157

2.  Mechanisms of Cryptochrome-Mediated Photoresponses in Plants.

Authors:  Qin Wang; Chentao Lin
Journal:  Annu Rev Plant Biol       Date:  2020-03-13       Impact factor: 26.379

3.  Dark, Light, and Temperature: Key Players in Plant Morphogenesis.

Authors:  Huanhuan Jin; Ziqiang Zhu
Journal:  Plant Physiol       Date:  2019-05-21       Impact factor: 8.340

Review 4.  Structural disorder in plant proteins: where plasticity meets sessility.

Authors:  Alejandra A Covarrubias; Cesar L Cuevas-Velazquez; Paulette S Romero-Pérez; David F Rendón-Luna; Caspar C C Chater
Journal:  Cell Mol Life Sci       Date:  2017-06-22       Impact factor: 9.261

5.  Hinge region of Arabidopsis phyA plays an important role in regulating phyA function.

Authors:  Yangyang Zhou; Li Yang; Jie Duan; Jinkui Cheng; Yunping Shen; Xiaoji Wang; Run Han; Hong Li; Zhen Li; Lihong Wang; William Terzaghi; Danmeng Zhu; Haodong Chen; Xing Wang Deng; Jigang Li
Journal:  Proc Natl Acad Sci U S A       Date:  2018-11-26       Impact factor: 11.205

6.  Cryptochrome mediated magnetic sensitivity in Arabidopsis occurs independently of light-induced electron transfer to the flavin.

Authors:  M Hammad; M Albaqami; M Pooam; E Kernevez; J Witczak; T Ritz; C Martino; M Ahmad
Journal:  Photochem Photobiol Sci       Date:  2020-02-17       Impact factor: 3.982

7.  Photoactivation and inactivation of Arabidopsis cryptochrome 2.

Authors:  Qin Wang; Zecheng Zuo; Xu Wang; Lianfeng Gu; Takeshi Yoshizumi; Zhaohe Yang; Liang Yang; Qing Liu; Wei Liu; Yun-Jeong Han; Jeong-Il Kim; Bin Liu; James A Wohlschlegel; Minami Matsui; Yoshito Oka; Chentao Lin
Journal:  Science       Date:  2016-10-21       Impact factor: 47.728

Review 8.  Beyond the photocycle-how cryptochromes regulate photoresponses in plants?

Authors:  Qin Wang; Zecheng Zuo; Xu Wang; Qing Liu; Lianfeng Gu; Yoshito Oka; Chentao Lin
Journal:  Curr Opin Plant Biol       Date:  2018-06-15       Impact factor: 7.834

Review 9.  Cryptochromes Orchestrate Transcription Regulation of Diverse Blue Light Responses in Plants.

Authors:  Zhaohe Yang; Bobin Liu; Jun Su; Jiakai Liao; Chentao Lin; Yoshito Oka
Journal:  Photochem Photobiol       Date:  2017-01-27       Impact factor: 3.421

Review 10.  Signaling mechanisms of plant cryptochromes in Arabidopsis thaliana.

Authors:  Bobin Liu; Zhaohe Yang; Adam Gomez; Bin Liu; Chentao Lin; Yoshito Oka
Journal:  J Plant Res       Date:  2016-01-25       Impact factor: 2.629
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