Literature DB >> 30948554

Developmental Programming of Thermonastic Leaf Movement.

Young-Joon Park1, Hyo-Jun Lee1, Kyung-Eun Gil1, Jae Young Kim1, June-Hee Lee1, Hyodong Lee2, Hyung-Taeg Cho2, Lam Dai Vu3,4,5,6, Ive De Smet3,4, Chung-Mo Park7,8.   

Abstract

Plants exhibit diverse polar behaviors in response to directional and nondirectional environmental signals, termed tropic and nastic movements, respectively. The ways in which plants incorporate directional information into tropic behaviors is well understood, but it is less well understood how nondirectional stimuli, such as ambient temperatures, specify the polarity of nastic behaviors. Here, we demonstrate that a developmentally programmed polarity of auxin flow underlies thermo-induced leaf hyponasty in Arabidopsis (Arabidopsis thaliana). In warm environments, PHYTOCHROME-INTERACTING FACTOR4 (PIF4) stimulates auxin production in the leaf. This results in the accumulation of auxin in leaf petioles, where PIF4 directly activates a gene encoding the PINOID (PID) protein kinase. PID is involved in polarization of the auxin transporter PIN-FORMED3 to the outer membranes of petiole cells. Notably, the leaf polarity-determining ASYMMETRIC LEAVES1 (AS1) directs the induction of PID to occur predominantly in the abaxial petiole region. These observations indicate that the integration of PIF4-mediated auxin biosynthesis and polar transport, and the AS1-mediated developmental shaping of polar auxin flow, coordinate leaf thermonasty, which facilitates leaf cooling in warm environments. We believe that leaf thermonasty is a suitable model system for studying the developmental programming of environmental adaptation in plants.
© 2019 American Society of Plant Biologists. All Rights Reserved.

Entities:  

Year:  2019        PMID: 30948554      PMCID: PMC6548248          DOI: 10.1104/pp.19.00139

Source DB:  PubMed          Journal:  Plant Physiol        ISSN: 0032-0889            Impact factor:   8.340


  48 in total

1.  High temperature exposure increases plant cooling capacity.

Authors:  Amanda J Crawford; Deirdre H McLachlan; Alistair M Hetherington; Keara A Franklin
Journal:  Curr Biol       Date:  2012-05-22       Impact factor: 10.834

2.  Eleven golden rules of quantitative RT-PCR.

Authors:  Michael K Udvardi; Tomasz Czechowski; Wolf-Rüdiger Scheible
Journal:  Plant Cell       Date:  2008-07-29       Impact factor: 11.277

3.  Polarization of PIN3-dependent auxin transport for hypocotyl gravitropic response in Arabidopsis thaliana.

Authors:  Hana Rakusová; Javier Gallego-Bartolomé; Marleen Vanstraelen; Hélène S Robert; David Alabadí; Miguel A Blázquez; Eva Benková; Jiří Friml
Journal:  Plant J       Date:  2011-06-29       Impact factor: 6.417

4.  Dynamic PIN-FORMED auxin efflux carrier phosphorylation at the plasma membrane controls auxin efflux-dependent growth.

Authors:  Benjamin Weller; Melina Zourelidou; Lena Frank; Inês C R Barbosa; Astrid Fastner; Sandra Richter; Gerd Jürgens; Ulrich Z Hammes; Claus Schwechheimer
Journal:  Proc Natl Acad Sci U S A       Date:  2017-01-17       Impact factor: 11.205

5.  FCA mediates thermal adaptation of stem growth by attenuating auxin action in Arabidopsis.

Authors:  Hyo-Jun Lee; Jae-Hoon Jung; Lucas Cortés Llorca; Sang-Gyu Kim; Sangmin Lee; Ian T Baldwin; Chung-Mo Park
Journal:  Nat Commun       Date:  2014-11-17       Impact factor: 14.919

Review 6.  Ethylene-Mediated Acclimations to Flooding Stress.

Authors:  Rashmi Sasidharan; Laurentius A C J Voesenek
Journal:  Plant Physiol       Date:  2015-04-20       Impact factor: 8.340

7.  A role for AUXIN RESISTANT3 in the coordination of leaf growth.

Authors:  José Manuel Pérez-Pérez; Héctor Candela; Pedro Robles; Gema López-Torrejón; Juan C del Pozo; José Luis Micol
Journal:  Plant Cell Physiol       Date:  2010-08-24       Impact factor: 4.927

8.  Plasma membrane-bound AGC3 kinases phosphorylate PIN auxin carriers at TPRXS(N/S) motifs to direct apical PIN recycling.

Authors:  Pankaj Dhonukshe; Fang Huang; Carlos S Galvan-Ampudia; Ari Pekka Mähönen; Jurgen Kleine-Vehn; Jian Xu; Ab Quint; Kalika Prasad; Jirí Friml; Ben Scheres; Remko Offringa
Journal:  Development       Date:  2010-10       Impact factor: 6.868

9.  Nucleocytoplasmic shuttling of BZR1 mediated by phosphorylation is essential in Arabidopsis brassinosteroid signaling.

Authors:  Hojin Ryu; Kangmin Kim; Hyunwoo Cho; Joonghyuk Park; Sunghwa Choe; Ildoo Hwang
Journal:  Plant Cell       Date:  2007-09-14       Impact factor: 11.277

10.  PIN auxin efflux carrier polarity is regulated by PINOID kinase-mediated recruitment into GNOM-independent trafficking in Arabidopsis.

Authors:  Jürgen Kleine-Vehn; Fang Huang; Satoshi Naramoto; Jing Zhang; Marta Michniewicz; Remko Offringa; Jirí Friml
Journal:  Plant Cell       Date:  2009-12-29       Impact factor: 11.277
View more
  19 in total

1.  Why Do Leaves Rise with the Temperature?

Authors:  Scott Hayes
Journal:  Plant Physiol       Date:  2019-06       Impact factor: 8.340

Review 2.  Developmental Plasticity at High Temperature.

Authors:  Lam Dai Vu; Xiangyu Xu; Kris Gevaert; Ive De Smet
Journal:  Plant Physiol       Date:  2019-07-30       Impact factor: 8.340

3.  Synchronization of photoperiod and temperature signals during plant thermomorphogenesis.

Authors:  Young-Joon Park; June-Hee Lee; Jae Young Kim; Chung-Mo Park
Journal:  Plant Signal Behav       Date:  2020-03-12

4.  The cold response regulator CBF1 promotes Arabidopsis hypocotyl growth at ambient temperatures.

Authors:  Xiaojing Dong; Yan Yan; Bochen Jiang; Yiting Shi; Yuxin Jia; Jinkui Cheng; Yihao Shi; Juqing Kang; Hong Li; Dun Zhang; Lijuan Qi; Run Han; Shaoman Zhang; Yangyang Zhou; Xiaoji Wang; William Terzaghi; Hongya Gu; Dingming Kang; Shuhua Yang; Jigang Li
Journal:  EMBO J       Date:  2020-05-25       Impact factor: 11.598

5.  Developmental polarity shapes thermo-induced nastic movements in plants.

Authors:  Jae Young Kim; Young-Joon Park; June-Hee Lee; Chung-Mo Park
Journal:  Plant Signal Behav       Date:  2019-05-14

6.  MEDIATOR SUBUNIT17 integrates jasmonate and auxin signaling pathways to regulate thermomorphogenesis.

Authors:  Rekha Agrawal; Mohan Sharma; Nidhi Dwivedi; Sourobh Maji; Pallabi Thakur; Alim Junaid; Jiří Fajkus; Ashverya Laxmi; Jitendra K Thakur
Journal:  Plant Physiol       Date:  2022-08-01       Impact factor: 8.005

7.  SMAX1 potentiates phytochrome B-mediated hypocotyl thermomorphogenesis.

Authors:  Young-Joon Park; Jae Young Kim; Chung-Mo Park
Journal:  Plant Cell       Date:  2022-07-04       Impact factor: 12.085

8.  An ATP-Binding Cassette Transporter, ABCB19, Regulates Leaf Position and Morphology during Phototropin1-Mediated Blue Light Responses.

Authors:  Mark K Jenness; Reuben Tayengwa; Angus S Murphy
Journal:  Plant Physiol       Date:  2020-08-27       Impact factor: 8.340

9.  A dual mode of ethylene actions contributes to the optimization of hypocotyl growth under fluctuating temperature environments.

Authors:  Jae Young Kim; Chung-Mo Park
Journal:  Plant Signal Behav       Date:  2021-05-11

10.  The membrane-localized protein kinase MAP4K4/TOT3 regulates thermomorphogenesis.

Authors:  Xiangyu Xu; Tingting Zhu; Kris Gevaert; Ive De Smet; Lam Dai Vu; Lixia Pan; Martijn van Zanten; Dorrit de Jong; Yaowei Wang; Tim Vanremoortele; Anna M Locke; Brigitte van de Cotte; Nancy De Winne; Elisabeth Stes; Eugenia Russinova; Geert De Jaeger; Daniël Van Damme; Cristobal Uauy
Journal:  Nat Commun       Date:  2021-05-14       Impact factor: 14.919
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.