RACK1 is a negative regulator of ABA responses in Arabidopsis

Guo, Jianjun; Wang, Junbi; Li, Xi; Huang, Weidong; Liang, Jiansheng; Chen, Jay

doi:10.1093/jxb/erp221

Cited by 106 publications

(115 citation statements)

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“…All three Arabidopsis RACK1s are detected in ribosomes Giavalisco et al, 2005;Carroll et al, 2008;Piques et al, 2009;Turkina et al, 2011;Hummel et al, 2012;Carroll, 2013), functionally complement a CPC2/RACK mutant of yeast, and interact with eIF6 (Guo et al, 2011a). Interestingly, single and multiple RACK1 mutants cause a variety of developmental abnormalities and enhance responsiveness to abscisic acid (ABA) (Guo et al, 2009;Guo et al, 2011b). Double mutants of rack1a rack1b are hypersensitive to anisomycin, an inhibitor of peptide elongation and display slightly reduced levels of 80S ribosomes under normal growth conditions and following ABA treatment (Guo and Chen, 2008).…”

Section: Rack1 a Ribosome Interacting Playermentioning

confidence: 99%

Mechanism of Cytoplasmic mRNA Translation

Browning

Bailey‐Serres

2015

The Arabidopsis Book

187

220

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Protein synthesis is a fundamental process in gene expression that depends upon the abundance and accessibility of the mRNA transcript as well as the activity of many protein and RNA-protein complexes. Here we focus on the intricate mechanics of mRNA translation in the cytoplasm of higher plants. This chapter includes an inventory of the plant translational apparatus and a detailed review of the translational processes of initiation, elongation, and termination. The majority of mechanistic studies of cytoplasmic translation have been carried out in yeast and mammalian systems. The factors and mechanisms of translation are for the most part conserved across eukaryotes; however, some distinctions are known to exist in plants. A comprehensive understanding of the complex translational apparatus and its regulation in plants is warranted, as the modulation of protein production is critical to development, environmental plasticity and biomass yield in diverse ecosystems and agricultural settings.

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Section: Rack1 a Ribosome Interacting Playermentioning

confidence: 99%

Mechanism of Cytoplasmic mRNA Translation

Browning

Bailey‐Serres

2015

The Arabidopsis Book

187

220

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“…Most of what we know comes from physiological analysis of rack1 mutants. Rack1 loss of function mutants display various developmental defects, specifically slow growth, dwarfism, and seedling-lethality in rack1a rack1b rack1c triple mutants (Chen et al, 2006;Guo and Chen, 2008;Guo et al, 2009). The rack1 mutants are less sensitive to gibberellic acid and hypersensitive to abscisic acid and show an mRNA expression profile reminiscent of ABA application (Guo et al, 2011).…”

Section: Rack1mentioning

confidence: 99%

Translational Regulation of Cytoplasmic mRNAs

Roy

Arnim

2013

The Arabidopsis Book

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Translation of the coding potential of a messenger RNA into a protein molecule is a fundamental process in all living cells and consumes a large fraction of metabolites and energy resources in growing cells. Moreover, translation has emerged as an important control point in the regulation of gene expression. At the level of gene regulation, translational control is utilized to support the specific life histories of plants, in particular their responses to the abiotic environment and to metabolites. This review summarizes the diversity of translational control mechanisms in the plant cytoplasm, focusing on specific cases where mechanisms of translational control have evolved to complement or eclipse other levels of gene regulation. We begin by introducing essential features of the translation apparatus. We summarize early evidence for translational control from the pre-Arabidopsis era. Next, we review evidence for translation control in response to stress, to metabolites, and in development. The following section emphasizes RNA sequence elements and biochemical processes that regulate translation. We close with a chapter on the role of signaling pathways that impinge on translation.

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“…8,9 Similar to mammalian RACK1, plant RACK1 interacts with a large group of proteins 10,11 and is involved in diverse biological processes, ranging from seed germination, leaf and root development to flowering, 8,12 and is also involved in responses to plant hormones, 8,13 and biotic and abiotic stresses. [13][14][15] At the molecular level, RACK1 protein is associated with ribosomes [16][17][18] and is involved in the regulation of protein translation 18 and miRNA abundance. 19 It is less clear how RACK1 is able to participate in so many different biological processes.…”

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confidence: 99%

“…For example, the transcription of RACK1 is suppressed by the plant stress hormone abscisic acid (ABA). 13 It was suggested that such transcriptional regulation likely contributes to RACK1's negative regulation of ABA responses in the ABA-mediated inhibition of seed germination, early seedling development, and ABA-induced gene expression. 13 More recently, it was demonstrated that RACK1 is also regulated at the post-translational level.…”

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confidence: 99%

“…13 It was suggested that such transcriptional regulation likely contributes to RACK1's negative regulation of ABA responses in the ABA-mediated inhibition of seed germination, early seedling development, and ABA-induced gene expression. 13 More recently, it was demonstrated that RACK1 is also regulated at the post-translational level. 20 It was found that RACK1 protein is subject to phosphorylation and that phosphorylation of RACK1 renders it unstable.…”

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confidence: 99%

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