TY - JOUR
T1 - AtSAP18, an orthologue of human SAP18, is involved in the regulation of salt stress and mediates transcriptional repression in Arabidopsis
AU - Song, Chun Peng
AU - Galbraith, David W.
N1 - Funding Information:
This work was supported by a grant from the NSF Plant Genome program (DBI-9813360) and, in part, by the Arizona Agricultural Experiment Station, and by the National Key Basic Special Funds of China (2003CB114305). We thank Dr W.B. Gurley (University of Florida) for providing the Gal4-DBD-VP16 and CaMV35S-GUS plasmids, Dr J.-K. Zhu for plasmids pAS2 and pACT2 and the yeast Y190 strain, and Dr B. Larkins for the pGex-2TK plasmid and gold-particles. We thank Drs. Song-Qin Pan and Michael Deyholos, and Dominic Decianne, Harry Rekapally, and Georgina Lambert for technical assistance and advice.
PY - 2006/1
Y1 - 2006/1
N2 - In yeast and mammalian systems, it is well established that transcriptional down-regulation by DNA-binding repressors involves core histone deacetylation, mediated by their interaction within a complex containing histone deacetylase (e.g. HDA1), as well as various other proteins (e.g. SIN3, SAP18, SAP30, and RbAp46). Here we identify that a Arabidopsis thaliana gene related in sequence to SAP18, designated AtSAP18, functions in transcription regulation in plants subjected to salt stress. The AtSAP18 loss- of-function mutant is more sensitive to NaCl, and is impaired in chlorophyll synthesis as compared to the wild-type. Using GST pull-down, two-hybrid, and transient transcription assays, we have characterized SAP18 and HDA1 orthologues and provide evidence that SAP18 and HDA1 function as transcriptional repressors. We further demonstrate that they associate with Ethylene-Responsive Element binding Factors (ERFs) to create a hormone-sensitive multimeric repressor complex under conditions of environmental stress. Our results indicate that AtSAP18 functions to link the HDA complex to transcriptional repressors that are bound to chromatin in a sequence-specific manner, thereby providing the specificity of signal transduction accompanying transcriptional repression under stress conditions.
AB - In yeast and mammalian systems, it is well established that transcriptional down-regulation by DNA-binding repressors involves core histone deacetylation, mediated by their interaction within a complex containing histone deacetylase (e.g. HDA1), as well as various other proteins (e.g. SIN3, SAP18, SAP30, and RbAp46). Here we identify that a Arabidopsis thaliana gene related in sequence to SAP18, designated AtSAP18, functions in transcription regulation in plants subjected to salt stress. The AtSAP18 loss- of-function mutant is more sensitive to NaCl, and is impaired in chlorophyll synthesis as compared to the wild-type. Using GST pull-down, two-hybrid, and transient transcription assays, we have characterized SAP18 and HDA1 orthologues and provide evidence that SAP18 and HDA1 function as transcriptional repressors. We further demonstrate that they associate with Ethylene-Responsive Element binding Factors (ERFs) to create a hormone-sensitive multimeric repressor complex under conditions of environmental stress. Our results indicate that AtSAP18 functions to link the HDA complex to transcriptional repressors that are bound to chromatin in a sequence-specific manner, thereby providing the specificity of signal transduction accompanying transcriptional repression under stress conditions.
KW - Arabidopsis thaliana
KW - Histone deacetylation
KW - Stress
KW - Transcriptional repression
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U2 - 10.1007/s11103-005-3880-9
DO - 10.1007/s11103-005-3880-9
M3 - Article
C2 - 16429262
AN - SCOPUS:31044443976
SN - 0167-4412
VL - 60
SP - 241
EP - 257
JO - Plant Molecular Biology
JF - Plant Molecular Biology
IS - 2
ER -