The Initiator Motif is Preferentially Used as the Core Promoter Element in Ionizing Radiation-Responsive Genes

The Initiator Motif is Preferentially Used as the Core Promoter Element in Ionizing Radiation-Responsive Genes

Wu, J., Daino, K., Ichimura, S. and Nenoi, M. The Initiator Motif is Preferentially Used as the Core Promoter Element in Ionizing Radiation-Responsive Genes. Radiat. Res. 166, 810– 813 (2006). Recent improvements in DNA microarray technologies and bioinformatics have made it possible to look for com...

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Veröffentlicht in:Radiation research 2006-11, Vol.166 (5), p.810-813
Hauptverfasser: Wu, Jianyu, Daino, Kazuhiro, Ichimura, Sachiko, Nenoi, Mitsuru
Format: Artikel
Sprache:eng
Schlagworte:
Blood cells
Blood Proteins - genetics
Blood Proteins - radiation effects
Cell cycle
Cells
Codon, Initiator - genetics
Gene expression regulation
Genes
Humans
Ionizing radiation
Irradiation
Promoter regions
Promoter Regions, Genetic - genetics
Radiation Tolerance - genetics
Radiation, Ionizing
RNA
SHORT COMMUNICATION
Space life sciences
TATA-Box Binding Protein - genetics
Transcription, Genetic - genetics
Transcription, Genetic - radiation effects
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container_end_page 813
container_issue 5
container_start_page 810
container_title Radiation research
container_volume 166
creator Wu, Jianyu
Daino, Kazuhiro
Ichimura, Sachiko
Nenoi, Mitsuru
description Wu, J., Daino, K., Ichimura, S. and Nenoi, M. The Initiator Motif is Preferentially Used as the Core Promoter Element in Ionizing Radiation-Responsive Genes. Radiat. Res. 166, 810– 813 (2006). Recent improvements in DNA microarray technologies and bioinformatics have made it possible to look for common features of ionizing radiation-responsive genes and their regulatory regions. We analyzed the promoters of 217 radiation-responsive human genes, compiled from microarray databases available in the literature. Using the DBTSS database, the transcriptional start sites were determined, and the core promoter elements, such as the TATA-box, initiator (Inr), GC-box and CCAAT-box, were searched for in the −1000 bp/ +200 bp region of each gene by using MATCH. It was found that the frequency of Inr in radiation-responsive genes was higher than that in general genes, and the frequencies of the GC-box and CCAAT-box were significantly lower than those in general genes. Use of the GC-box and the CCAAT-box in radiation-responsive genes was found to be dependent on the TATA-box status; that is, GC-box frequency was low in TATA box-containing genes, and CCAAT-box frequency was also low in TATA-less genes. When correlations between gene functions and frequencies of core promoter elements were examined, no apparent biased use of the core promoter element in association with a specific gene function was observed. It may be speculated that use of Inr in the core promoter correlates with appearance of radiation-responsive enhancer (silencer) elements in the upstream (downstream) regulatory region.
doi_str_mv 10.1667/RR0570.1
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Use of the GC-box and the CCAAT-box in radiation-responsive genes was found to be dependent on the TATA-box status; that is, GC-box frequency was low in TATA box-containing genes, and CCAAT-box frequency was also low in TATA-less genes. When correlations between gene functions and frequencies of core promoter elements were examined, no apparent biased use of the core promoter element in association with a specific gene function was observed. 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The Initiator Motif is Preferentially Used as the Core Promoter Element in Ionizing Radiation-Responsive Genes. Radiat. Res. 166, 810– 813 (2006). Recent improvements in DNA microarray technologies and bioinformatics have made it possible to look for common features of ionizing radiation-responsive genes and their regulatory regions. We analyzed the promoters of 217 radiation-responsive human genes, compiled from microarray databases available in the literature. Using the DBTSS database, the transcriptional start sites were determined, and the core promoter elements, such as the TATA-box, initiator (Inr), GC-box and CCAAT-box, were searched for in the −1000 bp/ +200 bp region of each gene by using MATCH. It was found that the frequency of Inr in radiation-responsive genes was higher than that in general genes, and the frequencies of the GC-box and CCAAT-box were significantly lower than those in general genes. 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subjects Blood cells
Blood Proteins - genetics
Blood Proteins - radiation effects
Cell cycle
Cells
Codon, Initiator - genetics
Gene expression regulation
Genes
Humans
Ionizing radiation
Irradiation
Promoter regions
Promoter Regions, Genetic - genetics
Radiation Tolerance - genetics
Radiation, Ionizing
RNA
SHORT COMMUNICATION
Space life sciences
TATA-Box Binding Protein - genetics
Transcription, Genetic - genetics
Transcription, Genetic - radiation effects
title The Initiator Motif is Preferentially Used as the Core Promoter Element in Ionizing Radiation-Responsive Genes
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