Cis- and trans-acting elements involved in amino acid regulation of asparagine synthetase gene expression.

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Mol Cell Biol. 1993 June; 13(6): 3202-3212

Cis- and trans-acting elements involved in amino acid regulation of asparagine synthetase gene expression.

L Guerrini, S S Gong, K Mangasarian and C Basilico

Department of Microbiology, New York University School of Medicine, New York 10016.

ABSTRACT

We have previously shown that asparagine synthetase (AS) mRNAexpression can be dramatically up-regulated by asparagine deprivationin ts11 cells, mutants of BHK hamster cells which encode a temperature-sensitiveAS. The expression of AS mRNA was also induced upon starvationfor one of several essential amino acids in HeLa cells. We alsoshowed that regulation of AS mRNA expression by amino acid concentrationhas both transcriptional and posttranscriptional components.Here we report the analysis of the elements in the human ASpromoter region important for its basal activity and activationby amino acid starvation. Our results indicate that a DNA fragmentspanning from nucleotides -164 to +44 of the AS promoter issufficient for uninduced and induced gene expression. Mutationsin a region located 15 to 30 bp downstream from the major transcriptionstart site that shows good homology to a sequence in the firstexon of c-fos implicated as a negative regulatory element resultedin a significant increase in basal gene expression but did notaffect regulation. Interestingly, this region binds single-stranded-DNA-bindingproteins that are specific for the AS coding strand. Mutationsin either one of two putative binding sites for transcriptionfactor Sp1, in a region of approximately 60 bp where many minorRNA start sites are located, or at the major transcription startsite decreased promoter activity, but significant inductionby amino acid starvation was still observed. Strikingly, mutationscentered around nucleotide -68 not only decreased the basalpromoter activity but also abolished amino acid regulation.This DNA region contains the sequence 5'-CATGATG-3', which wecall the amino acid response element (AARE), that can bind afactor(s) present in HeLa cells nuclear extracts that is notcapable of binding to an AS promoter with mutations or deletionsof the AARE. This finding is in line with the hypothesis thattranscriptional activation of AS gene expression is mediatedthrough the binding of a positive regulatory element. We didnot detect changes in the level of binding of this factor tothe AARE by using nuclear extracts from HeLa cells grown understarved conditions, suggesting that activation of this factor(s)results from posttranslational modification or complexing withother proteins that do not affect its DNA-binding properties.

Mol Cell Biol. 1993 June; 13(6): 3202-3212

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