Abstract
Transcription from the asparagine synthetase (A.S.) gene is increased in response to either amino acid (amino acid response) or glucose (endoplasmic reticulum stress response) deprivation. These two independent pathways converge on the same set of genomic cis-elements within the A.S. promoter referred to as nutrient-sensing response elements (NSRE) 1 and 2, both of which are necessary for gene activation. The NSRE-1 sequence was used to screen ATF/CREB family members by electrophoresis mobility shift assays and supershift by specific antibodies. The results indicated that ATF4 binds to the NSRE-1 sequence and that the amount of the ATF4 complex was increased when extracts from amino acid-deprived or glucose-deprived cells were tested. Using electrophoresis mobility shift assay experiments and a probe that contained both NSRE-1 and NSRE-2, mutation of the NSRE-1 sequence completely prevented formation of the ATF4-containing complexes, whereas mutation of the NSRE-2 sequence did not. Overexpression of ATF4 increased A.S. promoter-driven transcription, whereas an inhibitory dominant negative ATF4 mutant blocked both basal and starvation-enhanced transcription. Collectively, the results provide both in vitro and in vivo evidence for a role of ATF4 in the transcriptional activation of the A.S. gene in response to nutrient deprivation.
Highlights
Amino acid availability is an important factor in protein biosynthesis and degradation
Two separate cis-elements, nutrientsensing response elements (NSRE)-1 and NSRE-2, are both required for induction of the A.S. gene in response to activation of the amino acid-deprived (AAR) or endoplasmic reticulum stress response (ERSR) pathways [12]
Given that ATF4 mRNA translation is enhanced by amino acid deprivation [20], ATF4 was a potential regulator of A.S. transcription
Summary
Amino acid availability is an important factor in protein biosynthesis and degradation. Guerrini et al [9] identified a region from nt Ϫ70 to Ϫ62 within the human A.S. promoter that functioned as an amino acid response element (AARE). The NSRE-1 sequence is highly similar to an element in the human chop gene (5ЈTGATGCAAT-3Ј, Ϫ301 to Ϫ310) that functions as an AARE [15] and has been termed a C/EBP-ATF composite site [16, 17]. These sites appear to bind to C/EBP-ATF heterodimers. ATF4 Modulates the Human A.S. Gene of that shifted complex was increased when extracts from amino acid-deprived (AAR) or glucose-deprived (ERSR) cells were used. Overexpression of ATF4 caused increased basal transcription from the A.S. promoter, whereas expression of a dominant negative of the ATF4 mutant in HepG2 cells blocked transcriptional induction driven by the
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