AUUUA motifs in the 3'UTR of human glucocorticoid receptor alpha and beta mRNA destabilize mRNA and decrease receptor protein expression

An association between a gene polymorphism of the human glucocorticoid receptor (hGR) gene and rheumatoid arthritis has recently been suggested. This polymorphism contains an A to G mutation in the 3'UTR of exon 9beta, which encodes the 3'UTR of the mRNA of the hGRbeta isoform. The hGRbeta isoform can act as a dominant negative inhibitor of hGRalpha, and therefore may contribute to glucocorticoid resistance. The A to G mutation is located in an AUUUA motif, which is known to destabilize mRNA. In the present study, the importance of the mutation in this AUUUA motif was further characterized and mutations in other AUUUA motifs in the 3'UTR of hGRbeta and hGRalpha mRNA were studied. hGRbeta and hGRalpha expression vectors, carrying mutations in one AUUUA motif or all AUUUA motifs were transiently transfected into COS-1 cells. Each transfected vector was analyzed for the mRNA expression level, the mRNA turnover rate and the protein expression level. The naturally occurring mutation in the 3'UTR of hGRbeta mRNA increased mRNA stability and protein expression. Mutation of two other AUUUA motifs in the 3'UTR of hGRbeta, or mutation of all four AUUUA motifs resulted in a similar effect. Mutation of the most 5' AUUUA motif did not alter hGRbeta mRNA expression or mRNA stability. Mutation of all 10 AUUUA motifs in the 3'UTR of hGRalpha mRNA increased hGRalpha mRNA expression and mRNA stability as well as expression of the receptor protein level. Thus, the naturally occurring mutation in an AUUUA motif in the 3'UTR of hGRbeta mRNA results not only in increased mRNA stability, but also in increased receptor protein expression, which may contribute to glucocorticoid resistance. A similar role is suggested for two other AUUUA motifs in the 3'UTR of hGRbeta mRNA and for the 10 AUUUA motifs that are present in the 3'UTR of hGRalpha.     

Molecular origins for the dominant negative function of human glucocorticoid receptor beta

This study molecularly elucidates the basis for the dominant negative mechanism of the glucocorticoid receptor (GR) isoform hGRbeta, whose overexpression is associated with human glucocorticoid resistance. Using a series of truncated hGRalpha mutants and sequential mutagenesis to generate a series of hGRalpha/beta hybrids, we find that the absence of helix 12 is neither necessary nor sufficient for the GR dominant negative phenotype. Moreover, we have localized the dominant negative activity of hGRbeta to two residues and found that nuclear localization, in addition to heterodimerization, is a critical feature of the dominant negative activity. Molecular modeling of wild-type and mutant hGRalpha and hGRbeta provides structural insight and a potential physical explanation for the lack of hormone binding and the dominant negative actions of hGRbeta.     

Interaction of glucocorticoid analogues with the human glucocorticoid receptor

Transient co-transfection of receptor cDNA and suitable reporter genes was used to study human glucocorticoid receptor (hGR) function in a neutral mammalian cell background. A variety of natural and synthetic steroids were analyzed for their ability to activate gene expression through the hGR and to bind to extracts of cells expressing the hGR cDNA. There was very good correlation between these two in vitro parameters for these compounds. Furthermore, correlation of these data with reported in vivo anti-inflammatory potencies was surprisingly close, with two exceptions. The in vitro data suggest an explanation for the discrepant compounds, consistent with published data on their metabolic fate in vivo. The co-transfection assay has utility as a quantitative predictor of in vivo glucocorticoid pharmacology.     

Induction of gene expression by exon 2 of the major E1A proteins of adenovirus type 5.

We have constructed an adenovirus type 5 (Ad5) E1A mutant, dl1119/520, that produces essentially only exon 2 of the major E1A proteins. In infected primary baby rat kidney cells, this mutant induced expression of the E1B 55-kDa protein, and in infected human KB cells, it induced expression of this protein, the E2A 72-kDa protein, and hexon. In KB cells, this mutant grew substantially better than Ad5 dl312, which lacks E1A, and as well as Ad5 dl520, an E1A mutant producing only the 243-residue protein. These results suggest that exon 2 of E1A proteins on its own was able to activate gene expression. We also constructed mutants of dl1119/520, containing small deletions in regions of exon 2 that others found to be associated with effects on the properties of E1A transformants. None of these deletions destroyed gene activation completely, indicating that there may be some redundancy among sequences in exon 2 for inducing gene expression. The two deletions that decreased induction the most, residues 224 to 238 and 255 to 270, were in regions reported to be associated with the expression of a metalloprotease and with enhanced transformation, suggesting that exon 2 may regulate expression of genes governing cell growth. It is remarkable that all sections of E1A proteins, exon 1, the unique region, and exon 2, have now been found to affect gene expression.