Differential expression and localization of the mRNA binding proteins, AU-rich element mRNA binding protein (AUF1) and Hu antigen R (HuR), in neoplastic lung tissue.

Modulation of gene expression at the level of mRNA stability has emerged as an important regulatory paradigm. In this context, differential expression of numerous mRNAs in normal versus neoplastic tissues has been described. Altered expression of these genes, at least in part, has been demonstrated to be at the level of mRNA stability. Two ubiquitously expressed mRNA binding proteins have recently been implicated in the stabilization (Hu antigen R/HuR) or destabilization (AU-rich element mRNA binding protein [AUF1]/heterogeneous nuclear ribonucleoprotein D) of target mRNAs. Further, their functional activity appears to require cytoplasmic localization. In the present study, we demonstrate a strong correlation between increased cytoplasmic expression of both AUF1 and HuR with urethane-induced neoplasia and with butylated hydroxytoluene-induced compensatory hyperplasia in mouse lung tissue. In addition, when compared with slower growing cells, rapidly growing neoplastic lung epithelial cell lines expressed a consistently higher abundance of both AUF1 and HuR proteins. Moreover, in nontumorigenic cell lines, both AUF1 and HuR protein abundance decreased with confluence and growth arrest. In contrast, in spontaneous transformants, AUF1 and HuR abundance was unaffected by changes in cell density. We suggest that growth-regulated alterations in AUF1 and HuR abundance may have pleiotropic effects on the expression of a number of highly regulated mRNAs and that this significantly impacts the onset, maintenance, and progression of the neoplastic phenotype. Mol. Carcinog. 28:76-83, 2000.

Myocardial-directed overexpression of the human beta(1)-adrenergic receptor in transgenic mice.

The beta(1)-adrenergic receptor (AR) is the dominant subtype in non-failing and failing myocardium. beta(1)-AR signaling, by the endogenous neurotransmitter norepinephrine, is central to the regulation of myocardial contractility. In heart failure, the beta(1)-AR undergoes subtype-selective downregulation which may protect against the increased cardiac adrenergic drive associated with this pathophysiological state. To examine the hypothesis that chronically increased beta(1)-AR mediated signaling has adverse myocardial effects, transgenic mice overexpressing the human beta(1)-AR in a cardiac-selective context were produced, utilizing an alpha-myosin heavy chain (MHC) promoter. In these mice, beta(1)-AR protein abundance was approximately 24-46-fold (1-2 pmol/mg protein) that of wild-type mice. Histopathological examination of young (4 months old) and old (approximately 9 months old) transgenic mouse hearts consistently demonstrated large areas of interstitial replacement fibrosis, marked myocyte hypertrophy and myofibrilar disarray. In addition, increased expression of the pre-apoptotic marker, Bax, was observed coincident with regions of fibrosis accompanied by an increased apoptotic index, as measured by TUNEL assay. Older non-transgenic mice exhibited a slight tendency towards a decreased fractional shortening, whereas older beta(1)-AR transgenic mice had a marked reduction in fractional shortening (%FS approximately 30) as determined by echocardiography. Additionally, older beta(1)-AR transgenic mice had an increased left ventricular chamber size. In summary, cardiac-directed overexpression of the human beta(1)-AR in transgenic mice leads to a significant histopathological phenotype with no apparent functional consequence in younger mice and a variable degree of cardiac dysfunction in older animals. This model system may ultimately prove useful for investigating the biological basis of adrenergically-mediated myocardial damage in humans.

Purification and characterization of beta-adrenergic receptor mRNA-binding proteins.

Beta-adrenergic receptors (beta-ARs), like other G-protein-coupled receptors, can undergo post-transciptional regulation at the level of mRNA stability. In particular, the human beta(1)- and beta(2)-ARs and the hamster beta(2)-AR mRNA undergo beta-agonist-mediated destabilization. By UV cross-linking, we have previously described an approximately M(r) 36,000 mRNA-binding protein, betaARB, that binds to A/C+U-rich nucleotide regions within 3'-untranslated regions. Further, we have demonstrated previously that betaARB is immunologically distinct from AUF1/heterogeneous nuclear ribonucleoprotein (hnRNP) D, another mRNA-binding protein associated with destabilization of A+U-rich mRNAs (Pende, A., Tremmel, K. D., DeMaria, C. T., Blaxall, B. C., Minobe, W., Sherman, J. A., Bisognano, J., Bristow, M. R., Brewer, G., and Port, J. D. (1996) J. Biol. Chem. 271, 8493-8501). In this report, we describe the peptide composition of betaARB. Mass spectrometric analysis of an approximately M(r) 36,000 band isolated from ribosomal salt wash proteins revealed the presence of two mRNA-binding proteins, hnRNP A1, and the elav-like protein, HuR, both of which are known to bind to A+U-rich nucleotide regions. By immunoprecipitation, HuR appears to be the biologically dominant RNA binding component of betaARB. Although hnRNP A1 and HuR can both be immunoprecipitated from ribosomal salt wash proteins, the composition of betaARB (HuR alone versus HuR and hnRNP A1) appears to be dependent on the mRNA probe used. The exact role of HuR and hnRNP A1 in the regulation of beta-AR mRNA stability remains to be determined.

Agonist-mediated destabilization of human beta1-adrenergic receptor mRNA: role of the 3' untranslated translated region.

For proto-oncogenes and cytokines, regulation of gene expression at the level of mRNA stability is well established. In contrast, there is comparatively limited knowledge regarding this mechanism of regulation for G-protein-coupled receptors. To explore this process further, the human beta1-adrenergic receptor (AR) was stably expressed in tsAF8 cells. Treatment with beta-agonist decreased the half-life of beta1-AR mRNA by approximately 50%. Removal of the 3'UTR from the beta1-AR (coding region only) dramatically stabilized mRNA. Additionally, in a chimeric mRNA, the beta1-AR 3'UTR was able to target the normally highly stable beta-globin mRNA for accelerated decay. However, the chimera did not undergo agonist-mediated destabilization indicating that the 3'UTR may be "necessary but not sufficient" for agonist-mediated mRNA destabilization. Inhibition of translation significantly stabilized beta1-AR mRNA (approximately 2-fold); however, pretreatment of cells with beta-agonist prior to translational arrest produced the same degree of mRNA destabilization indicating that agonist-mediated destabilization may be independent of the translation process. Conversely, translational inhibition simultaneous with beta-agonist exposure abrogated agonist-mediated destabilization indicating a dependence on de novo protein synthesis.

Regulation of the mRNA-binding protein AUF1 by activation of the beta-adrenergic receptor signal transduction pathway.

In both cell culture based model systems and in the failing human heart, beta-adrenergic receptors ( beta-AR) undergo agonist-mediated down-regulation. This decrease correlates closely with down-regulation of its mRNA, an effect regulated in part by changes in mRNA stability. Regulation of mRNA stability has been associated with mRNA-binding proteins that recognize A + U-rich elements within the 3'-untranslated regions of many mRNAs encoding proto-oncogene and cytokine mRNAs. We demonstrate here that the mRNA-binding protein, AUF1, is present in both human heart and in hamster DDT1-MF2 smooth muscle cells and that its abundance is regulated by beta-AR agonist stimulation. In human heart, AUF1 mRNA and protein was significantly increased in individuals with myocardial failure, a condition associated with increases in the beta-adrenergic receptor agonist norepinephrine. In the same hearts, there was a significant decrease (approximately 50%) in the abundance of beta1-AR mRNA and protein. In DDT1-MF2 cells, where agonist-mediated destabilization of beta2-AR mRNA was first described, exposure to beta-AR agonist resulted in a significant increase in AUF1 mRNA and protein (approximately 100%). Conversely, agonist exposure significantly decreased (approximately 40%) beta2-adrenergic receptor mRNA abundance. Last, we demonstrate that AUF1 can be immunoprecipitated from polysome-derived proteins following UV cross-linking to the 3'-untranslated region of the human beta1-AR mRNA and that purified, recombinant p37AUF1 protein also binds to beta1-AR 3'-untranslated region mRNA.

Quantification of the interaction between lysolecithin and phospholipase A2.

The rate of hydrolysis of phosphatidylcholine bilayers by phospholipase A2 may be either enhanced or inhibited by the presence of lysolecithin depending on the experimental conditions examined. To further understand the relationship of lysolecithin to phospholipase A2 activity, the binding of lysolecithin to phospholipase A2 from the venom of Agkistrodon piscivorus piscivorus was examined by fluorescence spectroscopy. The tryptophan emission intensity of the enzyme was enhanced by 70% upon addition of lysolecithin. The binding isotherm for lysolecithin to the phospholipase A2 estimated from the fluorescence change was biphasic, with a clear break in the curve occurring at the critical micelle concentration of the lysolecithin. Several observations suggested that the phospholipase A2 was capable of hydrolyzing the lysolecithin although at a rate far below that of phospholipid hydrolysis. These experiments were repeated using several other species of phospholipase A2, and the results were found to be general among the enzymes except the lys-49 isozyme from A. p. piscivorus which displayed neither the dependence on the critical micelle concentration for binding nor the ability to hydrolyze lysolecithin. These results were used as the basis for a quantitative analysis of enzyme fluorescence changes that occur during the time course of phospholipid hydrolysis and of the mechanism whereby lysolecithin inhibits the hydrolysis of phosphatidylcholine bilayers by phospholipase A2.