Apparent versus true gene expression changes of three hypoxia-related genes in autopsy derived tissue and the importance of normalisation.

The aim of our work was to show how a chosen normal-isation strategy can affect the outcome of quantitative gene expression studies. As an example, we analysed the expression of three genes known to be upregulated under hypoxic conditions: HIF1A, VEGF and SLC2A1 (GLUT1). Raw RT-qPCR data were normalised using two different strategies: a straightforward normalisation against a single reference gene, GAPDH, using the 2(-ΔΔCt) algorithm and a more complex normalisation against a normalisation factor calculated from the quantitative raw data from four previously validated reference genes. We found that the two different normalisation strategies revealed contradicting results: normalising against a validated set of reference genes revealed an upregulation of the three genes of interest in three post-mortem tissue samples (cardiac muscle, skeletal muscle and brain) under hypoxic conditions. Interestingly, we found a statistically significant difference in the relative transcript abundance of VEGF in cardiac muscle between donors who died of asphyxia versus donors who died from cardiac death. Normalisation against GAPDH alone revealed no upregulation but, in some instances, a downregulation of the genes of interest. To further analyse this discrepancy, the stability of all reference genes used were reassessed and the very low expression stability of GAPDH was found to originate from the co-regulation of this gene under hypoxic conditions. We concluded that GAPDH is not a suitable reference gene for the quantitative analysis of gene expression in hypoxia and that validation of reference genes is a crucial step for generating biologically meaningful data.

Posttranscriptional control of renin synthesis: identification of proteins interacting with renin mRNA 3'-untranslated region.

Stabilization and correct localization of mRNA are important features of renin synthesis. To elucidate the molecular basis of cAMP-mediated posttranscriptional control via mRNA stabilization, we analyzed the interaction of human preprorenin (hREN) mRNA 3'-untranslated region (3'-UTR) with proteins of renin synthesizing Calu-6 cells and investigated their functional impact on messenger integrity. To identify hREN mRNA binding proteins, electrophoretic mobility shift assays, UV cross-linking and RNA-affinity chromatography with subsequent matrix-assisted laser desorption/ionization time-of-flight mass spectrometry were performed. The following six proteins were unambiguously identified as hREN mRNA 3'-UTR binding proteins: hnRNP E1 (synonyms alpha-CP or PCBP), hnRNP K, dynamin, nucleolin, YB-1, and MINT-homologous protein. All proteins contain various RNA binding motifs, and most have been described in the context of mRNA binding and mRNA stabilization. Four proteins for which antibodies were available were verified by immunological techniques (dynamin, nucleolin, hnRNP E1, and YB-1). Forskolin, an activator of cAMP synthesis, considerably stimulates renin synthesis via inhibition of REN mRNA decay. Functionally, this cAMP-based mRNA stabilization is accompanied by a 3- to 6-fold upregulation of REN mRNA binding proteins. RNase degradation assays confirm that 3'-UTR binding proteins are able to protect and stabilize REN mRNA in vitro.

Suppression of 15-lipoxygenase synthesis by hnRNP E1 is dependent on repetitive nature of LOX mRNA 3'-UTR control element DICE.

Cytidine-rich 15-lipoxygenase differentiation control element (15-LOX DICE) is a multifunctional cis-element found in the 3'-UTR of numerous eukaryotic mRNAs. It binds KH domain proteins of the type hnRNP E and K, thus mediating mRNA stabilization and translational control. Translational silencing is caused by formation of a simple binary complex between DICE and recombinant hnRNP E1 (E1). Electromobility shift assays and sucrose gradient centrifugation demonstrate that rabbit 15-LOX DICE, which is composed of ten subunits of the sequence (CCCCPuCCCUCUUCCCCAAG)10=10R, is able to bind up to ten molecules of E1. Protein/RNA interaction was studied with different subunits and submotifs of the 10R structure. Binding appears to be dependent on the degree of polymerization of the C-clusters (1R<2R<4R<10R), but not on their order. The minimal motif, which still functioned in E1 binding, contained two C-clusters (CCCCPuCCCUCUU). For efficient translational control, E1 binding is a necessary, but not sufficient, condition. Translational inhibition by E1 is only observed when at least a dimeric 2R configuration of the DICE is present in the 3'-UTR of a reporter mRNA. We conclude that binding of at least two E1 molecules activate or expose a binding site to enable the complex to interact with the 5'-end of the mRNA and the translational machinery. DICE-motifs are widely distributed in nature. The UTR database UTRnr contains 78 entries of mRNAs with 15-LOX DICEs. Most DICEs were two- to fourfold repetitive, but also highly repetitive structures were found, as in quail myelin protein mRNA (31 repeats) and hyperglycemic hormone mRNA of two crayfish species (nine and 11 repeats).