Project description:Expression of pulmonary surfactant, a complex mixture of lipids and proteins that acts to reduce alveolar surface tension, is developmentally regulated and restricted to lung alveolar type II cells. The hydrophobic protein surfactant protein-B (SP-B) is essential in surfactant function, and insufficient levels of SP-B result in severe respiratory dysfunction. Glucocorticoids accelerate fetal lung maturity and surfactant synthesis both experimentally and clinically. Glucocorticoids act transcriptionally and post-transcriptionally to increase steady-state levels of human SP-B mRNA; however, the mechanism(s) by which glucocorticoids act post-transcriptionally is unknown. We hypothesized that glucocorticoids act post-transcriptionally to increase SP-B mRNA stability via sequence-specific mRNA-protein interactions. We found that glucocorticoids increase SP-B mRNA stability in isolated human type II cells and in nonpulmonary cells, but do not alter mouse SP-B mRNA stability in a mouse type II cell line. Deletion analysis of an artificially-expressed SP-B mRNA indicates that the SP-B mRNA 3'-untranslated region (UTR) is necessary for stabilization, and the region involved can be restricted to a 126-nucleotide-long region near the SP-B coding sequence. RNA electrophoretic mobility shift assays indicate that cytosolic proteins bind to this region in the absence or presence of glucocorticoids. The formation of mRNA:protein complexes is not seen in other regions of the SP-B mRNA 3'-UTR. These results indicate that a specific 126-nucleotide region of human SP-B 3'-UTR is necessary for increased SP-B mRNA stability by glucocorticoids by a mechanism that is not lung cell specific and may involve mRNA-protein interactions.

Project description:VEGF165 is one of the key regulators of tumor development. Using HCT116 cells transfected with full-length vegf mRNA, full-length vegf mRNA with mutations of H9D and L14E, mutated vegf mRNAs lacking untranslated regions (UTRs), and 5’UTR mutated between nt 591 and nt 746, we found that vegf 5’UTR resided an anti-apoptotic activity against chemotherapy independently of VEGF165. We next established HCT116 clones stably expressing vegf 5’UTR or the mutated vegf 5’UTR. The cells expressing 5’UTR, but not the mutated UTR, showed the drug-resistant phenotype, anchorage-independent growth, and rapid tumor growth when implanted in athymic nude mice. Microarray and real-time PCR showed that the vegf 5’UTR-expressing tumors up-regulated anti-apoptotic genes including mia and down-regulated pro-apoptotic genes including fas, pdcd1, nrg1, and bax. Microarray analysis also revealed specific down-regulation of IFN-inducible genes (43 genes) in the growing tumors. HCT116 cells stably transcribing vegf 5’UTR decreased STAT1 expression and IFN alpha-STAT1 pathway. In addition to 5-fluorouracil treatment, the vegf 5’UTR-expressing tumors did not respond to IFN alpha therapy at all. This novel tumor-promoting function in the vegf 5’UTR may partly explain the insufficiency of the VEGF-VEGFR strategies and suggest a vegf-targeted silencing strategy as a more effective anti-tumor therapy. Keywords: genetic modification

Project description:Processing of 3’ untranslated region (3’-UTR) of precursor messenger RNAs (pre-mRNA) is a fundamental step in mRNA maturation, where the mRNA transcript is cleaved at a specific site, located downstream the open reading frame of the encoded gene. The position of the cleavage site is determined by cis-acting RNA sequence elements, which are recognized with high specificity by large 3’ end processing multiprotein complexes. Two main categories of metazoan 3’ pre-mRNA processing have been identified so far, describing elaboration of either canonical mRNAs – occurring during all phases of the cell cycle and containing a characteristic Poly-Adenylation Signal (PAS) element – or histone mRNAs – prevalently occurring during the S phase and containing a Histone Downstream Element (HDE). In this work, we isolate both human endogenous canonical and histone 3’ pre-mRNA processing complexes from human nuclear extracts by using a pre-mRNA containing the 3’UTR sequence of replication-dependent histone H2A.2. This H2A.2 pre-mRNA (H2A_4m), containing both an HDE sequence and a PAS element in a native overlaid position, was modified with a 5’ photocleavable biotin tag, and with modification of few bases to allow complex assembly and purification by affinity chromatography on streptavidin-agarose beads, elution by UV irradiation and subsequent mass spectrometric identification of bound 3’ mRNA processing factors.

Project description:The serotonin 5-HT4 receptor (where 5-HT stands for 5-hydroxy-tryptamine) is a member of the seven transmembrane-spanning G-protein-coupled family of receptors and mediates many cellular functions both in the central nervous system and at the periphery. In the present study, we isolated and characterized the 5'-flanking region of the h5-HT4 (human 5-HT4) receptor. We demonstrate the existence of a novel exon that corresponds to the 5'-untranslated region of the h5-HT4 receptor gene. RNase protection analysis and reverse transcriptase-PCR experiments performed on human atrial RNA demonstrated that the major transcription start site of the h5-HT4 receptor gene is located at -3185 bp relative to the first ATG codon. In addition, a 1.2 kb promoter fragment which drives the transcription of the 5-HT4 receptor was characterized. The promoter region lacks TATA and CAAT canonical motifs in the appropriate location, but contains putative binding sites for several transcription factors. Transient transfection assays revealed that the (-3299/-3050) gene fragment possesses the ability to promote the expression of the luciferase reporter gene in human cell lines. In contrast, the promoter was silent in monkey COS-7 cells, indicating the requirement of specific factors to initiate transcription in human cells. In addition to the promoter element, enhancer activity was found in a region (-220/-61) located in the long 5'-untranslated region. Mutational analysis, gel shift and transfection assays identified an Nkx2.5 (NK2-transcription-factor-related 5)-like binding site as a regulatory sequence of this enhancer. Our results suggest a complex regulation of the h5-HT4 receptor gene expression involving distinct promoters and non-coding exons.

Project description:The RNA G-quadruplex (rG4) is a kind of non-canonical high-order secondary structure with important biological functions and is enriched in untranslated regions (UTRs) of protein-coding genes. However, how rG4 structures evolve is largely unknown. Here, we systematically investigated the evolution of RNA sequences around UTR rG4 structures in 5 eukaryotic organisms. We found universal selection on UTR sequences, which facilitated rG4 formation in all the organisms that we analyzed. While G-rich sequences were preferred in the rG4 structural region, C-rich sequences were selectively not preferred. The selective pressure acting on rG4 structures in the UTRs of genes with higher G content was significantly smaller. Furthermore, we found that rG4 structures experienced smaller evolutionary selection near the translation initiation region in the 5' UTR, near the polyadenylation signals in the 3' UTR, and in regions flanking the miRNA targets in the 3' UTR. These results suggest universal selection for rG4 formation in the UTRs of eukaryotic genomes and the selection may be related to the biological functions of rG4s.

Project description:Background informationMaskin is a member of the TACC (transforming acidic coiled-coil) domain proteins found in Xenopus laevis oocytes and embryos. It has been implicated in the co-ordination of the spindle and has been reported to mediate translational repression of cyclin B1 mRNA.ResultsIn the present study, we report that maskin mRNA is translationally repressed at the level of initiation in stage 4 oocytes and becomes activated in stage 6 oocytes. The translational repression of maskin mRNA correlates with the presence of a short poly(A) tail on this mRNA in stage 4 oocytes. The 3'-UTR (untranslated region) of maskin can confer the translational regulation to a reporter mRNA, and so can the 3'-UTR of human TACC3. A conserved GUCU repeat element was found to repress translation in both stage 4 and stage 6 oocytes, but deletion of this element did not abrogate repression in stage 4 oocytes. UV cross-linking experiments indicated that overlapping sets of proteins bind efficiently to both the maskin and the cyclin B1 3'-UTRs. As reported previously, CPEB [CPE (cytoplasmic polyadenylation element)-binding protein] binds to the cyclin B1 3'-UTR, but its binding to the maskin 3'-UTR is minimal. By RNA affinity chromatography and MS, we identified the EDEN-BP [EDEN (embryonic deadenylation element)-binding protein] as one of the proteins binding to both the maskin and the cyclin B1 3'-UTRs.ConclusionsMaskin mRNA is translationally regulated by at least two repressor elements and an activation element. One of the repessor elements is the evolutionarily conserved GUCU repeat. EDEN-BP binds to both the maskin and cyclin B1 3'-UTRs, indicating it may be involved in the deadenylation of these mRNAs.

Project description:Processing of 3’ untranslated region (3’-UTR) of precursor messenger RNAs (pre-mRNA) is a fundamental step in mRNA maturation, where the mRNA transcript is cleaved at a specific site, located downstream the open reading frame of the encoded gene. The position of the cleavage site is determined by cis-acting RNA sequence elements, which are recognized with high specificity by large 3’ end processing multiprotein complexes. Two main categories of metazoan 3’ pre-mRNA processing have been identified so far, describing elaboration of either canonical mRNAs – occurring during all phases of the cell cycle and containing a characteristic Poly-Adenylation Signal (PAS) element – or histone mRNAs – prevalently occurring during the S phase and containing a Histone Downstream Element (HDE). In this work, we isolate both human endogenous canonical and histone 3’ pre-mRNA processing complexes from human nuclear extracts by using a pre-mRNA containing the 3’UTR sequence of replication-dependent histone H2A.2. This H2A.2 pre-mRNA (H2A_4m), containing both an HDE sequence and a PAS element in a native overlaid position, was modified with a 5’ photocleavable biotin tag, and with modification of few bases to allow complex assembly and purification by affinity chromatography on streptavidin-agarose beads, elution by UV irradiation and subsequent mass spectrometric identification of bound 3’ mRNA processing factors.

Project description:Cell cycle progression during oocyte maturation requires the strict temporal regulation of maternal mRNA translation. The intrinsic basis of this temporal control has not been fully elucidated but appears to involve distinct mRNA 3' UTR regulatory elements. In this study, we identify a novel translational control sequence (TCS) that exerts repression of target mRNAs in immature oocytes of the frog, Xenopus laevis, and can direct early cytoplasmic polyadenylation and translational activation during oocyte maturation. The TCS is functionally distinct from the previously characterized Musashi/polyadenylation response element (PRE) and the cytoplasmic polyadenylation element (CPE). We report that TCS elements exert translational repression in both the Wee1 mRNA 3' UTR and the pericentriolar material-1 (Pcm-1) mRNA 3' UTR in immature oocytes. During oocyte maturation, TCS function directs the early translational activation of the Pcm-1 mRNA. By contrast, we demonstrate that CPE sequences flanking the TCS elements in the Wee1 3' UTR suppress the ability of the TCS to direct early translational activation. Our results indicate that a functional hierarchy exists between these distinct 3' UTR regulatory elements to control the timing of maternal mRNA translational activation during oocyte maturation.

Project description:Ischemic events, common in many diseases, result from decreased blood flow and impaired delivery of oxygen and glucose to tissues of the body. While much is known about the cellular transcriptional response to ischemia, much less is known about the posttranscriptional response to oxygen and glucose deprivation. The goal of this project was to investigate one such posttranscriptional response, the regulation of mRNA stability. To that end, we have identified several novel ischemia-related mRNAs that are synergistically stabilized by oxygen and glucose deprivation including VEGF, MYC, MDM2, and CYR61. This increase in mRNA half-life requires the synergistic effects of both low oxygen (1%) as well as low glucose (? 1 g/L) conditions. Oxygen or glucose deprivation alone fails to initiate the response, as exposure to either high glucose (4 g/L) or normoxic conditions inhibits the response. Furthermore, in response to hypoxia/hypoglycemia, the identified mRNAs are released from the RNA binding protein KHSRP which likely contributes to their stabilization.

Project description:Long 3' untranslated regions (3'UTRs) are common in eukaryotic mRNAs. In contrast, long 3'UTRs are rare in bacteria, and have not been characterized in detail. We describe a 3'UTR of 310 nucleotides in hilD mRNA, a transcript that encodes a transcriptional activator of Salmonella enterica pathogenicity island 1 (SPI-1). Deletion of the hilD 3'UTR increases the hilD mRNA level, suggesting that the hilD 3'UTR may play a role in hilD mRNA turnover. Cloning of the hilD 3'UTR downstream of the green fluorescent protein (gfp) gene decreases green fluorescent protein (GFP) activity in both Escherichia coli and S. enterica, indicating that the hilD 3'UTR can act as an independent module. S. enterica mutants lacking either ribonuclease E or polynucleotide phosphorylase contain similar amounts of hilD and hilD ?3'UTR mRNAs, suggesting that the hilD 3'UTR is a target for hilD mRNA degradation by the degradosome. The hilD 3'UTR is also necessary for modulation of hilD and SPI-1 expression by the RNA chaperone Hfq. Overexpression of SPI-1 in the absence of the hilD 3'UTR retards Salmonella growth and causes uncontrolled invasion of epithelial cells. Based on these observations, we propose that the S. enterica hilD 3'UTR is a cis-acting element that contributes to cellular homeostasis by promoting hilD mRNA turnover.