Activation of decapping involves binding of the mRNA and facilitation of the post-binding steps by the Lsm1-7–Pat1 complex

Decapping is a critical step in the conserved 5′-to-3′ mRNA decay pathway of eukaryotes. The hetero-octameric Lsm1-7–Pat1 complex is required for normal rates of decapping in this pathway. This complex also protects the mRNA 3′-ends from trimming in vivo. To elucidate the mechanism of decapping, we analyzed multiple lsm1 mutants, lsm1-6, lsm1-8, lsm1-9, and lsm1-14, all of which are defective in decapping and 3′-end protection but unaffected in Lsm1-7–Pat1 complex integrity. The RNA binding ability of the mutant complex was found to be almost completely lost in the lsm1-8 mutant but only partially impaired in the other mutants. Importantly, overproduction of the Lsm1-9p- or Lsm1-14p-containing (but not Lsm1-8p-containing) mutant complexes in wild-type cells led to a dominant inhibition of mRNA decay. Further, the mRNA 3′-end protection defect of lsm1-9 and lsm1-14 cells, but not the lsm1-8 cells, could be partly suppressed by overproduction of the corresponding mutant complexes in those cells. These results suggest the following: (1) Decapping requires both binding of the Lsm1-7–Pat1 complex to the mRNA and facilitation of the post-binding events, while binding per se is sufficient for 3′-end protection. (2) A major block exists at the post-binding steps in the lsm1-9 and lsm1-14 mutants and at the binding step in the lsm1-8 mutant. Consistent with these ideas, the lsm1-9, 14 allele generated by combining the mutations of lsm1-9 and lsm1-14 alleles had almost fully lost the RNA binding activity of the complex and behaved like the lsm1-8 mutant.     

Identification of proteins specifically interacting with YB-1 mRNA 3′ UTR and the effect of hnRNP Q on YB-1 mRNA translation

In this study, proteins specifically interacting with the 3′ untranslated region (UTR) of mRNA of the multifunctional Y-box-binding protein 1 (YB-1) were identified. One of these, hnRNP Q, was shown to specifically interact with the regulatory element (RE) in YB-1 mRNA 3′ UTR and to inhibit translation of this mRNA. Its binding to the RE was accompanied by displacement from this element of the poly(A)-binding protein (PABP), a positive regulator of YB-1 mRNA translation, and by enhanced binding of the negative YB-1 mRNA translation regulator — YB-1 itself.     

Staufen1-mediated mRNA decay induces Requiem mRNA decay through binding of Staufen1 to the Requiem 3′UTR

Requiem (REQ/DPF2) was originally identified as an apoptosis-inducing protein in mouse myeloid cells and belongs to the novel Krüppel-type zinc finger d4-protein family of proteins, which includes neuro-d4 (DPF1) and cer-d4 (DPF3). Interestingly, when a portion of the REQ messenger ribonucleic acid (mRNA) 3′ untranslated region (3′UTR), referred to as G8, was overexpressed in K562 cells, β-globin expression was induced, suggesting that the 3′UTR of REQ mRNA plays a physiological role. Here, we present evidence that the REQ mRNA 3′UTR, along with its trans-acting factor, Staufen1 (STAU1), is able to reduce the level of REQ mRNA via STAU1-mediated mRNA decay (SMD). By screening a complementary deoxyribonucleic acid (cDNA) expression library with an RNA–ligand binding assay, we identified STAU1 as an interactor of the REQ mRNA 3′UTR. Specifically, we provide evidence that STAU1 binds to putative 30-nucleotide stem–loop-structured RNA sequences within the G8 region, which we term the protein binding site core; this binding triggers the degradation of REQ mRNA and thus regulates translation. Furthermore, we demonstrate that siRNA-mediated silencing of either STAU1 or UPF1 increases the abundance of cellular REQ mRNA and, consequently, the REQ protein, indicating that REQ mRNA is a target of SMD.     

Degradation of δ-crystallin mRNA in the lens fiber cells of the chicken

δ-Crystallin is the principal protein synthesized in the embryonic chicken lens. After hatching δ-crystallin synthesis decreases and eventually ceases. We have determined when the δ-crystallin messenger RNA (mRNA) disappears from the lens fiber cells during the first year of age by cell-free translation of lens RNA in a reticulocyte lysate, RNA blot (Northern) hybridization, and in situ hybridization. The hybridization was performed with a nick-translated, cloned δ-crystallin cDNA (pδCr2). δ-Crystallin mRNA was present in the lens until 3 months of age and disappeared between the third and fifth month after hatching. The in situ hybridization experiments indicated that the δ-crystallin mRNA was present throughout the lens fiber mass until 1 month after hatching and was greatly reduced in the cortical fiber cells thereafter. In contrast to earlier stages, then, the cortical fiber cells differentiating at the lens equator after about 1 month of age do not accumulate δ-crystallin mRNA. The data also indicate that the maximal half-life of functional δ-crystallin mRNA in the posthatched chicken lens is about 2 months.     

U1A Regulates 3′ Processing of the Survival Motor Neuron mRNA

Insufficient expression of the survival motor neuron (SMN) protein causes spinal muscular atrophy, a neurodegenerative disease characterized by loss of motor neurons. Despite the importance of maintaining adequate SMN levels, little is known about factors that control SMN expression, particularly 3′ end processing of the SMN pre-mRNA. In this study, we identify the U1A protein as a key regulator of SMN expression. U1A, a component of the U1 snRNP, is known to inhibit polyadenylation upon direct binding to mRNA. We show that U1A binds directly and with high affinity and specificity to the SMN 3′-UTR adjacent to the polyadenylation site, independent of the U1 snRNP (U1 small nuclear ribonucleoprotein). Binding of U1A inhibits polyadenylation of the SMN pre-mRNA by specifically inhibiting 3′ cleavage by the cleavage and polyadenylation specificity factor. Expression of U1A in excess of U1 snRNA causes inhibition of SMN polyadenylation and decreases SMN protein levels. This work reveals a new mechanism for regulating SMN levels and provides new insight into the roles of U1A in 3′ processing of mRNAs.     

The Role of IRE1α in the Degradation of Insulin mRNA in Pancreatic β-Cells

Background

The endoplasmic reticulum (ER) is a cellular compartment for the biosynthesis and folding of newly synthesized secretory proteins such as insulin. Perturbations to ER homeostasis cause ER stress and subsequently activate cell signaling pathways, collectively known as the Unfolded Protein Response (UPR). IRE1α is a central component of the UPR. In pancreatic β-cells, IRE1α also functions in the regulation of insulin biosynthesis.

Principal Findings

Here we report that hyperactivation of IRE1α caused by chronic high glucose treatment or IRE1α overexpression leads to insulin mRNA degradation in pancreatic β-cells. Inhibition of IRE1α signaling using its dominant negative form prevents insulin mRNA degradation. Islets from mice heterozygous for IRE1α retain expression of more insulin mRNA after chronic high glucose treatment than do their wild-type littermates.

Conclusions/Significance

These results reveal a role of IRE1α in insulin mRNA expression under ER stress conditions caused by chronic high glucose. The rapid degradation of insulin mRNA could provide immediate relief for the ER and free up the translocation machinery. Thus, this mechanism would preserve ER homeostasis and help ensure that the insulin already inside the ER can be properly folded and secreted. This adaptation may be crucial for the maintenance of β-cell homeostasis and may explain why the β-cells of type 2 diabetic patients with chronic hyperglycemia stop producing insulin in the absence of apoptosis. This mechanism may also be involved in suppression of the autoimmune type 1 diabetes by reducing the amount of misfolded insulin, which could be a source of “neo-autoantigens.”     

No role of the 5′ untranslated region of ornithine decarboxylase mRNA in the feedback control of the enzyme

The polyamines are ubiquitous in nature and appear to fulfil several important functions, mostly related to growth, in the cell. The first, and often rate-limiting, step in the biosynthesis of the polyamines is catalysed by ornithine decarboxylase (ODC), which is subject to a variety of control mechanisms. The polyamines exert a strong feedback regulation of the expression - as well as the degradation of the enzyme. The regulation of ODC expression appears to occur at the translational level. The ODC mRNA contains a long GC-rich 5 untranslated region (UTR), which has been demonstrated to hamper the translation of the mRNA. However, it has not yet been conclusively established whether this part of the mRNA fulfils any function in relation to the polyamine-mediated control of ODC synthesis. In the present study, we have used stable transgenic CHO cells, expressing either full-length ODC mRNA or 5 UTR-truncated ODC mRNA, to elucidate the role, if any, of the 5 UTR in the translational regulation of the enzyme by polyamines. No differences in regulatory properties were observed between the cells expressing the full-length ODC mRNA and those expressing the ODC mRNA devoid of most the 5 UTR. The cell lines down-regulated ODC (synthesis as well as activity) to the same extent upon exposure to an excess of polyamines, demonstrating that the feedback control of ODC mRNA translation occurs by a mechanism independent of the major part of the 5 UTR of the ODC mRNA.     

Determination of the primary sequence of the duck αD globin mRNA and comparison of all adult duck and chick globin mRNA sequences

The nucleotide sequence of the duck α^D globin mRNA was determined. Its main feature is an exceptionally short 3′ non-coding segment of only 46 nucleotides, placed after the coding sequence of 141 codons. The last of the 6 adult globin mRNA of duck and chicken being thus sequenced, a comparison of all their features has become possible. Comparing the duck α^D mRNA to the related sequence in the chicken, we found greater homology than comparing it to the linked α^A globin sequence in the same species. Extensive homology can be found for a same globin chain α^A, α^D or β in between different avian species including also the goose and the ostrich; the avian α globin chains show a lower degree of sequence conservation in between species than the β chains. In contrast, within one species the three globin sequences have further diverged. The divergence between the α^A and α^D globin within a same species point to individual functional specificity and hence independent evolution and suggest that a mechanism of ‘gene conversion’ did not operate in between the avian α globin genes. Two segments of the amino acid sequence which we named ‘A^α’ and ‘B^α’ remain homologous in all avian α globins; two other regions ‘A^β’ and ‘B^β’ are identical in between the β globins. Segment A is placed at the 5′ end of exon II, and segment B at the 3′ end of the same exon; some amino acids in those segments are involved in the Heme binding site. Being almost identical in all know mammalian and avian globins of the α respectively the β type, regions A and B seem to represent the best conserved sequences in adult globin mRNA maintained during the divergence of species.     

Efficiency of the miRNA–mRNA Interaction Prediction Programs

miRNAs play a key role in regulation of gene expression. Nowadays it is known more than 2500 human miRNAs, while a majority of miRNA–mRNA interactions remains unidentified. The recent development of a high-throughput CLASH (crosslinking, ligation and sequencing of hybrids) technique for discerning miRNA–mRNA interactions allowed an experimental analysis of the human miRNA–mRNA interactome. Therefore, it allowed us, for the first time, make an experimental analysis of the human miRNA–mRNA interactome as a whole and an evaluation of the quality of most commonly used miRNA prediction tools (TargetScan, PicTar, PITA, RNA22 and miRanda). To estimate efficiency of the miRNA–mRNA prediction tools, we used next parameters: sensitivity, positive predicted value, predictions in different mRNA regions (3' UTR, CDS, 5' UTR), predictions for different types of interactions (5 classes), predictions of “canonical” and “nocanonical” interactions, similarity with the random generated data. The analysis revealed low efficiency of all prediction programs in comparison with the CLASH data in terms of the all examined parameters.     

PCBP2 enhances the antiviral activity of IFN-α against HCV by stabilizing the mRNA of STAT1 and STAT2

Interferon-α (IFN-α) is a natural choice for the treatment of hepatitis C, but half of the chronically infected individuals do not achieve sustained clearance of hepatitis C virus (HCV) during treatment with IFN-α alone. The virus can impair IFN-α signaling and cellular factors that have an effect on the viral life cycles. We found that the protein PCBP2 is down-regulated in HCV-replicon containing cells (R1b). However, the effects and mechanisms of PCBP2 on HCV are unclear. To determine the effect of PCBP2 on HCV, overexpression and knockdown of PCBP2 were performed in R1b cells. Interestingly, we found that PCBP2 can facilitate the antiviral activity of IFN-α against HCV, although the RNA level of HCV was unaffected by either the overexpression or absence of PCBP2 in R1b cells. RIP-qRT-PCR and RNA half-life further revealed that PCBP2 stabilizes the mRNA of STAT1 and STAT2 through binding the 3'Untranslated Region (UTR) of these two molecules, which are pivotal for the IFN-α anti-HCV effect. RNA pull-down assay confirmed that there were binding sites located in the C-rich tracts in the 3'UTR of their mRNAs. Stabilization of mRNA by PCBP2 leads to the increased protein expression of STAT1 and STAT2 and a consistent increase of phosphorylated STAT1 and STAT2. These effects, in turn, enhance the antiviral effect of IFN-α. These findings indicate that PCBP2 may play an important role in the IFN-α response against HCV and may benefit the HCV clinical therapy.     

Mitochondrial Cytochrome b mRNA Editing in Dinoflagellates: Possible Ecological and Evolutionary Associations?

To verify the hypothesis that mt mRNA editing is widespread in dinoflagellates, we analyzed cytochrome b (cob) mRNA editing for six species representing distinct ecotypes and taxonomic classes of Dinophyceae. Editing is detected in all, which is similar to the three other species studied previously in that edited sites appear to aggregate in four clusters and occur predominantly at first and second positions of codons (93%), overwhelmingly involving A --> G, U --> C, or C --> U substitutions with a smaller number of G --> C, G --> A changes. Comparative analyses on editing characteristics reveal interesting trends related to phylogenetic relatedness and ecological features. Editing density (percentage of nucleotide that is affected by editing) increases from early to derived lineages. Higher editing densities also map to red tide-forming lineages. Furthermore, similarity of location of edited codons (LOE) and the type of nucleotide changes (TOE) in different lineages mirror the taxonomic affinity of the lineages. Phylogenetic trees constructed from LOE and TOE resemble those inferred from cob sequences. The results bolster our earlier hypothesis that cob editing is widespread in dinoflagellates and suggest that density, location, and type of editing may bear yet-to-be-defined evolutionary and ecological significance.