Effect of Hfq on RprA-rpoS mRNA pairing: Hfq-RNA binding and the influence of the 5' rpoS mRNA leader region.

The rpoS mRNA encodes a stress response transcription factor in Escherichia coli. It is one of a growing number of mRNAs found to be regulated by small RNAs (sRNA). Translation initiation of rpoS mRNA is enhanced by two sRNAs, DsrA and RprA, that pair to the same site near the rpoS start codon in the presence of the Hfq protein. In this work, we examine the interaction of E. coli Hfq with RprA and two portions of the rpoS mRNA leader region. One rpoS RNA, rpoS-L, contained the entire 565-nucleotide leader region, while the other, rpoS-S, contained the 199-nucleotide sequence surrounding the start codon. An RNase H assay indicated both rpoS RNAs have similar secondary structures in the translation initiation region. Hfq formed two complexes with RprA in a gel mobility assay with binding parameters similar to values previously determined for DsrA. Unlike DsrA, Hfq binding to RprA was inhibited by poly(A) and influenced by Hfq mutations on both the distal and proximal surfaces. Hfq increased the level of RprA binding to both rpoS RNAs but showed a much larger enhancement when rpoS-L, the entire leader region, was examined. The lower affinity of RprA for rpoS-L versus rpoS-S in the absence of Hfq suggests that Hfq overcomes an inhibitory structure within rpoS-L in stimulating RprA binding. Similar results were obtained with DsrA. The results indicate that the full upstream leader sequence of rpoS mRNA influences Hfq-facilitated annealing of RprA and DsrA and is likely to be involved in its regulation.

Heterogeneous nuclear ribonuclear protein K interacts with the enterovirus 71 5' untranslated region and participates in virus replication.

Enterovirus 71 (EV71) is a picornavirus that can cause severe neurological complications in children. Like other picornaviruses, the genomic RNA of EV71 contains a long 5' untranslated region (UTR). Cellular proteins interact with the EV71 5' UTR, and these interactions are important for virus replication. Using an RNA pull-down assay and proteomics approaches, this study identified the heterogeneous nuclear ribonucleoprotein K (hnRNP K) as one of the EV71 5' UTR-associated proteins. The interaction between hnRNP K and the 5' UTR was further confirmed by mapping the interaction regions to stem-loops I-II and IV in the 5' UTR. During EV71 infection, hnRNP K was enriched in the cytoplasm where virus replication occurs, whereas hnRNP K was localized in the nucleus in mock-infected cells. Viral yields were found to be significantly lower in hnRNP K knockdown cells and viral RNA synthesis was delayed in hnRNP K knockdown cells in comparison with negative-control cells treated with small interfering RNA. These results suggest that hnRNP K interacts with the EV71 5' UTR and participates in virus replication.

Context-influenced cap-independent translation of Tombusvirus mRNAs in vitro.

Tomato bushy stunt virus (TBSV) possesses a positive-strand RNA genome that is not 5'-capped or 3'-polyadenylated. Previous analysis revealed that the TBSV genome contains a 3'-cap-independent translational enhancer (3'CITE) in its 3'-untranslated region (3'UTR) that facilitates translation of viral mRNAs in vivo. A long-range 5'-3' RNA-RNA interaction between the 3'CITE and the 5'UTR of viral mRNAs is necessary for function, and this RNA bridge has been proposed to mediate delivery of translation-related factors bound to the 3'CITE to the 5'-end of the message. Although fully functional when assayed in plant protoplasts, the TBSV 3'CITE was previously found to be unable to activate translation in vitro in wheat germ extract (wge). In the current report we have determined that (i) another Tombusvirus, Carnation Italian ringspot virus (CIRV), contains a TBSV-like 3'CITE that is active in wge; (ii) the CIRV 3'CITE functions in vitro in a manner analogous to the TBSV 3'CITE in vivo; (iii) the TBSV 3'CITE is able to competitively inhibit CIRV 3'CITE-dependent translation in wge and (iv) the TBSV 3'CITE can enhance translation in wge when present in short viral messages. These results reveal the contrasting activities of different TBSV-like 3'CITEs in vitro and shed light on the nature of the defect in TBSV.

A single mutation in the IF3 N-terminal domain perturbs the fidelity of translation initiation at three levels.

Bacterial translation initiation factor 3 (IF3) is involved in the fidelity of translation initiation at several levels, including start-codon discrimination, mRNA translation, and initiator-tRNA selection. The IF3 C-terminal domain (CTD) is required for binding to the 30S ribosomal subunit. N-terminal domain (NTD) function is less certain, but likely contributes to initiation fidelity. Point mutations in either domain can decrease initiation fidelity, but C-terminal domain mutations may be indirect. Here, the Y75N substitution mutation in the NTD is examined in vitro and in vivo. IF3(Y75N) protein binds 30S subunits normally, but is defective in start-codon discrimination, inhibition of initiation on leaderless mRNA, and initiator-tRNA selection, thereby establishing a direct role for the IF3 NTD in these initiation processes. A model illustrating how IF3 modulates an inherent function of the 30S subunit is discussed.

Activation of cap-independent translation by variant eukaryotic initiation factor 4G in vivo.

Protein synthesis is tightly controlled by assembly of an intricate ribonucleoprotein complex at the m(7)GTP-cap on eukaryotic mRNAs. Ensuing linear scanning of the 5' untranslated region (UTR) is believed to transfer the preinitiation complex to the initiation codon. Eukaryotic mRNAs are characterized by significant 5' UTR heterogeneity, raising the possibility of differential control of translation initiation rate at individual mRNAs. Curiously, many mRNAs with unconventional, highly structured 5' UTRs encode proteins with central biological roles in growth control, metabolism, or stress response. The 5' UTRs of such mRNAs may influence protein synthesis rate in multiple ways, but most significantly they have been implicated in mediating alternative means of translation initiation. Cap-independent initiation bypasses strict control over the formation of initiation intermediates at the m(7)GTP cap. However, the molecular mechanisms that favor alternative means of ribosome recruitment are not understood. Here we provide evidence that eukaryotic initiation factor (eIF) 4G controls cap-independent translation initiation at the c-myc and vascular endothelial growth factor (VEGF) 5' UTRs in vivo. Cap-independent translation was investigated in tetracycline-inducible cell lines expressing either full-length eIF4G or a C-terminal fragment (Ct) lacking interaction with eIF4E and poly(A) binding protein. Expression of Ct, but not intact eIF4G, potently stimulated cap-independent initiation at the c-myc/VEGF 5' UTRs. In vitro RNA-binding assays suggest that stimulation of cap-independent translation initiation by Ct is due to direct association with the c-myc/VEGF 5' UTR, enabling 43S preinitiation complex recruitment. Our work demonstrates that variant translation initiation factors enable unconventional translation initiation at mRNA subsets with distinct structural features.

Ribosomes bind leaderless mRNA in Escherichia coli through recognition of their 5'-terminal AUG.

Leaderless mRNAs are translated in the absence of upstream signals that normally contribute to ribosome binding and translation efficiency. In order to identify ribosomal components that interact with leaderless mRNA, a fragment of leaderless cI mRNA from bacteriophage lambda, with a 4-thiouridine (4(S)-U) substituted at the +2 position of the AUG start codon, was used to form cross-links to Escherichia coli ribosomes during binary (mRNA+ribosome) and ternary (mRNA+ribosome+initiator tRNA) complex formation. Ribosome binding assays (i.e., toeprints) demonstrated tRNA-dependent binding of leaderless mRNA to ribosomes; however, cross-links between the start codon and 30S subunit rRNA and r-proteins formed independent of initiator tRNA. Toeprints revealed that a leaderless mRNA's 5'-AUG is required for stable binding. Furthermore, the addition of a 5'-terminal AUG triplet to a random RNA fragment can make it both competent and competitive for ribosome binding, suggesting that a leaderless mRNA's start codon is a major feature for ribosome interaction. Cross-linking assays indicate that a subset of 30S subunit r-proteins, located at either end of the mRNA tunnel, contribute to tRNA-independent contacts and/or interactions with a leaderless mRNA's start codon. The interaction of leaderless mRNA with ribosomes may reveal features of mRNA binding and AUG recognition that are distinct from known signals but are important for translation initiation of all mRNAs.

CSIG inhibits PTEN translation in replicative senescence.

Using a suppressive subtractive hybridization system, we identified CSIG (cellular senescence-inhibited gene protein; RSL1D1) that was abundant in young human diploid fibroblast cells but declined upon replicative senescence. Overexpression or knockdown of CSIG did not influence p21(Cip1) and p16(INK4a) expressions. Instead, CSIG negatively regulated PTEN and p27(Kip1) expressions, in turn promoting cell proliferation. In PTEN-silenced HEK 293 cells and PTEN-deficient human glioblastoma U87MG cells, the effect of CSIG on p27(Kip1) expression and cell division was abolished, suggesting that PTEN was required for the role of CSIG on p27(Kip1) regulation and cell cycle progression. Investigation into the underlying mechanism revealed that the regulation of PTEN by CSIG was achieved through a translational suppression mechanism. Further study showed that CSIG interacted with PTEN mRNA in the 5' untranslated region (UTR) and that knockdown of CSIG led to increased luciferase activity of a PTEN 5' UTR-luciferase reporter. Moreover, overexpression of CSIG significantly delayed the progression of replicative senescence, while knockdown of CSIG expression accelerated replicative senescence. Knockdown of PTEN diminished the effect of CSIG on cellular senescence. Our findings indicate that CSIG acts as a novel regulatory component of replicative senescence, which requires PTEN as a mediator and involves in a translational regulatory mechanism.

Translational regulation of glutathione peroxidase 4 expression through guanine-rich sequence-binding factor 1 is essential for embryonic brain development.

Phospholipid hydroperoxide glutathione peroxidase (GPx4) is a moonlighting selenoprotein, which has been implicated in basic cell functions such as anti-oxidative defense, apoptosis, and gene expression regulation. GPx4-null mice die in utero at midgestation, and developmental retardation of the brain appears to play a major role. We investigated post-transcriptional mechanisms of GPx4 expression regulation and found that the guanine-rich sequence-binding factor 1 (Grsf1) up-regulates GPx4 expression. Grsf1 binds to a defined target sequence in the 5'-untranslated region (UTR) of the mitochondrial GPx4 (m-GPx4) mRNA, up-regulates UTR-dependent reporter gene expression, recruits m-GPx4 mRNA to translationally active polysome fractions, and coimmunoprecipitates with GPx4 mRNA. During embryonic brain development, Grsf1 and m-GPx4 are coexpressed, and functional knockdown (siRNA) of Grsf1 prevents embryonic GPx4 expression. When compared with mock controls, Grsf1 knockdown embryos showed significant signs of developmental retardations that are paralleled by apoptotic alterations (TUNEL staining) and massive lipid peroxidation (isoprostane formation). Overexpression of m-GPx4 prevented the apoptotic alterations in Grsf1-deficient embryos and rescued them from developmental retardation. These data indicate that Grsf1 up-regulates translation of GPx4 mRNA and implicate the two proteins in embryonic brain development.

A hepatitis C virus cis-acting replication element forms a long-range RNA-RNA interaction with upstream RNA sequences in NS5B.

The genome of hepatitis C virus (HCV) contains cis-acting replication elements (CREs) comprised of RNA stem-loop structures located in both the 5' and 3' noncoding regions (5' and 3' NCRs) and in the NS5B coding sequence. Through the application of several algorithmically independent bioinformatic methods to detect phylogenetically conserved, thermodynamically favored RNA secondary structures, we demonstrate a long-range interaction between sequences in the previously described CRE (5BSL3.2, now SL9266) with a previously predicted unpaired sequence located 3' to SL9033, approximately 200 nucleotides upstream. Extensive reverse genetic analysis both supports this prediction and demonstrates a functional requirement in genome replication. By mutagenesis of the Con-1 replicon, we show that disruption of this alternative pairing inhibited replication, a phenotype that could be restored to wild-type levels through the introduction of compensating mutations in the upstream region. Substitution of the CRE with the analogous region of different genotypes of HCV produced replicons with phenotypes consistent with the hypothesis that both local and long-range interactions are critical for a fundamental aspect of genome replication. This report further extends the known interactions of the SL9266 CRE, which has also been shown to form a "kissing loop" interaction with the 3' NCR (P. Friebe, J. Boudet, J. P. Simorre, and R. Bartenschlager, J. Virol. 79:380-392, 2005), and suggests that cooperative long-range binding with both 5' and 3' sequences stabilizes the CRE at the core of a complex pseudoknot. Alternatively, if the long-range interactions were mutually exclusive, the SL9266 CRE may function as a molecular switch controlling a critical aspect of HCV genome replication.

The rpoS mRNA leader recruits Hfq to facilitate annealing with DsrA sRNA.

Small noncoding RNAs (sRNAs) regulate the response of bacteria to environmental stress in conjunction with the Sm-like RNA binding protein Hfq. DsrA sRNA stimulates translation of the RpoS stress response factor in Escherichia coli by base-pairing with the 5' leader of the rpoS mRNA and opening a stem-loop that represses translation initiation. We report that rpoS leader sequences upstream of this stem-loop greatly increase the sensitivity of rpoS mRNA to Hfq and DsrA. Native gel mobility shift assays show that Hfq increases the rate of DsrA binding to the full 576 nt rpoS leader as much as 50-fold. By contrast, base-pairing with a 138-nt RNA containing just the repressor stem-loop is accelerated only twofold. Deletion and mutagenesis experiments showed that sensitivity to Hfq requires an upstream AAYAA sequence. Leaders long enough to contain this sequence bind Hfq tightly and form stable ternary complexes with Hfq and DsrA. A model is proposed in which Hfq recruits DsrA to the rpoS mRNA by binding both RNAs, releasing the self-repressing structure in the mRNA. Once base-pairing between DsrA and rpoS mRNA is established, interactions between Hfq and the mRNA may stabilize the RNA complex by removing Hfq from the sRNA.

RNA secondary structure of the feline immunodeficiency virus 5'UTR and Gag coding region.

The 5' untranslated region (5'UTR) of lentiviral genomic RNA is highly structured, and is the site of multiple RNA-RNA and RNA-protein interactions throughout the viral life cycle. The 5'UTR plays a critical role during transcription, translational regulation, genome dimerization, reverse transcription priming and encapsidation. The 5'UTR structures of human lentiviruses have been extensively studied, yet the respective role and conformation of each domain is still controversial. To gain insight into the structure-function relationship of lentiviral 5'UTRs, we modelled the RNA structure of the feline immunodeficiency virus (FIV), a virus that is evolutionarily distant from the primate viruses. Through combined chemical and enzymatic structure probing and a thorough phylogenetic study, we establish a model for the secondary structure of the 5'UTR and Gag coding region. This work highlights properties common to all lentiviruses, like the primer binding site structure and the presence of a stable stem-loop at the 5' extremity. We find that FIV has also evolved specific features, including a long stem loop overlapping the end of the 5'UTR and the beginning of the coding region. In addition, we observed footprints of Gag protein on each side of the initiation codon, this sheds light on the role of the sequences required for encapsidation.

Iron increases translation initiation directed by internal ribosome entry site of hepatitis C virus.

Although increased liver iron in individuals with chronic hepatitis C virus (HCV) is associated with a poor response to interferon therapy, the underlying molecular mechanisms are poorly understood. In this study, we show that iron enhances the translation initiation mediated by the internal ribosome entry site (IRES) of HCV. We also demonstrate by UV cross-linking analysis that specific cellular proteins bind to HCV 5' untranslated region (5' UTR) in an iron-dependent manner. Notably, p85 and p110 are competed out for their binding to HCV 5' UTR when excess amounts of iron-responsive element (IRE) competitor RNAs are treated. This indicates that at least these two factors are common proteins for binding to HCV 5' UTR and IRE. Our results, taken together, suggest that intracellular iron modulates the iron sensing pathway and HCV IRES-dependent translation by changing the binding affinities of the common cellular factors to IRE and HCV IRES, respectively. As a consequence, the coordinated regulation of gene expression by intracellular iron could provide favorable conditions for HCV proliferation.

Monocistronic mRNAs containing defective hepatitis C virus-like picornavirus internal ribosome entry site elements in their 5' untranslated regions are efficiently translated in cells by a cap-dependent mechanism.

The initiation of protein synthesis on mRNAs within eukaryotic cells is achieved either by a 5' cap-dependent mechanism or through internal initiation directed by an internal ribosome entry site (IRES). Picornavirus IRES elements, located in the 5' untranslated region (5'UTR), contain extensive secondary structure and multiple upstream AUG codons. These features can be expected to inhibit cap-dependent initiation of translation. However, we have now shown that certain mutant hepatitis C virus-like picornavirus IRES elements (from porcine teschovirus-1 and avian encephalomyelitis virus), which are unable to direct internal initiation, are not significant barriers to efficient translation of capped monocistronic mRNAs that contain these defective elements within their 5'UTRs. Moreover, the translation of these mRNAs is highly sensitive to the expression of an enterovirus 2A protease (which induces cleavage of eIF4G) and is also inhibited by hippuristanol, a specific inhibitor of eIF4A function, in contrast to their parental wild-type IRES elements. These results provide a possible basis for the evolution of viral IRES elements within the context of functional mRNAs that are translated by a cap-dependent mechanism.

Inhibition of translation in living eukaryotic cells by an RNA G-quadruplex motif.

Guanine-rich sequences can adopt intramolecular four-stranded structures, called G-quadruplexes. These motifs have been intensively investigated on the DNA level, but their overall biological relevance remains elusive. Only recently has research concerning the function of G-quadruplexes in RNAs commenced. Here, we demonstrate for the first time, that an RNA G-quadruplex structure inhibits translation in vivo in eukaryotic cells. We investigated the function of a highly conserved, thermodynamically stable RNA G-quadruplex in the 5'-UTR of the mRNA of the human Zic-1 zinc-finger protein. Using dual luciferase reporter assay, we demonstrate that the Zic-1 RNA G-quadruplex represses protein synthesis inside eukaryotic cells. Quantitative RT-PCR assays confirmed that the reduction of protein synthesis is due to regulation of the translation process and not a consequence of reduced transcription. Western blot analysis revealed that expression of Zic-1 is strongly reduced by a 73 nucleotides-long fragment of the UTR containing the G-quadruplex motif. These structures might add to the more recently discovered elements in untranslated regions of mRNAs that regulate their translation.

RNA stability regulates differential expression of the metastasis protein, osteopontin, in hepatocellular cancer.

BACKGROUND: Osteopontin (OPN) is a potential therapeutic target in hepatocellular carcinoma (HCC), because it is a critical mediator of metastatic function. The molecular mechanisms that determine expression of OPN in HCC, however, are unknown. In this study, we examine differential OPN expression in the 2 HCC cell lines: HepG2 and Hep3B. METHODS: OPN expression, metastatic function, OPN promoter activity, and active transcription of OPN mRNA and its decay were assessed in the 2 HCC cell lines using standard techniques. RNA gel-shift assays were performed to determine binding of cytoplasmic proteins to OPN mRNA. RESULTS: Expression of OPN cellular/secreted protein and mRNA was greater in HepG2 than Hep3B cells (P < .01). Transient transfection of the OPN promoter construct demonstrated equivalent luciferase activities in the 2 cell lines; the rate of transcription was also equivalent as determined by chromatin immuno-precipitation assay. OPN mRNA half-life was 21 +/- 1 h and 3 +/- 1 h in HepG2 and Hep3B, respectively (P < .02). In HepG2 and Hep3B, the nucleotide sequence of OPN and its 5'-UTR, 3'-UTR, and poly (A) tail lengths were identical. A luciferase construct coupled in line with OPN-5'-UTR and OPN 3'-UTR presented greater expression in HepG2 (P < .01 vs Hep3B). Deletion of nt 10-57 of the OPN 5'-UTR restored luciferase and HA-tagged OPN protein expression in Hep3B but not in Hep G2. RNA gel-shift assays demonstrate different patterns of protein binding to OPN 5'-UTR between the 2 HCC cell lines. CONCLUSIONS: We conclude that RNA stability is a new, previously unrecognized mechanism that regulates OPN expression in HCC to convey metastatic function.

A +8 (-->CT) mutation within the 5' untranslated region of beta-globin down-regulates the mRNA transcription.

The 5' untranslated region (5'UTR) of beta-globin has been well characterized and is often used as a model for eukaryotic transcription/translation, but there are still questions regarding the mechanism of translational control. Mutations affecting the Cap site at + 1 and at positions +10, +22, +33 and +40-43 have been described, and it is thought that the initiator element required for transcription stretches from -2 to +7 relative to the Cap site with a downstream element situated from +10 to +15. The influence on initiation or translation of sequences between +7 and +10 is unknown. We report here a family with beta-thalassemia (beta-thal) who have a + 8 (CT) mutation. Molecular studies indicate that this mutation leads to a reduction in mRNA levels and we discuss the implications of a CT change at this position on the transcription/translation process.

T cell receptor signaling controls Foxp3 expression via PI3K, Akt, and mTOR.

Regulatory T (Treg) cells safeguard against autoimmunity and immune pathology. Because determinants of the Treg cell fate are not completely understood, we have delineated signaling events that control the de novo expression of Foxp3 in naive peripheral CD4 T cells and in thymocytes. We report that premature termination of TCR signaling and inibition of phosphatidyl inositol 3-kinase (PI3K) p110alpha, p110delta, protein kinase B (Akt), or mammalian target of rapamycin (mTOR) conferred Foxp3 expression and Treg-like gene expression profiles. Conversely, continued TCR signaling and constitutive PI3K/Akt/mTOR activity antagonised Foxp3 induction. At the chromatin level, di- and trimethylation of lysine 4 of histone H3 (H3K4me2 and -3) near the Foxp3 transcription start site (TSS) and within the 5' untranslated region (UTR) preceded active Foxp3 expression and, like Foxp3 inducibility, was lost upon continued TCR stimulation. These data demonstrate that the PI3K/Akt/mTOR signaling network regulates Foxp3 expression.

DNA methylation profiling of pseudogene-parental gene pairs and two gene families.

A substantial proportion of human genes contain tissue-specifically DNA-methylated regions (TDMRs). However, little is known about the evolutionary conservation of differentially methylated loci, how they evolve, and the signals that regulate them. We have studied TDMR conservation in the PLG and TBX gene families and in 32 pseudogene-parental gene pairs. Among the members of the recently evolved PLG gene family, 5'-UTR methylation is conserved and inversely correlated with the cognate gene expression, indicating as well a conserved regulatory role of DNA methylation. Conversely, many genes of the much older TBX family display complementary tissue-specific methylation, suggesting an epigenetic complementation in the evolution of this gene family. Similar to gene families, unprocessed pseudogenes arose from gene duplications and we found TDMR conservation in some pseudogene-parental gene pairs displaying short evolutionary distances. However, for the majority of unprocessed pseudogenes and for all processed pseudogenes examined, we found that tissue-specific methylation arose de novo after gene duplication.

RNase P cleaves the adenine riboswitch and stabilizes pbuE mRNA in Bacillus subtilis.

RNase P from Bacillus subtilis cleaves in vitro the adenine riboswitch upstream of pbuE, which codes for an adenine efflux pump. The guanine riboswitch, encoded upstream of xpt-pbuX operon, is not cleaved. The cleavage sites do not occur at any predicted structures that should be recognized by RNase P in the theoretical model of the adenine riboswitch. However, it is possible to draw alternative secondary structure models that match the apparent requirements for RNase P substrates at these cleavage sites. Support for these models is provided by appropriate mutagenesis experiments. Adenine showed no effect on the cleavage in vitro of the pbuE adenine riboswitch by RNase P holoenzyme from B. subtilis. The results of genetic experiments performed in B. subtilis support the cleavage of adenine riboswitch by RNase P in vivo and suggest that it induces the stabilization of pbuE mRNA under normal conditions.

Molecular mechanism of drug-dependent ribosome stalling.

Inducible expression of the erm erythromycin resistance genes relies on drug-dependent ribosome stalling. The molecular mechanisms underlying stalling are unknown. We used a cell-free translation system to elucidate the contribution of the nascent peptide, the drug, and the ribosome toward formation of the stalled complex during translation of the ermC leader cistron. Toe-printing mapping, selective amino acid labeling, and mutational analyses revealed the peptidyl transferase center (PTC) as the focal point of the stalling mechanism. In the ribosome exit tunnel, the C-terminal sequence of the nascent peptide, critical for stalling, is in the immediate vicinity of the universally conserved A2062 of 23S rRNA. Mutations of this nucleotide eliminate stalling. Because A2062 is located in the tunnel, it may trigger a conformational change in the PTC, responding to the presence of a specific nascent peptide. The cladinose-containing macrolide antibiotic in the tunnel positions the nascent peptide for interaction with the tunnel sensory elements.