Jorge Ramajo

A novel role for Gemin5 in mRNA translation

In eukaryotic cells translation initiation occurs through two alternative mechanisms, a cap-dependent operating in the majority of mRNAs, and a 5′-end-independent driven by internal ribosome entry site (IRES) elements, specific for a subset of mRNAs. IRES elements recruit the translation machinery to an internal position in the mRNA through a mechanism involving the IRES structure and several trans-acting factors. Here, we identified Gemin5 protein bound to the foot-and-mouth disease virus (FMDV) and hepatitis C virus (HCV) IRES using two independent approaches, riboproteomic analysis and immunoprecipitation of photocroslinked factors. Functional analysis performed in Gemin5 shRNA-depleted cells, or in in vitro translation reactions, revealed an unanticipated role of Gemin5 in translation control as a down-regulator of cap-dependent and IRES-driven translation initiation. Consistent with this, pull-down assays showed that Gemin5 forms part of two distinct complexes, a specific IRES-ribonucleoprotein complex and an IRES-independent protein complex containing eIF4E. Thus, beyond its role in snRNPs biogenesis, Gemin5 also functions as a modulator of translation activity.

Gemin5 promotes IRES interaction and translation control through its C-terminal region

Gene expression control largely depends on ribonucleoprotein complexes regulating mRNA translation. Initiation of translation in mRNAs that overcome cap-dependent translation inhibition is often driven by internal ribosome entry site (IRES) elements, whose activity is regulated by multifunctional RNA-binding factors. Here we show that Gemin5 interacts preferentially with a specific domain of a viral IRES consisting of a hairpin flanked by A/U/C-rich sequences. RNA-binding assays using purified proteins revealed that Gemin5–IRES interaction depends on the C-terminal region of the protein. Consistent with this novel finding, the C-terminal region of Gemin5, but not the N-terminal region, impaired translation. Furthermore, RNA selective 2′hydroxyl acylation analysed by primer extension (SHAPE) reactivity demonstrated that addition of purified Gemin5 to IRES mRNA induced the specific protection of residues around the hairpin of the IRES element. We further demonstrate that Gemin5 out-competed SHAPE reactivity variations induced by the IRES-binding factor PTB, leading to a local conformational change in the IRES structure. Together, our data unveil the inhibitory mechanism of Gemin5 on IRES-mediated translation.

Identification of novel non-canonical RNA-binding sites in Gemin5 involved in internal initiation of translation

Ribonucleic acid (RNA)-binding proteins are key players of gene expression control. We have shown that Gemin5 interacts with internal ribosome entry site (IRES) elements and modulates initiation of translation. However, little is known about the RNA-binding sites of this protein. Here we show that the C-terminal region of Gemin5 bears two non-canonical bipartite RNA-binding sites, encompassing amino acids 1297–1412 (RBS1) and 1383–1508 (RBS2). While RBS1 exhibits greater affinity for RNA than RBS2, it does not affect IRES-dependent translation in G5-depleted cells. In solution, the RBS1 three-dimensional structure behaves as an ensemble of flexible conformations rather than having a defined tertiary structure. However, expression of the polypeptide G51383–1508, bearing the low RNA-binding affinity RBS2, repressed IRES-dependent translation. A comparison of the RNA-binding capacity and translation control properties of constructs expressed in mammalian cells to that of the Gemin5 proteolysis products observed in infected cells reveals that non-repressive products accumulated during infection while the repressor polypeptide is not stable. Taken together, our results define the low affinity RNA-binding site as the minimal element of the protein being able to repress internal initiation of translation.

Gemin5 proteolysis reveals a novel motif to identify L protease targets

Translation of picornavirus RNA is governed by the internal ribosome entry site (IRES) element, directing the synthesis of a single polyprotein. Processing of the polyprotein is performed by viral proteases that also recognize as substrates host factors. Among these substrates are translation initiation factors and RNA-binding proteins whose cleavage is responsible for inactivation of cellular gene expression. Foot-and-mouth disease virus (FMDV) encodes two proteases, Lpro and 3Cpro. Widespread definition of Lpro targets suffers from the lack of a sufficient number of characterized substrates. Here, we report the proteolysis of the IRES-binding protein Gemin5 in FMDV-infected cells, but not in cells infected by other picornaviruses. Proteolysis was specifically associated with expression of Lpro, yielding two stable products, p85 and p57. In silico search of putative L targets within Gemin5 identified two sequences whose potential recognition was in agreement with proteolysis products observed in infected cells. Mutational analysis revealed a novel Lpro target sequence that included the RKAR motif. Confirming this result, the Fas-ligand Daxx, was proteolysed in FMDV-infected and Lpro-expressing cells. This protein carries a RRLR motif whose substitution to EELR abrogated Lpro recognition. Thus, the sequence (R)(R/K)(L/A)(R) defines a novel motif to identify putative targets of Lpro in host factors.

Rescue of internal initiation of translation by RNA complementation provides evidence for a distribution of functions between individual IRES domains.

Picornavirus RNAs initiate translation using an internal ribosome entry site (IRES)-dependent mechanism. The IRES element of foot-and-mouth disease virus (FMDV) is organized in domains, being different from each other in RNA structure and RNA-protein interaction. Wild-type transcripts provided in trans rescue defective FMDV IRES mutants. Complementation, however, was partial since translation efficiency of the mutant RNAs was up to 10% of the wild type IRES. We report here that mutations diminishing the RNA-RNA interaction capacity induced a decrease in IRES rescue. On the other hand, IRES transcripts bearing mutations that reorganize the RNA structure of the apical region of central domain, although weakly, complement defective IRES that are unable to interact with the initiation factor eIF4G in a separate domain. Together, these results suggest that IRES rescue may involve RNA-mediated contacts between defective elements, each carrying a defect in a separate domain but having the complementing one with the appropriate structural orientation and/or ribonucleoprotein composition. Our observations further support the essential role of the central domain of the FMDV IRES during protein synthesis and demonstrate that there is a division of functions between the IRES domains.

Specific interference between two unrelated internal ribosome entry site elements impairs translation efficiency

Internal ribosome entry site (IRES) elements allow simultaneous synthesis of multiple proteins in eukaryotic cells. Here, two unrelated IRESs that perform efficiently in bicistronic constructs, the picornavirus foot‐and‐mouth disease virus (FMDV) and the cellular immunoglobulin heavy chain binding protein (BiP) IRES, were used to generate a tricistronic vector. Functional analysis of the tricistronic RNA evidenced that the efficiency of protein synthesis under the control of BiP IRES was lower than that of the FMDV IRES, relative to the efficiency measured in bicistronic vectors. A specific competition between these elements was verified using two separate mono‐ or bicistronic constructs in vivo and in vitro. In contrast, no interference was detected with the hepatitis C virus (HCV) IRES. The interference effect of FMDV IRES was observed in cis and trans, in support of competition for common transacting factors different than those used in cap‐ and HCV‐dependent initiation.

The RNA-binding protein Gemin5 binds directly to the ribosome and regulates global translation

RNA-binding proteins (RBPs) play crucial roles in all organisms. The protein Gemin5 harbors two functional domains. The N-terminal domain binds to snRNAs targeting them for snRNPs assembly, while the C-terminal domain binds to IRES elements through a non-canonical RNA-binding site. Here we report a comprehensive view of the Gemin5 interactome; most partners copurified with the N-terminal domain via RNA bridges. Notably, Gemin5 sediments with the subcellular ribosome fraction, and His-Gemin5 binds to ribosome particles via its N-terminal domain. The interaction with the ribosome was lost in F381A and Y474A Gemin5 mutants, but not in W14A and Y15A. Moreover, the ribosomal proteins L3 and L4 bind directly with Gemin5, and conversely, Gemin5 mutants impairing the binding to the ribosome are defective in the interaction with L3 and L4. The overall polysome profile was affected by Gemin5 depletion or overexpression, concomitant to an increase or a decrease, respectively, of global protein synthesis. Gemin5, and G5-Nter as well, were detected on the polysome fractions. These results reveal the ribosome-binding capacity of the N-ter moiety, enabling Gemin5 to control global protein synthesis. Our study uncovers a crosstalk between this protein and the ribosome, and provides support for the view that Gemin5 may control translation elongation.

Local RNA flexibility perturbation of the IRES element induced by a novel ligand inhibits viral RNA translation

The internal ribosome entry site (IRES) element located at the 5´untranslated genomic region of various RNA viruses mediates cap-independent initiation of translation. Picornavirus IRES activity is highly dependent on both its structural organization and its interaction with host factors. Small molecules able to interfere with RNA function are valuable candidates for antiviral agents. Here we show that a small molecule based on benzimidazole (IRAB) inhibited foot-and-mouth disease virus (FMDV) IRES-dependent protein synthesis in cells transfected with infectious RNA leading to a decrease of the virus titer, which was higher than that induced by a structurally related benzimidazole derivative. Interestingly, IRAB preferentially inhibited IRES-dependent translation in cell free systems in a dose-dependent manner. RNA structural analysis by SHAPE demonstrated an increased local flexibility of the IRES structure upon incubation with IRAB, which affected 3 stem-loops (SL) of domain 3. Fluorescence binding assays conducted with individual aminopurine-labeled oligoribonucleotides indicated that the SL3A binds IRAB (EC50 18 μM). Taken together, the results derived from SHAPE reactivity and fluorescence binding assays suggested that the target site of IRAB within the FMDV IRES might be a folded RNA structure that involves the entire apical region of domain 3. Our data suggest that the conformational changes induced by this compound on a specific region of the IRES structure which is essential for its activity is, at least in part, responsible for the reduced IRES efficiency observed in cell free lysates and, particularly, in RNA-transfected cells.

Designing synthetic RNAs to determine the relevance of structural motifs in picornavirus IRES elements

The function of Internal Ribosome Entry Site (IRES) elements is intimately linked to their RNA structure. Viral IRES elements are organized in modular domains consisting of one or more stem-loops that harbor conserved RNA motifs critical for internal initiation of translation. A conserved motif is the pyrimidine-tract located upstream of the functional initiation codon in type I and II picornavirus IRES. By computationally designing synthetic RNAs to fold into a structure that sequesters the polypyrimidine tract in a hairpin, we establish a correlation between predicted inaccessibility of the pyrimidine tract and IRES activity, as determined in both in vitro and in vivo systems. Our data supports the hypothesis that structural sequestration of the pyrimidine-tract within a stable hairpin inactivates IRES activity, since the stronger the stability of the hairpin the higher the inhibition of protein synthesis. Destabilization of the stem-loop immediately upstream of the pyrimidine-tract also decreases IRES activity. Our work introduces a hybrid computational/experimental method to determine the importance of structural motifs for biological function. Specifically, we show the feasibility of using the software RNAiFold to design synthetic RNAs with particular sequence and structural motifs that permit subsequent experimental determination of the importance of such motifs for biological function.

RNAiFold2T: Constraint Programming design of thermo-IRES switches.

Motivation: RNA thermometers (RNATs) are cis-regulatory elements that change secondary structure upon temperature shift. Often involved in the regulation of heat shock, cold shock and virulence genes, RNATs constitute an interesting potential resource in synthetic biology, where engineered RNATs could prove to be useful tools in biosensors and conditional gene regulation. Results: Solving the 2-temperature inverse folding problem is critical for RNAT engineering. Here we introduce RNAiFold2T, the first Constraint Programming (CP) and Large Neighborhood Search (LNS) algorithms to solve this problem. Benchmarking tests of RNAiFold2T against existent programs (adaptive walk and genetic algorithm) inverse folding show that our software generates two orders of magnitude more solutions, thus allowing ample exploration of the space of solutions. Subsequently, solutions can be prioritized by computing various measures, including probability of target structure in the ensemble, melting temperature, etc. Using this strategy, we rationally designed two thermosensor internal ribosome entry site (thermo-IRES) elements, whose normalized cap-independent translation efficiency is approximately 50% greater at 42 °C than 30 °C, when tested in reticulocyte lysates. Translation efficiency is lower than that of the wild-type IRES element, which on the other hand is fully resistant to temperature shift-up. This appears to be the first purely computational design of functional RNA thermoswitches, and certainly the first purely computational design of functional thermo-IRES elements. Availability: RNAiFold2T is publicly available as part of the new release RNAiFold3.0 at https://github.com/clotelab/RNAiFold and http://bioinformatics.bc.edu/clotelab/RNAiFold, which latter has a web server as well. The software is written in C ++ and uses OR-Tools CP search engine. Contact: clote@bc.edu Supplementary information: Supplementary data are available at Bioinformatics online.