Role of G-quadruplex located at 5ʹ end of mRNAs

BackgroundSecondary structures in 5′ UTR of mRNAs play a critical role in regulating protein synthesis. Though studies have indicated the role of secondary structure G-quadruplex in translational regulation, position-specific effect of G-quadruplex in naturally occurring mRNAs is still not understood. As a pre-initiation complex recognises 5′ cap of the mRNA and scans along the untranslated region (UTR) before initiating translation, the presence of G-quadruplex in 5′ region may have a significant contribution in regulating translation. Here, we investigate the role of G-quadruplex located at the 5′ end of an mRNA.MethodsBiophysical characterisation of putative G-quadruplexes was performed using UV and CD spectroscopy. Functional implication of G-quadruplex in the context of their location was assessed in cellulo using qRT-PCR and dual luciferase assay system.ResultsPG4 sequences in 5′ UTR of AKT interacting protein (AKTIP), cathepsin B (CTSB) and forkhead box E3 (FOXE3) mRNAs form G-quadruplex whereas it is unable to form G-quadruplex in apolipoprotein A-I binding protein (APOA1BP). Our results demonstrated diverse roles of G-quadruplex located at 5′ end of mRNAs. Though G-quadruplex in AKTIP and CTSB mRNA act as inhibitory modules, it activates translation in FOXE3 mRNA.ConclusionsOur works suggests that G-quadruplex present at the 5′ terminal of an mRNA behaves differently in a different gene context. It can activate or inhibit gene expression.General significanceThis study demonstrated that it is difficult to predict the role of G-quadruplex on the basis of its position in 5′ UTR. The neighbouring nucleotide sequence, the intracellular milieu and the interacting partners might render diverse functions to this secondary structure.     

RNAi-mediated knockdown of the Rhau helicase preferentially depletes proteins with a Guanine-quadruplex motif in the 5'-UTR of their mRNA

Guanine-quadruplex (G-quadruplex) structures in mRNAs have been shown to modulate gene expression. However, the overall biological relevance of this process is under debate, as cellular helicases unwind G-quadruplex structures. The helicase Rhau (encoded by the DHX36 gene) was reported to be the major source of RNA G-quadruplex resolving activity in lysates of human cells. In the current study, we depleted Rhau by RNAi-mediated silencing and analyzed the effect on proteins whose mRNAs harbor a G-quadruplex motif in their 5'-UTRs. A targeted investigation of the proto-oncogenes Bcl-2 and NRAS, which are well-known examples for the translational repression of G-quadruplex structures, did not reveal effects caused by Rhau silencing. We therefore carried out a global analysis of changes in protein levels by label-free quantification using liquid chromatography-electrospray ionization-tandem mass spectrometry (LC-ESI-MS/MS). Following Rhau knockdown, of all the identified proteins, only 1.9% were significantly downregulated to at least 70%. According to a bioinformatic analysis with the QGRS mapper, 33% of the downregulated proteins were predicted to harbor a G-quadruplex motif in the 5'-UTR of their respective mRNAs, compared to only 11% in the complete dataset. This indicates that in an unexpectedly small set of genes, in which G-quadruplex motifs are unusually common in the 5'-UTR of their mRNAs, Rhau helicase is responsible for the regulation of their expression.     

Circular dichroism spectra demonstrate formation of the thrombin-binding DNA aptamer G-quadruplex under stabilizing-cation-deficient conditions

It is noteworthy that the formation of the DNA G-quadruplex is induced by factors other than stabilizing cations because this event probably occurs in living cells. Previous studies have shown that thrombin-binding DNA aptamer (TBA) forms a chair-type intramolecular G-quadruplex structure that binds with thrombin protein in the absence of stabilizing cations. Here, we used circular dichroism (CD) spectroscopy to confirm G-quadruplex formation in the presence of thrombin without stabilizing cations. We obtained characteristic CD spectra that demonstrated that TBA forms the distinctive G-quadruplex structure. Additionally, we investigated G-quadruplex formation induced by change of solvent environment: the influence of low-temperature conditions and molecular crowding.     

Nucleophosmin mutations alter its nucleolar localization by impairing G-quadruplex binding at ribosomal DNA

Nucleophosmin (NPM1) is an abundant nucleolar protein implicated in ribosome maturation and export, centrosome duplication and response to stress stimuli. NPM1 is the most frequently mutated gene in acute myeloid leukemia. Mutations at the C-terminal domain led to variant proteins that aberrantly and stably translocate to the cytoplasm. We have previously shown that NPM1 C-terminal domain binds with high affinity G-quadruplex DNA. Here, we investigate the structural determinants of NPM1 nucleolar localization. We show that NPM1 interacts with several G-quadruplex regions found in ribosomal DNA, both in vitro and in vivo. Furthermore, the most common leukemic NPM1 variant completely loses this activity. This is the consequence of G-quadruplex–binding domain destabilization, as mutations aimed at refolding the leukemic variant also result in rescuing the G-quadruplex–binding activity and nucleolar localization. Finally, we show that treatment of cells with a G-quadruplex selective ligand results in wild-type NPM1 dislocation from nucleoli into nucleoplasm. In conclusion, this work establishes a direct correlation between NPM1 G-quadruplex binding at rDNA and its nucleolar localization, which is impaired in the acute myeloid leukemia-associated protein variants.     

Coexistence of G-quadruplex and duplex domains within the secondary structure of 31-mer DNA thrombin-binding aptamer

A number of thrombin-binding DNA aptamers have been developed during recent years. So far the structure of just a single one, 15-mer thrombin-binding aptamer (15TBA), has been solved as G-quadruplex. Structures of others, showing variable anticoagulation activities, are still not known yet. In this paper, we applied the circular dichroism and UV spectroscopy to characterize the temperature unfolding and conformational features of 31-mer thrombin-binding aptamer (31TBA), whose sequence has a potential to form G-quadruplex and duplex domains. Both structural domains were monitored independently in 31TBA and in several control oligonucleotides unable to form either the duplex region or the G-quadruplex region. The major findings are as follows: (1) both duplex and G-quadruplex domains coexist in intramolecular structure of 31TBA, (2) the formation of duplex domain does not change the fold of G-quadruplex, which is very similar to that of 15TBA, and (3) the whole 31TBA structure disrupts if either of two domains is not formed: the absence of duplex structure in 31TBA abolishes G-quadruplex, and vice versa, the lack of G-quadruplex folding results in disallowing the duplex domain.     

Fast screening and structural elucidation of G-quadruplex ligands from a mixture via G-quadruplex recognition and NMR methods

Currently, there is a considerable interest in discovering G-quadruplex ligands. Plant-derived agents, because of their diversity in structure and bioactivity and low toxicity, may be a very diverse source of G-quadruplex ligands. However, up to now, the screening of G-quadruplex ligands from natural plant extract has not been reported. Herein, in order to develop a simple method for fast identifying G-quadruplex ligands from plant extract, we intended to substitute the spectral shift in the imino region (δ 10–12) in ¹H NMR spectra of G-quadruplex for in vitro bioassay to judge the existence/nonexistence of G-quadruplex ligand(s) in plant extract, and then couple G-quadruplex recognition with NMR based structure elucidation to identify the structure of the ligand(s) without the need of prior separation. In this paper, we successfully screened a G-quadruplex ligand from a simulated plant extract using this approach. This research work provides a promising tactic to find new leading compounds from nature plant extract.     

Coexistence of G-quadruplex and duplex domains within the secondary structure of 31-mer DNA thrombin-binding aptamer

A number of thrombin-binding DNA aptamers have been developed during recent years. So far the structure of just a single one, 15-mer thrombin-binding aptamer (15TBA), has been solved as G-quadruplex. Structures of others, showing variable anticoagulation activities, are still not known yet. In this paper, we applied the circular dichroism and UV spectroscopy to characterize the temperature unfolding and conformational features of 31-mer thrombin-binding aptamer (31TBA), whose sequence has a potential to form G-quadruplex and duplex domains. Both structural domains were monitored independently in 31TBA and in several control oligonucleotides unable to form either the duplex region or the G-quadruplex region. The major findings are as follows: (1) both duplex and G-quadruplex domains coexist in intramolecular structure of 31TBA, (2) the formation of duplex domain does not change the fold of G-quadruplex, which is very similar to that of 15TBA, and (3) the whole 31TBA structure disrupts if either of two domains is not formed: the absence of duplex structure in 31TBA abolishes G-quadruplex, and vice versa, the lack of G-quadruplex folding results in disallowing the duplex domain.     

Position and stability are determining factors for translation repression by an RNA G-quadruplex-forming sequence within the 5' UTR of the NRAS proto-oncogene

Nucleic acid secondary structures in the 5' untranslated regions (UTRs) of mRNAs have been shown to play a critical role in translation regulation. We recently demonstrated that a naturally occurring, conserved, and stable RNA G-quadruplex element (5'-GGGAGGGGCGGGUCUGGG-3'), located close to the 5' cap within the 5' UTR of the NRAS proto-oncogene mRNA, modulates gene expression at the translational level. Herein, we show that the translational effect of this G-quadruplex motif in NRAS 5' UTR is not uniform, but rather depends on the location of the G-quadruplex-forming sequence. The RNA G-quadruplex-forming sequence represses translation when situated relatively proximal to the 5' end, within the first 50 nt, in the 5' UTR of the NRAS proto-oncogene, whereas it has no significant effect on translation if located comparatively away from the 5' end. We have also demonstrated that the thermodynamic stability of the RNA G-quadruplex at its natural position within the NRAS 5' UTR is an important factor contributing toward its ability to repress translation.     

Identification of cis elements which direct the localization of maternal mRNAs to the posterior pole of ascidian embryos

During ascidian embryogenesis, some mRNAs show clear localization at the posterior-most region. These postplasmic mRNAs are divided into two groups (type I and type II) according to their pattern of localization. To elucidate how these localization patterns are achieved, we attempted to identify the localization elements of these mRNAs. When in vitro synthesized postplasmic mRNAs were introduced into eggs, these mRNAs showed posterior localization similar to the endogenous mRNAs. The posterior localization of these mRNAs was mediated by their 3' untranslated regions (3' UTRs), as is the case for several localized Drosophila and Xenopus mRNAs. We identified smaller fragments of the 3' UTRs of HrWnt-5 and HrPOPK-1 mRNAs (type I) and HrPet-3 mRNA (type II) that were sufficient to direct green fluorescent protein mRNA to the posterior pole. For the localization of HrWnt-5 mRNA, two UG dinucleotide repetitive elements were essential. Motifs similar to these small elements also exist within the HrPOPK-1 mRNA localization element and 3' UTR of HrZF-1 mRNA, suggesting the conservation of localization elements among type I mRNAs. In contrast, the smallest sequence that suffices for the posterior localization of HrPet-3 (a type II mRNA) has different features from those of type I mRNAs; indeed, it does not have an identifiable critical element. This difference may distinguish type II mRNAs from type I mRNAs. These findings, especially the identification of the small localization element of HrWnt-5 mRNA, provide new insights into the localization of mRNAs during ascidian embryogenesis.     

Cloning, localization and differential expression of the Trypanosoma cruzi TcOGNT-2 glycosyl transferase

It is well established that G-quadruplex DNA structures form at ciliate telomeres and their formation throughout the cell-cycle by telomere-end-binding proteins (TEBPs) has been analyzed. During replication telomeric G-quadruplex structure has to be resolved to allow telomere replication by telomerase. It was shown that both phosphorylation of TEBPβ and binding of telomerase are prerequisites for this process, but probably not sufficient to unfold G-quadruplex structure in timely manner to allow replication to proceed. Here we describe a RecQ-like helicase required for unfolding of G-quadruplex structures in vivo. This helicase is highly reminiscent of human RecQ protein-like 4 helicase as well as other RecQ-like helicase found in various eukaryotes and E. coli. In situ analyses combined with specific silencing of either the telomerase or the helicase by RNAi and co-immunoprecipitation experiments demonstrate that this helicase is associated with telomerase during replication and becomes recruited to telomeres by this enzyme. In vitro assays showed that a nuclear extract prepared from cells in S-phase containing both the telomerase as well as the helicase resolves telomeric G-quadruplex structure. This finding can be incorporated into a mechanistic model about the replication of telomeric G-quadruplex structures during the cell cycle.     

Analysis of the Fragile X mental retardation protein isoforms 1, 2 and 3 interactions with the G-quadruplex forming semaphorin 3F mRNA

Fragile X syndrome, the most prevalent inheritable mental retardation, is caused by the loss of fragile X mental retardation protein (FMRP) expression. FMRP is an RNA-binding protein with nucleo-cytoplasmic shuttle activity, proposed to act as a translation regulator of specific mRNAs in the brain. It has been shown that FMRP uses its arginine-glycine-glycine (RGG) box domain to bind a subset of mRNA targets that form a G-quadruplex structure. FMRP has also been shown to undergo the post-translational modifications of arginine methylation and phosphorylation, as well as alternative splicing, resulting in multiple isoforms. The alternative splice isoforms investigated in this study, isoform 1 (ISO1), isoform 2 (ISO2), and isoform 3 (ISO3), are created by the alternative splicing acceptor site at exon 15. FMRP ISO2 and ISO3 are truncated by 12 and 13 residues, respectively, relative to the longest FMRP isoform ISO1. These truncations, which are in the close proximity of the RGG box domain, preserve the integrity of the RGG box in all three isoforms, but eliminate the in vivo phosphorylation sites, present only on FMRP ISO1. We have expressed and purified recombinant FMRP ISO1, ISO2 and ISO3 in Escherichia coli, free of post-translational modifications, and by using fluorescence spectroscopy, we show that each FMRP isoform binds G-quadruplex RNA, albeit with different binding affinities, suggesting that naturally occurring sequence modifications in the proximity of the RGG box modulate its G-quadruplex RNA binding ability.     

Loop lengths of G-quadruplex structures affect the G-quadruplex DNA binding selectivity of the RGG motif in Ewing's sarcoma

The G-quadruplex nucleic acid structural motif is a target for designing molecules with potential anticancer properties. To achieve therapeutic selectivity by targeting the G-quadruplex, the molecules must be able to differentiate between the DNA of different G-quadruplexes. We recently reported that the Arg-Gly-Gly repeat (RGG) of the C-terminus in Ewing's sarcoma protein (EWS), which is a group of dominant oncogenes that arise due to chromosomal translocations, is capable of binding to G-quadruplex telomere DNA and RNA via arginine residues and stabilize the G-quadruplex DNA form in vitro. Here, we show that the RGG of EWS binds preferentially to G-quadruplexes with longer loops, which is not related to the topology of the G-quadruplex structure. Moreover, the G-quadruplex DNA binding of the RGG in EWS depends on the phosphate backbone of the loops in the G-quadruplex DNA. We also investigated the G-quadruplex DNA binding activity of the N- and C-terminally truncated RGG to assess the role of the regions in the RGG in G-quadruplex DNA binding. Our findings indicate that the RGG and the other arginine-rich motif of residues 617-656 of the RGG in EWS are important for the specific binding to G-quadruplex DNA. These findings will contribute to the development of molecules that selectively target different G-quadruplex DNA.     

Genome-wide analysis demonstrates conserved localization of messenger RNAs to mitotic microtubules

RNA localization is of critical importance in many fundamental cell biological and developmental processes by regulating the spatial control of gene expression. To investigate how spindle-localized RNAs might influence mitosis, we comprehensively surveyed all messenger RNAs (mRNAs) that bound to microtubules during metaphase in both Xenopus laevis egg extracts and mitotic human cell extracts. We identify conserved classes of mRNAs that are enriched on microtubules in both human and X. laevis. Active mitotic translation occurs on X. laevis meiotic spindles, and a subset of microtubule-bound mRNAs (MT-mRNAs) associate with polyribosomes. Although many MT-mRNAs associate with polyribosomes, we find that active translation is not required for mRNA localization to mitotic microtubules. Our results represent the first genome-wide survey of mRNAs localized to a specific cytoskeletal component and suggest that microtubule localization of specific mRNAs is likely to function in mitotic regulation and mRNA segregation during cell division.     

Specific stabilization of DNA G-quadruplex structures with a chemically modified complementary probe

The DNA G-quadruplex is an important higher-order structure formed from guanine-rich DNA sequences. There are many molecules which can stabilize this structure. However, the selectivity of these ligands to different G-quadruplexes was not satisfactory. Herein, we designed and synthesized a chemically modified G-quadruplex probe, Razo-DNA, for the unique stabilization of the G-quadruplex. Razo-DNA consists of two fragments: The first is an organic molecular moiety which can stabilize G-quadruplex structures, and the second is a DNA molecule that is complementary with a sequence adjacent to the guanine-rich sequence of targeted DNA. Further studies showed that Razo-DNA could precisely stabilize the targeted DNA G-quadruplex structures in vitro.