Isoxazole-containing 5' mRNA cap analogues as inhibitors of the translation initiation process.

Herein we describe a synthesis of new isoxazole-containing 5' mRNA cap analogues via a cycloaddition reaction. The obtained analogues show a capability to inhibit cap-dependent translation in vitro and are characterized by a new binding mode in which an isoxazolic ring, instead of guanine, is involved in the stacking effect. Our study provides valuable information toward designing new compounds that can be potentially used as anticancer therapeutics.

Exploring the potential of phosphotriazole 5' mRNA cap analogues as efficient translation initiators.

Augmenting the mRNA translation efficiency and stability by replacing the standard 7-methylguanosine 5'-cap with properly designed analogues is a viable strategy for increasing the in vivo expression of proteins from exogenously delivered mRNA. However, the development of novel cap analogues with superior biological properties is hampered by the challenges associated with the synthesis of such highly modified nucleotides. To provide a simpler alternative to traditional methods for cap analogue preparation, we have recently proposed a click-chemistry-based strategy for the synthesis of dinucleotide cap analogues and identified several triazole-containing compounds with promising biochemical properties. Here, we further explored the concept of CuAAC-mediated cap synthesis by designing and studying 'second generation' triazole-modified caps, which were derived from the most promising 'first generation' compounds by modifying the oligophosphate chain length, altering the position of the triazole moiety, or replacing chemically labile P-N bonds with P-O bonds. The biochemical properties of the new analogues were evaluated by determining their affinity for eIF4E, susceptibility to hDcp2-catalysed decapping, and translation efficiencies in vitro and in cultured cells. The results led to identification of cap analogues that have superior translational properties compared to standard caps and the parent triazole-modified compounds as well as provided directions for future improvements.

Capped RNA primer binding to influenza polymerase and implications for the mechanism of cap-binding inhibitors.

Influenza polymerase uses short capped primers snatched from nascent Pol II transcripts to initiate transcription of viral mRNAs. Here we describe crystal structures of influenza A and B polymerase bound to a capped primer in a configuration consistent with transcription initiation ('priming state') and show by functional assays that conserved residues from both the PB2 midlink and cap-binding domains are important for positioning the capped RNA. In particular, mutation of PB2 Arg264, which interacts with the triphosphate linkage in the cap, significantly and specifically decreases cap-dependent transcription. We also compare the configuration of the midlink and cap-binding domains in the priming state with their very different relative arrangement (called the 'apo' state) in structures where the potent cap-binding inhibitor VX-787, or a close analogue, is bound. In the 'apo' state the inhibitor makes additional interactions to the midlink domain that increases its affinity beyond that to the cap-binding domain alone. The comparison suggests that the mechanism of resistance of certain mutations that allow virus to escape from VX-787, notably PB2 N510T, can only be rationalized if VX-787 has a dual mode of action, direct inhibition of capped RNA binding as well as stabilization of the transcriptionally inactive 'apo' state.

7-Methylguanosine monophosphate analogues with 5'-(1,2,3-triazoyl) moiety: Synthesis and evaluation as the inhibitors of cNIIIB nucleotidase.

The hydrolysis of nucleoside 5'-monophosphates to the corresponding nucleosides and inorganic phosphate is catalysed by 5'-nucleotidases, thereby contributing to the control of endogenous nucleotide turnover and affecting the fate of exogenously delivered nucleotide- and nucleoside-derived therapeutics in cells. A recently identified nucleotidase cNIIIB shows preference towards 7-methylguanosine monophosphate (m7GMP) as a substrate, which suggests its potential involvement in mRNA degradation. However, the extent of biological functions and the significance of cNIIIB remains to be elucidated. Here, we synthesised a series of m7GMP analogues carrying a 1,2,3-triazole moiety at the 5' position as the potential inhibitors of human cNIIIB. The compounds were synthesised by using the copper-catalysed azide-alkyne cycloaddition (CuAAC) between 5'-azido-5'-deoxy-7-methylguanosine and different phosphate or phosphonate derivatives carrying terminal alkyne. The analogues were evaluated as cNIIIB inhibitors using HPLC and malachite green assays, demonstrating that compound 1a, carrying a 1,2,3-triazoylphosphonate moiety, inhibits cNIIIB activity at micromolar concentrations (IC50 87.8 ±â€¯7.5 µM), while other analogues showed no activity. In addition, compound 1d was identified as an artifical substrate for HscNIIIB. Further characterization of inhibitor 1a revealed that it is poorly recognised by other m7G-binding proteins, eIF4E and DcpS, indicating its selectivity towards cNIIIB. The first inhibitor (1a) and unnatural substrate (1d) of cNIIIB, identified here, can be used as molecular probes for the elucidation of biological roles of cNIIIB, including the verification of its proposed function in mRNA metabolism.

mRNA cap analogues substituted in the tetraphosphate chain with CX2: identification of O-to-CCl2 as the first bridging modification that confers resistance to decapping without impairing translation.

Analogues of the mRNA 5'-cap are useful tools for studying mRNA translation and degradation, with emerging potential applications in novel therapeutic interventions including gene therapy. We report the synthesis of novel mono- and dinucleotide cap analogues containing dihalogenmethylenebisphosphonate moiety (i.e. one of the bridging O atom substituted with CCl2 or CF2) and their properties in the context of cellular translational and decapping machineries, compared to phosphate-unmodified and previously reported CH2-substituted caps. The analogues were bound tightly to eukaryotic translation initiation factor 4E (eIF4E), with CCl2-substituted analogues having the highest affinity. When incorporated into mRNA, the CCl2-substituted dinucleotide most efficiently promoted cap-dependent translation. Moreover, the CCl2-analogues were potent inhibitors of translation in rabbit reticulocyte lysate. The crystal structure of eIF4E in complex with the CCl2-analogue revealed a significantly different ligand conformation compared to that of the unmodified cap analogue, which likely contributes to the improved binding. Both CCl2- and CF2- analogues showed lower susceptibility to hydrolysis by the decapping scavenger enzyme (DcpS) and, when incorporated into RNA, conferred stability against major cellular decapping enzyme (Dcp2) to transcripts. Furthermore, the use of difluoromethylene cap analogues was exemplified by the development of 19F NMR assays for DcpS activity and eIF4E binding.

Design, synthesis and biological evaluation of dinucleotide mRNA cap analog containing propargyl moiety.

The first example of the synthesis of new dinucleotide cap analog containing propargyl group such as m(7,3'-O-propargyl)G[5']ppp[5']G is reported. The effect of propargyl cap analog with standard cap was evaluated with respect to their capping efficiency, in vitro T7 RNA polymerase transcription efficiency, and translation activity using cultured HeLa cells. It is noteworthy that propargyl cap analog outperforms standard cap by 3.1 fold in terms of translational properties. The propargyl cap analog forms a more stable complex with translation initiation factor eIF4E based on the molecular modeling studies.

Triazole-containing monophosphate mRNA cap analogs as effective translation inhibitors.

Synthetic analogs of the 5' end of mRNA (cap structure) are widely used in molecular studies on mechanisms of cellular processes such as translation, intracellular transport, splicing, and turnover. The best-characterized cap binding protein is translation initiation factor 4E (eIF4E). Recognition of the mRNA cap by eIF4E is a critical, rate-limiting step for efficient translation initiation and is considered a major target for anticancer therapy. Here, we report a facile methodology for the preparation of N2-triazole-containing monophosphate cap analogs and present their biological evaluation as inhibitors of protein synthesis. Five analogs possessing this unique hetero-cyclic ring spaced from the m7-guanine of the cap structure at a distance of one or three carbon atoms and/or additionally substituted by various groups containing the benzene ring were synthesized. All obtained compounds turned out to be effective translation inhibitors with IC50 similar to dinucleotide triphosphate m(7)GpppG. As these compounds possess a reduced number of phosphate groups and, thereby, a negative charge, which may support their cell penetration, this type of cap analog might be promising in terms of designing new potential therapeutic molecules. In addition, an exemplary dinucleotide from a corresponding mononucleotide containing benzyl substituted 1,2,3-triazole was prepared and examined. The superior inhibitory properties of this analog (10-fold vs. m(7)GpppG) suggest the usefulness of such compounds for the preparation of mRNA transcripts with high translational activity.

Synthesis, properties, and biological activity of boranophosphate analogs of the mRNA cap: versatile tools for manipulation of therapeutically relevant cap-dependent processes.

Modified mRNA cap analogs aid in the study of mRNA-related processes and may enable creation of novel therapeutic interventions. We report the synthesis and properties of 11 dinucleotide cap analogs bearing a single boranophosphate modification at either the α-, ß- or γ-position of the 5',5'-triphosphate chain. The compounds can potentially serve either as inhibitors of translation in cancer cells or reagents for increasing expression of therapeutic proteins in vivo from exogenous mRNAs. The BH3-analogs were tested as substrates and binding partners for two major cytoplasmic cap-binding proteins, DcpS, a decapping pyrophosphatase, and eIF4E, a translation initiation factor. The susceptibility to DcpS was different between BH3-analogs and the corresponding analogs containing S instead of BH3 (S-analogs). Depending on its placement, the boranophosphate group weakened the interaction with DcpS but stabilized the interaction with eIF4E. The first of the properties makes the BH3-analogs more stable and the second, more potent as inhibitors of protein biosynthesis. Protein expression in dendritic cells was 2.2- and 1.7-fold higher for mRNAs capped with m2 (7,2'-O)GppBH3pG D1 and m2 (7,2'-O)GppBH3pG D2, respectively, than for in vitro transcribed mRNA capped with m2 (7,3'-O)GpppG. Higher expression of cancer antigens would make mRNAs containing m2 (7,2'-O)GppBH3pG D1 and m2 (7,2'-O)GppBH3pG D2 favorable for anticancer immunization.

Synthesis and biological validation of N7-(4-chlorophenoxyethyl) substituted dinucleotide cap analogs for mRNA translation.

Design, synthesis and biological validation of dinucleotide cap analogs, N(7)-(4-chlorophenoxyethyl)-G(5')ppp(5')G (5a) and N(7)-(4-chlorophenoxyethyl)-m(3'-O)G(5')ppp(5')G (5b) are reported. The effect of N(7)-(4-chlorophenoxyethyl) substitution on cap analogs has been evaluated with respect to its in vitro transcription by using T7 RNA polymerase capping efficiency, and translational activity. The gel shift assay indicates that the new cap analogs (5a, 5b) showed 77% and 76% capping efficiency respectively, whereas the standard cap analog, m(7)G(5')ppp(5')G has a capping efficiency of 63%. The capping efficiency experiment clearly demonstrates that the N(7)-modified analogs are good substrate for T7 RNA polymerase. It is noteworthy that the mRNA poly(A) capped with N(7)-(4-chlorophenoxyethyl)-m(3'-O)G(5')ppp(5')G (5b) was translated ∼1.64-fold more efficiently, while compound (5a) was translated ∼0.72-fold less efficiently than mRNA capped with standard cap analog. The observed low translation activity for (5a) could be due to stability in the form of dinucleotide cap analogs. Based on the substrate compatability of the N(7) modification in dinucleotide form, these new analogs may be used for structure function studies as well as protein production.

Potential therapeutic applications of RNA cap analogs.

Cap analogs are chemically modified derivatives of the unique cap structure present at the 5´ end of all eukaryotic mRNAs and several non-coding RNAs. Until recently, cap analogs have served primarily as tools in the study of RNA metabolism. Continuing advances in our understanding of cap biological functions (including RNA stabilization, pre-mRNA splicing, initiation of mRNA translation, as well as cellular transport of mRNAs and snRNAs) and the consequences of the disruption of these processes - resulting in serious medical disorders - have opened new possibilities for pharmaceutical applications of these compounds. In this review, the medicinal potential of cap analogs in areas, such as cancer treatment (including eIF4E targeting and mRNA-based immunotherapy), spinal muscular atrophy treatment, antiviral therapy and the improvement of the localization of nucleus-targeting drugs, are highlighted. Advances achieved to date, challenges, plausible solutions and prospects for the future development of cap analog-based drug design are described.

Synthesis of N²-modified 7-methylguanosine 5'-monophosphates as nematode translation inhibitors.

Preparative scale synthesis of 14 new N(2)-modified mononucleotide 5' mRNA cap analogues was achieved. The key step involved use of an S(N)Ar reaction with protected 2-fluoro inosine and various primary and secondary amines. The derivatives were tested in a parasitic nematode, Ascaris suum, cell-free system as translation inhibitors. The most effective compound with IC(50) ∼0.9µM was a N(2)-p-metoxybenzyl-7-methylguanosine-5'-monophosphate 35.

Synthesis and evaluation of 2'-O-allyl substituted dinucleotide cap analog for mRNA translation.

The first example of the synthesis and biological evaluation of a new analog containing 2'-OH modification on m(7)G moiety, that is, m(7,2'-)(O-Allyl)GpppG is reported. The effect of the 2'-O-allyl substitution on cap analog has been evaluated with respect to its in vitro transcription by using T7 RNA polymerase, capping efficiency, and translational activity. The gel shift assay indicates that the new cap analog has 59% capping efficiency whereas the standard cap analog, m(7)GpppG has a capping efficiency of 70%. The capping efficiency experiment clearly demonstrates that the new analog was a substrate for T7 RNA polymerase. The nature of the orientation has been determined by HPLC that reveals that the new analog incorporates exclusively in the forward orientation. It is noteworthy that the mRNA poly(A) capped with 2'-O-allyl substituted cap analog was translated ∼1.7-fold more efficiently than the mRNA capped with standard cap analog. Based on the higher translational data compared to the standard cap analog, it is likely that the new analog may find application that utilize mRNA transfection such as protein production, anti-cancer immunization, and gene therapy.

Cap analog substrates reveal three clades of cap guanine-N2 methyltransferases with distinct methyl acceptor specificities.

The Tgs proteins are structurally homologous AdoMet-dependent eukaryal enzymes that methylate the N2 atom of 7-methyl guanosine nucleotides. They have an imputed role in the synthesis of the 2,2,7-trimethylguanosine (TMG) RNA cap. Here we exploit a collection of cap-like substrates to probe the repertoire of three exemplary Tgs enzymes, from mammalian, protozoan, and viral sources, respectively. We find that human Tgs (hTgs1) is a bona fide TMG synthase adept at two separable transmethylation steps: (1) conversion of m(7)G to m(2,7)G, and (2) conversion of m(2,7)G to m(2,2,7)G. hTgs1 is unable to methylate G or m(2)G, signifying that both steps require an m(7)G cap. hTgs1 utilizes a broad range of m(7)G nucleotides, including mono-, di-, tri-, and tetraphosphate derivatives as well as cap dinucleotides with triphosphate or tetraphosphate bridges. In contrast, Giardia lamblia Tgs (GlaTgs2) exemplifies a different clade of guanine-N2 methyltransferase that synthesizes only a dimethylguanosine (DMG) cap structure and cannot per se convert DMG to TMG under any conditions tested. Methylation of benzyl(7)G and ethyl(7)G nucleotides by hTgs1 and GlaTgs2 underscored the importance of guanine N7 alkylation in providing a key pi-cation interaction in the methyl acceptor site. Mimivirus Tgs (MimiTgs) shares with the Giardia homolog the ability to catalyze only a single round of methyl addition at guanine-N2, but is distinguished by its capacity for guanine-N2 methylation in the absence of prior N7 methylation. The relaxed cap specificity of MimiTgs is revealed at alkaline pH. Our findings highlight both stark and subtle differences in acceptor specificity and reaction outcomes among Tgs family members.

Mesoionic heterocyclic compounds as candidate messenger RNA cap analogue inhibitors of the influenza virus RNA polymerase cap-binding activity.

BACKGROUND: An unusual feature of influenza viral -messenger RNA (mRNA) synthesis is its dependence upon host cell mRNAs as a source of capped RNA primers. A crucial activity of the influenza polymerase is to steal these primers by binding and cleaving the caps from host mRNAs. The recent structural analysis of the cap-binding fragment of the influenza virus PB2 protein has highlighted the importance of the mesoionic properties of the N7-methylguanine (N(7m)G) component of the mRNA cap in this interaction. METHODS: A series of mesoionic heterocycles with 5,6-fused ring systems analogous to the N(7m)G component of mRNA cap structures were synthesized and examined for the ability to inhibit the cap-binding activity of the influenza virus RNA polymerase complex using a bead-based in vitro cap-binding assay. RESULTS: None of the compounds tested were able to significantly inhibit binding and subsequent endonucleolytic cleavage of a synthetic radiolabelled capped mRNA substrate by recombinant influenza virus polymerase in vitro. CONCLUSIONS: Compounds analogous to the mesoionic N(7m)G component of mRNA cap structures comprise a large class of potential inhibitors of the influenza virus polymerase. Although this preliminary assessment of a small group of related analogues was unsuccessful, further screening of this class of compounds is warranted.

Phosphorothioate analogs of m7GTP are enzymatically stable inhibitors of cap-dependent translation.

We report synthesis and properties of a pair of new potent inhibitors of translation, namely two diastereomers of 7-methylguanosine 5'-(1-thiotriphosphate). These new analogs of mRNA 5'cap (referred to as m(7)GTPalphaS (D1) and (D2)) are recognized by translational factor eIF4E with high affinity and are not susceptible to hydrolysis by Decapping Scavenger pyrophosphatase (DcpS). The more potent of diastereomers, m(7)GTPalphaS (D1), inhibited cap-dependent translation in rabbit reticulocyte lysate approximately 8-fold and approximately 15-fold more efficiently than m(7)GTP and m(7)GpppG, respectively. Both analogs were also significantly more stable in RRL than unmodified ones.

Translation initiation of the human tau mRNA through an internal ribosomal entry site.

Neurofibrillary tangles are a pathological phenotype in Alzheimer's disease (AD) and are caused by the hyperphosphorylation of the microtubule associated protein tau. In mouse models of AD, decreasing tau protein expression limits the severity of symptoms and inhibits progression of AD. We now report that the 5' leader in the human tau mRNA contains an internal ribosomal entry site (IRES) and that IRES-dependent translation plays a role in the synthesis of tau protein. Consequently, targeting the tau IRES provides a novel target for regulating tau expression in AD and other tauopathies.

m7GTP alphaS is a strong and stable inhibitor of cap-dependent translation.

Two diastereomers of 7-methylguanosine 5'-O-(1-thiotriphosphate) have been synthesized and resolved by RP HPLC. Preliminary studies revealed that these new analogs of mRNA cap are characterized by high affinity for eIF4E, resistance towards DcpS pyrophosphatase and high potency to inhibit cap-dependent translation.

Synthesis and characterization of mRNA cap analogs containing phosphorothioate substitutions that bind tightly to eIF4E and are resistant to the decapping pyrophosphatase DcpS.

Analogs of the mRNA cap are widely employed to study processes involved in mRNA metabolism as well as being useful in biotechnology and medicinal applications. Here we describe synthesis of six dinucleotide cap analogs bearing a single phosphorothioate modification at either the alpha, beta, or gamma position of the 5',5'-triphosphate chain. Three of them were also modified with methyl groups at the 2'-O position of 7-methylguanosine to produce anti-reverse cap analogs (ARCAs). Due to the presence of stereogenic P centers in the phosphorothioate moieties, each analog was obtained as a mixture of two diastereomers, D1 and D2. The mixtures were resolved by RP HPLC, providing 12 different compounds. Fluorescence quenching experiments were employed to determine the association constant (K(AS)) for complexes of the new analogs with eIF4E. We found that phosphorothioate modifications generally stabilized the complex between eIF4E and the cap analog. The most strongly bound phosphorothioate analog (the D1 isomer of the beta-substituted analog m(7)Gpp(S)pG) was characterized by a K(AS) that was more than fourfold higher than that of its unmodified counterpart (m(7)GpppG). All analogs modified in the gamma position were resistant to hydrolysis by the scavenger decapping pyrophosphatase DcpS from both human and Caenorhabditis elegans sources. The absolute configurations of the diastereomers D1 and D2 of analogs modified at the alpha position (i.e., m(7)Gppp(S)G and m(2) (7,2'-O )Gppp(S)G) were established as S(P) and R(P) , respectively, using enzymatic digestion and correlation with the S(P) and R(P) diastereomers of guanosine 5'-O-(1-thiodiphosphate) (GDPalphaS). The analogs resistant to DcpS act as potent inhibitors of in vitro protein synthesis in rabbit reticulocyte lysates.

Synthesis and biological evaluation of trimethyl-substituted cap analogs.

The N(7)-methyl guanosine cap located on the 5'-terminus of mRNAs is important for a number of biochemical processes. A new dinucleoside triphosphate cap analog was synthesized with methyl groups on the N(7) of both guanine moieties, as well as the 3'-OH of one of the ribose moieties [see text]. The function of this trimethylated cap analog was compared with those of three other, less-methylated cap analogs: one omitting the ribose methylation (m(7)G[5']ppp[5']m(7)G), one omitting the N(7) methylation linked to the unmodified ribose [see text], and the standard cap analog, m(7)G[5']ppp[5']G. These cap modifications were assayed with respect to their effects on capping efficiency, yield of RNAs during in vitro transcription, and the translational activity of these RNAs upon transfection into HeLa cells. The translational activity was monitored by measuring the luciferase activity of a luciferase-fusion protein produced from the in vitro synthesized RNAs. The RNA capped with the trimethylated analog [see text] was translated the most efficiently, with approximately 2.6-fold more activity than the conventional cap (m(7)G[5']ppp[5']G). The other two variants were also more efficient, generating, approximately 2.2 times (for the [see text] analog) and, approximately 1.6 times (for the m(7)G[5']ppp[5']m(7)G analog) more luciferase function than the conventional cap.

Kinetics of C. elegans DcpS cap hydrolysis studied by fluorescence spectroscopy.

DcpS (scavenger decapping enzyme) from nematode C. elegans readily hydrolyzes both monomethyl- and trimethylguanosine cap analogues. The reaction was followed fluorimetrically. The marked increase of fluorescence intensity after the cleavage of pyrophosphate bond in dinucleotides was used to determine K(m) and V(max)values. Kinetic parameters were similar for both classes of substrates and only slightly dependent on pH. The hydrolysis was strongly inhibited by methylene cap analogues (m(7)Gp(CH(2))ppG and m(7)Gpp(CH(2))pG) and less potently by ARCA (m(7,3' O)GpppG).