Synthesis of 5' cap-0 and cap-1 RNAs using solid-phase chemistry coupled with enzymatic methylation by human (guanine-N⁷)-methyl transferase

The 5' end of eukaryotic mRNA carries a N(7)-methylguanosine residue linked by a 5'-5' triphosphate bond. This cap moiety ((7m)GpppN) is an essential RNA structural modification allowing its efficient translation, limiting its degradation by cellular 5' exonucleases and avoiding its recognition as "nonself" by the innate immunity machinery. In vitro synthesis of capped RNA is an important bottleneck for many biological studies. Moreover, the lack of methods allowing the synthesis of large amounts of RNA starting with a specific 5'-end sequence have hampered biological and structural studies of proteins recognizing the cap structure or involved in the capping pathway. Due to the chemical nature of N(7)-methylguanosine, the synthesis of RNAs possessing a cap structure at the 5' end is still a significant challenge. In the present work, we combined a chemical synthesis method and an enzymatic methylation assay in order to produce large amounts of RNA oligonucleotides carrying a cap-0 or cap-1. Short RNAs were synthesized on solid support by the phosphoramidite 2'-O-pivaloyloxymethyl chemistry. The cap structure was then coupled by the addition of GDP after phosphorylation of the terminal 5'-OH and activation by imidazole. After deprotection and release from the support, GpppN-RNAs or GpppN(2'-Om)-RNAs were purified before the N(7)-methyl group was added by enzymatic means using the human (guanine-N(7))-methyl transferase to yield (7m)GpppN-RNAs (cap-0) or (7m)GpppN(2'-Om)-RNAs (cap-1). The RNAs carrying different cap structures (cap, cap-0 or, cap-1) act as bona fide substrates mimicking cellular capped RNAs and can be used for biochemical and structural studies.     

Two methyltransferase activities in the purified virions of vesicular stomatitis virus.

In addition to an RNA-dependent RNA polymerase, purified vesicular stomatitis virus contains a methyltransferase activity which transfers the methyl group from the methyl donor, S-adenosyl-L-methionine, to two positions in the 5'-terminal capped structure of the nascent mRNA's synthesized in vitro as 7mG-(5)'ppp(5')Apm... In the present study it is shown that two distinct methyltransferase activities are discernible in the purified virus. The in vitro concentrations of the methyl donor specify the number and location of the methyl groups transferred to the capped 5'-termini of VSV mRNA's. Limited concentrations of the methyl donor result in a single methylation of the penultimate base in the 2'-hydroxyl position, that is, G(5')ppp(5')Apm..., whereas saturating concentrations of the methyl donor methylate the blocking guanosine residue at the 7-position, resulting in the dimethylated cap, 7mG(5')ppp(5')Apm... Pulse-chase experiments demonstrate that the monomethylated cap structure is the precursor substrate for the dimethylated cap. In this respect, vesicular stomatitis virus system is quite distinct from the vaccinia and reovirus systems. Virus purified from different host cells including hamster, mouse, and human contain both methyltransferase activities. The mRNA's containing monomethylated capped structures are poor templates for protein synthesis in vitro.     

Synthesis of Leishmania cap-4 intermediates, cap-2 and cap-3

Synthesis of Leishmania mRNA 5'-cap analogs, m(7)Gpppm(2)(6)AmpAm (cap-2), and m(7)Gpppm(2)(6)AmpAmpCm (cap-3) is reported. Binding affinities of those cap analogs for LeishIF4E proteins were determined using fluorescence spectroscopy. Cap-3 showed similar affinity to LeishIF4Es compared to the mature trypanosomatids cap structure (cap-4).     

Effect of capping upon the mRNA properties of satellite tobacco necrosis virus ribonucleic acid.

The mRNA guanyltransferase-mRNA methyltransferases of vaccinia virions can be used to introduce a 5'-terminal m7g(5')pp(5')Apm... capping group onto the RNA of satellite tobacco necrosis virus (STNV RNA) to yield intact capped STNV RNA. Studies with an in vitro system from wheat germ and limiting quantities of capped and uncapped STNV RNA show that the rates and extents of formation of initiation complexes of protein synthesis by intact capped and uncapped STNV RNA are identical, suggesting that 5'-terminal cap groups cannot function in the translation of STNV RNA. Also, the cap analogue pm7G equally inhibits the initiation and the translation of limiting quantities of both capped and uncapped STNV RNA. These contrasting observations suggest that the wheat germ system contains a pm7G sensitive protein and that STNV RNA has a tertiary structure that restricts the function of an added 5'-terminal capping group. This theory is supported by observations that fragmented capped STNV RNA is better at forming initiation complexes than is equally fragmented uncapped STNV RNA.     

Differential inhibition of mRNA degradation pathways by novel cap analogs

mRNA degradation predominantly proceeds through two alternative routes: the 5'-->3' pathway, which requires deadenylation followed by decapping and 5'-->3' hydrolysis; and the 3'-->5' pathway, which involves deadenylation followed by 3'-->5' hydrolysis and finally decapping. The mechanisms and relative contributions of each pathway are not fully understood. We investigated the effects of different cap structure (Gp(3)G, m(7)Gp(3)G, or m(2)(7,3'-O) Gp(3)G) and 3' termini (A(31),A(60), or G(16)) on both translation and mRNA degradation in mammalian cells. The results indicated that cap structures that bind eIF4E with higher affinity stabilize mRNA to degradation in vivo. mRNA stability depends on the ability of the 5' terminus to bind eIF4E, not merely the presence of a blocking group at the 5'-end. Introducing a stem-loop in the 5'-UTR that dramatically reduces translation, but keeping the cap structure the same, does not alter the rate of mRNA degradation. To test the relative contributions of the 5'-->3' versus 3'-->5' pathways, we designed and synthesized two new cap analogs, in which a methylene group was substituted between the alpha- and beta-phosphate moieties, m(2)(7,3'-O)Gpp(CH2)pG and m(2)(7,3'-O)Gp(CH2)ppG, that are predicted to be resistant to cleavage by Dcp1/Dcp2 and DcpS, respectively. These cap analogs were recognized by eIF4E and conferred cap-dependent translation to mRNA both in vitro and in vivo. Oligonucleotides capped with m(2)(7,3'-O)Gpp(CH2)pG were resistant to hydrolysis by recombinant human Dcp2 in vitro. mRNAs capped with m(2)(7,3'-O)Gpp(CH2)pG, but not m(2)(7,3'-O)Gp(CH2)ppG, were more stable in vivo, indicating that the 5'-->3' pathway makes a major contribution to overall degradation. Luciferase mRNA containing a 5'-terminal m(2)(7,3'-O)Gpp(CH2)pG and 3'-terminal poly(G) had the greatest stability of all mRNAs tested.     

Kinetic proofreading scanning models for eukaryotic translational initiation: the cap and poly(A) tail dependency of translation

Two simplified kinetic proofreading scanning (KPS) models were proposed to describe the 5' cap and 3' poly(A) tail dependency of eukaryotic translation initiation. In Model I, the initiation factor complex starts scanning and unwinding the secondary structure of the 5' untranslated region (UTR) from the 5' terminus of mRNA. In Model II, the initiation factor complex starts scanning from any binding site in the 5' UTR. In both models, following ATP hydrolysis, the initiation factor complex either dissociates from mRNA or continues to scan and unwind RNA secondary structure in the 5' UTR. This step repeats n times until the AUG codon is reached. These two models show very different cap and/or poly(A) tail dependency of translation initiation. The models predict that both cap and poly(A) tail dependencies of translation, and translatability of mRNAs are coupled with the structure of 5' UTR: the translation of mRNA with structured 5' UTR is strongly cap- and poly(A) tail-dependent; while translation of mRNA with unstructured 5' UTR is less cap- and poly(A) tail-dependent. We use these two models to explain: (1) the cap and poly(A) tail dependence of translation; (2) the effect of exogenous poly(A) on translation; (3) repression of host mRNA and translation of late adenovirus mRNA in the late phase of adenovirus infection; (4) repression of host mRNA and translation of Vaccinia virus mRNA in virus-infected cell; (5) heat shock repression of translation of normal mRNA and stimulation of translation of hsp mRNA; and (6) the synergistic effect of cap and poly(A) tail on stimulating translation. The kinetic proofreading scanning models provide a coherent interpretation of those phenomena.     

Kinetics of Novikoff cytoplasmic messenger RNA methylation.

Methylation patterns of Novikoff cytoplasmic mRNA were determined as a function of labeling time with L-[methyl-3H]methionine. The 5'-terminal m7G could be released from whole mRNA by treatment with nucleotide pyrophosphatase. Subsequent alkaline phosphatase treatment of this mRNA, followed by KOH digestion, yielded N'mpNp and N'mpNp from cap 1 (m7GpppN'mpN) and cap 2 (m7GpppN'mpN'mpN), respectively. Our results indicate that the relative amounts of labeled cap structures do change with time and that the amount of internal N6-methyladenosine decreases, relative to 5'-cap structures, as the cytoplasmic mRNAs age and the average size decreases. The formation of cap-2 structures by the addition of second 2'-O-methyl group at position N'm appears to be cytoplasmic event. Thus, after very short labeling times, greater than 80% of the labeled methyl groups in cap 2 are found in this position. These results, along with earlier data obtained on L-cell heterogeneous nuclear RNA methylation, are consistent with a model in which the nucleus is the cellular site of three mRNA methylation events producing 5'-terminal m7G, the first 2'-O-methylnucleoside (N'm) found in cap-1 structures and internal N6-methyladenosine. Subsequently, these nuclear methylations are followed by the cytoplasmic methylation at N'm. Analysis of the methynucleoside composition of cap-1 structures, along with comparable "core" structures (m7GpppN'm) generated from cap-2 by removal of N'm, indicates that at any single labeling time the methylnucleoside composition of a given cap-1 and the cap-2 "core" structure is remarkably similar. On the other hand, comparisons of the methylnucleoside composition of the cap structures at different labeling times indicate an increase in Cm in the first 2'-O-methylnucleoside (N'm) with time.     

Binding specificities and potential roles of isoforms of eukaryotic initiation factor 4E in Leishmania

The 5' cap structure of trypanosomatid mRNAs, denoted cap 4, is a complex structure that contains unusual modifications on the first four nucleotides. We examined the four eukaryotic initiation factor 4E (eIF4E) homologues found in the Leishmania genome database. These proteins, denoted LeishIF4E-1 to LeishIF4E-4, are located in the cytoplasm. They show only a limited degree of sequence homology with known eIF4E isoforms and among themselves. However, computerized structure prediction suggests that the cap-binding pocket is conserved in each of the homologues, as confirmed by binding assays to m(7)GTP, cap 4, and its intermediates. LeishIF4E-1 and LeishIF4E-4 each bind m(7)GTP and cap 4 comparably well, and only these two proteins could interact with the mammalian eIF4E binding protein 4EBP1, though with different efficiencies. 4EBP1 is a translation repressor that competes with eIF4G for the same residues on eIF4E; thus, LeishIF4E-1 and LeishIF4E-4 are reasonable candidates for serving as translation factors. LeishIF4E-1 is more abundant in amastigotes and also contains a typical 3' untranslated region element that is found in amastigote-specific genes. LeishIF4E-2 bound mainly to cap 4 and comigrated with polysomal fractions on sucrose gradients. Since the consensus eIF4E is usually found in 48S complexes, LeishIF4E-2 could possibly be associated with the stabilization of trypanosomatid polysomes. LeishIF4E-3 bound mainly m(7)GTP, excluding its involvement in the translation of cap 4-protected mRNAs. It comigrates with 80S complexes which are resistant to micrococcal nuclease, but its function is yet unknown. None of the isoforms can functionally complement the Saccharomyces cerevisiae eIF4E, indicating that despite their structural conservation, they are considerably diverged.     

Synthesis of Leishmania Cap-4 Intermediates,Cap-2 and Cap-3

Synthesis of Leishmania mRNA 5′-cap analogs, m ⁷ Gpppm ₂ ⁶ AmpAm (cap-2), and m ⁷ Gpppm ₂ ⁶ AmpAmpCm (cap-3) is reported. Binding affinities of those cap analogs for LeishIF4E proteins were determined using fluorescence spectroscopy. Cap-3 showed similar affinity to LeishIF4Es compared to the mature trypanosomatids cap structure (cap-4).     

Sequence specificity of internal methylation in B77 avian sarcoma virus RNA subunits.

Following ribonuclease digestion of methyl-3H-labeled B77 avian sarcoma virus RNA subunits, methylated oligonucleotides were isolated by diethylaminoethylcellulose chromotogrpahy. Partial nucleotide sequences were deduced from the known enzymatic specificities of the ribonucleases. In addition to methylated nucleosides in the 5'-terminal cap structure, m7G(5')GmpCp, N6-methyladenosine(m6A) was found to be present in only two internal sequences of the RNA molecule, Gpm6ApC and Apm6ApC. The average numbers of methylated nucleosides per RNA subunit are about 12-13 in Gpm6ApC, 1-2 in Apm6ApC, and 2 in m7GpppGmpCp. The sequences containing m6A in B77 sarcoma virus RNA are identical to m6A-containing sequences previously reported for the bulk mRNA from HeLa cells (Wei, C.M., Gershowitz, A., and Moss, B. (1976), Biochemistry 15, 397-401). Analysis of the oligonucleotides produced by RNase A digestion indicated that the sequence of bases on the 5' side of these trinucleotides is not specific. The oligonucleotide profile, however, was highly reproducible in different virus preparations. This suggests that the methylations occur at specific positions on the RNA molecule. Some of the methylated oligonucleotides produced by RNase A digestion appear to be present in less than molar amounts. Several hypotheses are proposed to explain this result.     

Affinity of dinucleotide cap analogues for human decapping scavenger (hDcpS)

Eukaryotic cells utilize scavenger decapping enzymes to degrade cap structure following 3'-5' mRNA decay. Human DcpS recently has been described as a highly specific hydrolase (a member of the HIT family) that catalyses the cleavage of m(7)GpppG and short capped oligoribonucleotides. We have demonstrated here that cap-1 (m(7)GpppGm) is a preferred substrate among several investigated dinucleotide cap analogues m(7)Gp(n)N (n = 3-5, N is a purine or pyrimidine base) and m(7)GMP is always one of the reaction product. Cap analogues containing pyrimidine base instead of guanine or diphosphate chain are resistant to hydrolysis catalyzed by human scavenger. Contrary to the other enzymes of HIT family, hDcpS activity is not stimulated by Mg(2+).     

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.     

Translational repression by a novel partner of human poly(A) binding protein, Paip2

The eukaryotic mRNA 3' poly(A) tail acts synergistically with the 5' cap structure to enhance translation. This effect is mediated by a bridging complex, composed of the poly(A) binding protein (PABP), eIF4G, and the cap binding protein, eIF4E. PABP-interacting protein 1 (Paip1) is another factor that interacts with PABP to coactivate translation. Here, we describe a novel human PABP-interacting protein (Paip2), which acts as a repressor of translation both in vitro and in vivo. Paip2 preferentially inhibits translation of a poly(A)-containing mRNA, but has no effect on the translation of hepatitis C virus mRNA, which is cap- and eIF4G-independent. Paip2 decreases the affinity of PABP for polyadenylate RNA, and disrupts the repeating structure of poly(A) ribonucleoprotein. Furthermore, Paip2 competes with Paip1 for PABP binding. Thus, Paip2 inhibits translation by interdicting PABP function.     

Decoying the cap- mRNA degradation system by a double-stranded RNA virus and poly(A)- mRNA surveillance by a yeast antiviral system.

The major coat protein of the L-A double-stranded RNA virus of Saccharomyces cerevisiae covalently binds m7 GMP from 5' capped mRNAs in vitro. We show that this cap binding also occurs in vivo and that, while this activity is required for expression of viral information (killer toxin mRNA level and toxin production) in a wild-type strain, this requirement is suppressed by deletion of SKI1/XRN1/SEP1. We propose that the virus creates decapped cellular mRNAs to decoy the 5'-->3' exoribonuclease specific for cap- RNA encoded by XRN1. The SKI2 antiviral gene represses the copy numbers of the L-A and L-BC viruses and the 20S RNA replicon, apparently by specifically blocking translation of viral RNA. We show that SKI2, SKI3, and SKI8 inhibit translation of electroporated luciferase and beta-glucuronidase mRNAs in vivo, but only if they lack the 3' poly(A) structure. Thus, L-A decoys the SKI1/XRN1/SEP1 exonuclease directed at 5' uncapped ends, but translation of the L-A poly(A)- mRNA is repressed by Ski2,3,8p. The SKI2-SKI3-SKI8 system is more effective against cap+ poly(A)- mRNA, suggesting a (nonessential) role in blocking translation of fragmented cellular mRNAs.