Use of Chemically Modified Nucleotides to Determine a 62-Nucleotide RNA Crystal Structure: A Survey of Phosphorothioates,Br, Pt and Hg

Abstract

Two important challenges confronting RNA crystallographers are producing crystals and finding isomorphous heavy-atom derivatives. Non-isomorphism can be addressed by determining the phases using the multiwavelength anomalous dispersion (MAD) method. These phases can be greatly improved by combining phases from MAD experiments done on different heavy-atom derivatives. Heavy-atom derivatives can be created by chemically modifying the RNA through covalent attachment of bromine or mercury to C5 of pyrimidines or [Pt(NH₃)₃]²⁺ to N7 of guanine. While phosphorothioates can provide mercury binding sites, disorder can reduce their value for phase determination. The location of these chemical modifications is critical since crystallization of these derivatized RNAs is sensitive to heavy atom induced conformational alterations and crystal packing.     

Biochemical detection of monovalent metal ion binding sites within RNA

Many RNAs, including the ribosome, RNase P, and the group II intron, explicitly require monovalent cations for activity in vitro. Although the necessity of monovalent cations for RNA function has been known for more than a quarter of a century, the characterization of specific monovalent metal sites within large RNAs has been elusive. Here we describe a biochemical approach to identify functionally important monovalent cations in nucleic acids. This method uses thallium (Tl+), a soft Lewis acid heavy metal cation with chemical properties similar to those of the physiological alkaline earth metal potassium (K+). Nucleotide analog interference mapping (NAIM) with the sulfur-substituted nucleotide 6-thioguanosine in combination with selective metal rescue of the interference with Tl+ provides a distinct biochemical signature for monovalent metal ion binding. This approach has identified a K+ binding site within the P4-P6 domain of the Tetrahymena group I intron that is also present within the X-ray crystal structure. The technique also predicted a similar binding site within the Azoarcus group I intron where the structure is not known. The approach is applicable to any RNA molecule that can be transcribed in vitro and whose function can be assayed.     

Facile syntheses of BODIPY derivatives for fluorescent labeling of the 3' and 5' ends of RNAs

As inexpensive and readily available fluorophores for 3′ and 5′ end labeling of RNA molecules, symmetrical BODIPY (boron dipyrromethene: 4,4-difluoro-4-bora-3a,4a-diaza-s-indacene) derivatives having a primary amino group were designed, and their facile synthetic route was established. Novel BODIPY derivatives exhibited photophysical properties comparable to commercially available BODIPY FL EDA (4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-propionyl ethylenediamine). To confirm utility of new derivatives, specific labeling of the 3′ and 5′ ends of in vitro transcribed RNAs was carried out. Furthermore, the 3′ end of the 5′ fragment of the bimolecular Tetrahymena ribozyme was labeled, and its catalytic activity was investigated.     

Analysis of the CYT-18 Protein Binding Site at the Junction of Stacked Helices in a Group I Intron RNA by Quantitative Binding Assays andin vitroSelection

TheNeurospora crassamitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing group I introns by promoting the formation of the catalytically active structure of the intron RNA. Previous studies showed that CYT-18 binds with high affinity to the P4-P6 domain of the catalytic core and that there is some additional contribution to binding from the P3-P9 domain. Here, quantitative binding assays with deletion derivatives of theN. crassamitochondrial large rRNA intron showed that at least 70% of the binding energy can be accounted for by the interaction of CYT-18 with the P4-P6 domain. Within this domain, P4 and P6 are required for high affinity CYT-18 binding, while the distal elements P5 and P6a may contribute indirectly by stabilizing the correct structure of the binding site in P4 and P6. CYT-18 binds to a small RNA corresponding to the isolated P4-P6 domain, but not to a permuted version of this RNA in which P4-P6 is a continuous rather than a stacked helix. Iterativein vitroselection experiments with the isolated P4-P6 domain showed a requirement for base-pairing to maintain helices P4, P6 and P6a, but indicate that P5 is subject to fewer constraints. The most strongly conserved nucleotides in the selections were clustered around the junction of the P4-P6 stacked helix, with ten nucleotides (J3/4-2,3, P4 bp -1 and 3, and P6 bp -1 and 2) found invariant in the context of the wild-type RNA structure.In vitromutagenesis confirmed that replacement of the wild-type nucleotides at J3/4-2 and 3 or P4 bp-3 markedly decreased CYT-18 binding, reflecting either base specific contacts or indirect readout of RNA structure by the protein. Our results suggest that a major function of CYT-18 is to promote assembly of the P4-P6 domain by stabilizing the correct geometry at the junction of the P4-P6 stacked helix. The relatively large number of conserved nucleotides at the binding site suggests that the interaction of CYT-18 with group I introns is unlikely to have arisen by chance and could reflect either an evolutionary relationship between group I introns and tRNAs or interaction with a common stacked-helical structural motif that evolved separately in these RNAs.     

An RNA internal loop acts as a hinge to facilitate ribozyme folding and catalysis.

RNA molecules commonly consist of helical regions separated by internal loops, and in many cases these internal loops have been found to assume stable structures. We have examined the function and dynamics of an internal loop, J5/5a, that joins the two halves of the P4-P6 domain of the Tetrahymena self-splicing group I intron. P4-P6 RNAs with mutations in the J5/5a region showed nondenaturing gel electrophoretic mobilities and levels of Fe(II)-EDTA cleavage protection intermediate between those of wild-type RNA and a mutant incapable of folding into the native P4-P6 tertiary structure. Mutants with the least structured J5/5a loops behaved the most like wild-type P4-P6, and required smaller amounts of Mg2+ to rescue folding. The activity of reconstituted introns containing mutant P4-P6 RNAs correlated similarly with the nature of the J5/5a mutation. Our results suggest that, in solution, the P4-P6 RNA is in a two-state equilibrium between folded and unfolded states. We conclude that this internal loop mainly acts as a flexible hinge, allowing the coaxially stacked helical regions on either side of it to interact via specific tertiary contacts. To a lesser extent, the specific bases within the loop contribute to folding. Furthermore, it is crucial that the junction remain unstructured in the unfolded state. These conclusions cannot be derived from a simple examination of the P4-P6 crystal structure (Cate JH et al., 1996, Science 273:1678-1685), showing once again that structure determination must be supplemented with mutational and thermodynamic analysis to provide a complete picture of a folded macromolecule.     

Genes for two small cytoplasmic Ro RNAs are adjacent and appear to be single-copy in the human genome

Anti-Ro autoantibodies precipitate several small cytoplasmic ribonucleoproteins from mammalian cells. The RNA components of these particles, designated hY1-hY5 in human cells and mY1 and mY2 in mouse cells, are about 100 nucleotides long. We have analyzed a genomic clone that appears to contain true RNA-coding regions for two of the human Ro RNAs, hY1 and hY3. These RNAs exhibit many sequence and secondary structure homologies, both with each other and with the recently sequenced hY5 RNA. The hY2 RNA is a slightly truncated form of hY1; several shorter versions of hY3 are also detected in cell extracts and immunoprecipitates. The human hY1 and hY3 genes cross-hybridize with the mouse Ro RNAs, mY1 and mY2, respectively; we show that the mouse Ro RNAs are exclusively contained in Ro particles. The genes for hY1 and hY3 are transcribed in vitro by RNA polymerase III. In contrast with all other mammalian class III genes described, they appear to be present as single copies in the human genome.     

Two major tertiary folding transitions of the Tetrahymena catalytic RNA.

The L-21 Tetrahymena ribozyme, an RNA molecule with sequence-specific endoribonuclease activity derived from a self-splicing group I intron, provides a model system for studying the RNA folding problem. A 160 nucleotide, independently folding domain of tertiary structure (the P4-P6 domain) comprises about half of the ribozyme. We now apply Fe(II)-EDTA cleavage to mutants of the ribozyme to explore the role of individual structural elements in tertiary folding of the RNA at equilibrium. Deletion of peripheral elements near the 3' end of the ribozyme destabilizes a region of the catalytic core (P3-P7) without altering the folding of the P4-P6 domain. Three different mutations within the P4-P6 domain that destabilize its folding also shift the folding of the P3-P7 region of the catalytic core to higher MgCl2 concentrations. We conclude that the role of the extended P4-P6 domain and of the 3'-terminal peripheral elements is at least in part to stabilize the catalytic core. The organization of RNA into independently folding domains of tertiary structure may be common in large RNAs, including ribosomal RNAs. Furthermore, the observation of domain-domain interactions in a catalytic RNA supports the feasibility of a primitive spliceosome without any proteins.     

Removal of covalent heterogeneity reveals simple folding behavior for P4-P6 RNA

RNA folding landscapes have been described alternately as simple and as complex. The limited diversity of RNA residues and the ability of RNA to form stable secondary structures prior to adoption of a tertiary structure would appear to simplify folding relative to proteins. Nevertheless, there is considerable evidence for long-lived misfolded RNA states, and these observations have suggested rugged energy landscapes. Recently, single molecule fluorescence resonance energy transfer (smFRET) studies have exposed heterogeneity in many RNAs, consistent with deeply furrowed rugged landscapes. We turned to an RNA of intermediate complexity, the P4-P6 domain from the Tetrahymena group I intron, to address basic questions in RNA folding. P4-P6 exhibited long-lived heterogeneity in smFRET experiments, but the inability to observe exchange in the behavior of individual molecules led us to probe whether there was a non-conformational origin to this heterogeneity. We determined that routine protocols in RNA preparation and purification, including UV shadowing and heat annealing, cause covalent modifications that alter folding behavior. By taking measures to avoid these treatments and by purifying away damaged P4-P6 molecules, we obtained a population of P4-P6 that gave near-uniform behavior in single molecule studies. Thus, the folding landscape of P4-P6 lacks multiple deep furrows that would trap different P4-P6 molecules in different conformations and contrasts with the molecular heterogeneity that has been seen in many smFRET studies of structured RNAs. The simplicity of P4-P6 allowed us to reliably determine the thermodynamic and kinetic effects of metal ions on folding and to now begin to build more detailed models for RNA folding behavior.     

戊型肝炎病毒亚基因组RNA的研究

本文利用同位素代谢标记在HEV感染85～10.5,6.5～7.5h分别检测到1及2个亚基因组RNA,而感染21h后及在成熟的病毒颗粒内未能检测到亚基因组RNA。通过杂交实验,发现HEV的亚基因组RNA具有典型的共3′端的半套式结构,且基因组RNA与亚基因组RNA的5′端不存在共同的引导序列。通过紫外转录图谱发现HEV的亚基因组RNA是通过独立转录的方式产生的。利用引物延伸反应发现两种亚基因组RNA的转录起始位点分别位于RNA聚合酶区及非结构区、结构区的基因间序列。     

Biotin and fluorescent labeling of RNA using T4 RNA ligase.

Biotin, fluorescein, and tetramethylrhodamine derivatives of P1-(6-aminohex-1-yl)-P2-(5'-adenosine) pyrophosphate were synthesized and used as substrates with T4 RNA ligase. In the absence of ATP, the non-adenylyl portion of these substrates is transferred to the 3'-hydroxyl of an RNA acceptor to form a phosphodiester bond and the AMP portion is released. E. coli and D. melanogaster 5S RNA, yeast tRNAPhe, (Ap)3C, and (Ap)3A serve as acceptors with yields of products varying from 50 to 100%. Biotin-labeled oligonucleotides are bound selectively and quantitatively to avidin-agarose and may be eluted with 6 M guanidine hydrochloride, pH 2.5. Fluorescein and tetramethylrhodamine-labeled oligonucleotides are highly fluorescent and show no quenching due to attachment to the acceptor. The diverse structures of the appended groups and of the chain lengths and compositions of the acceptor RNAs show that T4 RNA ligase will be a useful modification reagent for the addition of various functional groups to the 3'-terminus of RNA molecules.     

In vitro selection of RNAs with increased tertiary structure stability.

An in vitro selection system was devised to select RNAs based on their tertiary structural stability, independent of RNA activity. Selection studies were conducted on the P4-P6 domain from the Tetrahymena thermophila group I intron, an autonomous self-folding unit that contains several important tertiary folding motifs including the tetraloop receptor and the A-rich bulge. Partially randomized P4-P6 molecules were selected based on their ability to fold into compact structures using native gel electrophoresis in the presence of decreasing concentrations of MgCl2. After 10 rounds of the selection process, a number of sequence alterations were identified that stabilized the P4-P6 RNA. One of these, a single base deletion of C209 within the P4 helix, significantly stabilized the P4-P6 molecule and would not have been identified by an activity-based selection because of its essential role for ribozyme function. Additionally, the sequence analysis provided evidence that stabilization of secondary structure may contribute to overall tertiary stability for RNAs. This system for probing RNA structure irrespective of RNA activity allows analysis of RNA structure/function relationships by identifying nucleotides or motifs important for folding and then comparing them with RNA sequences required for function.     

Nucleotide sequence of 5S RNA ofMycobacterium smegmatis

³²P labelled 5S RNA isolated fromMycobacterium smegmatis was digested withT ₁ and pancreatic ribonucleases separately and fingerprinted by two dimensional high voltage electrophoresis on thin-layer DEAE-cellulose plates. The radioactive spots were sequenced and their molar yields were determined. The chain length of the 5S RNA was found to be 120. It showed resemblances to both prokaryotic and eukaryotic 5S RNAs.     

A new strategy for introducing photoactivatable 4-thiouridine ((4S)U) into specific positions in a long RNA molecule.

We describe a new protocol, which does not require (4S)UpG, for introducing (4S)U into specific sites in a pre-mRNA substrate. A 5'-half and a full-length RNA are first synthesized by phage RNA polymerase. p(4S)Up, which is derived from (4S)UpU and can therefore be 32P-labeled, is then ligated to the 3' end of the 5'-half RNA with T4 RNA ligase. The 3' phosphate of the ligated product is removed subsequently by CIP (calf intestinal alkaline phosphatase) to produce a 3'-OH group. The 3'-half RNA with a 5' phosphate is produced by site-specific RNase H cleavage of the full-length pre-mRNA directed by a 2'-O-methyl RNA-DNA chimera. The two half RNAs are then aligned with a bridging oligonucleotide and ligated with T4 DNA ligase. Our results show that 32P-p(4S)Up ligation to the 3' end of the 5'-half RNA is comparable to 32P-pCp ligation. Also, the efficiency of the bridging oligonucleotide-mediated two-piece ligation is quite high, approximately 30-50%. This strategy has been applied to the P120 pre-mRNA containing an AT-AC intron, but should be applicable to many other RNAs.     

A selective temperature-sensitive defect in viral RNA expression in cells infected with a ts transformation mutant of murine sarcoma virus

We investigated the nature of the defect in the temperature-sensitive mutant of Moloney murine sarcoma virus (Mo-MuSV), termed ts110. This mutant has a temperature-sensitive defect in a function required for maintenance of the transformed state. A nonproducer cell clone, 6m2, infected with ts110 expresses P85 and P58 at 33°C, the transformed temperature, but only P58 is detected at the restrictive temperature of 39°C. Shift-up (33°C → 39°C) and in vitro experiments have established that P85 is not thermolabile for immunoprecipitation. Previous temperature-shift experiments (39°C → 33°C) have shown that P85 synthesis resumes after a 2–3 hr lag period. Temperature shifts (39°C → 33°C) performed in the presence of actinomycin D prevented the synthesis of P85, whereas P58 synthesis did not decline for 5 hr, suggesting that P58 and P85 are translated from different mRNAs. The shift-up experiments also indicated that, once made, the RNA coding for P85 can function at the restrictive temperature for several hours. MuSV-ts110-infected cells superinfected with Mo-MuLV produced a ts110 MuSV-MuLV mixture. Sucrose gradient analysis of virus subunit RNAs revealed a ～28S and a ～35S peak. Electrophoresis of the ～28S poly(A)-containing RNA from ts110 virus in methyl mercuric hydroxide gels resolved two RNAs with estimated sizes of 1.9 × 10⁶ and 1.6 × 10⁶ daltons, both smaller than the wild type MuSV-349 genomic RNA (2.2 × 10⁶ daltons). RNA in the ～28S size class from virus preparations harvested at 33°C was found to translate from P85 and P58, whereas, the ～35S RNA yielded helper virus Pr63^gag. In contrast, virus harvested at 39°C was deficient in P85 coding RNA only. Peptide mapping experiments indicate that P85 contains P23 sequences, a candidate Moloney mouse sarcoma virus src gene product. Taken together, these results suggest that two virus-specific RNAs are present in ts 110-infected 6m2 cells and rescued ts110 pseudotype virions at 33°C, one coding for P85, whose expression can be interfered with by shifting the culture to 39°C; the other coding for P58, whose expression is unaffected by temperature shifts. P85 is a candidate gag-src fusion protein, while P58 contains gag sequences only.