The cleavage specificity of RNase III.

We determined sites in lambda cII mRNA that are cleaved by RNase III in the presence of lambda OOP antisense RNA, using a series of OOP RNAs with different internal deletions. In OOP RNA-cII mRNA structures containing a potential region of continuous double-stranded RNA bounded by a non-complementary unpaired region, RNase III cleaved the cII mRNA at one or more preferred sites located 10 to 14 bases from the 3'-end of the region of continuous complementarity. Cleavage patterns were almost identical when the presumptive structure was the same continuously double-stranded region followed by a single-stranded bulge and a second short region of base pairing. The sequences of the new cleavage sites show generally good agreement with a consensus sequence derived from thirty-five previously determined cleavage sequences. In contrast, four 'non-sites' at which cleavage is never observed show poor agreement with this consensus sequence. We conclude that RNase III specificity is determined both by the distance from the end of continuous pairing and by nucleotide sequence features within the region of pairing.     

Template requirement and initiation site selection by hepatitis C virus polymerase on a minimal viral RNA template

RNA-dependent RNA polymerase, NS5B protein, catalyzes replication of viral genomic RNA, which presumably initiates from the 3'-end. We have previously shown that NS5B can utilize the 3'-end 98-nucleotide (nt) X region of the hepatitis C virus (HCV) genome as a minimal authentic template. In this study, we used this RNA to characterize the mechanism of RNA synthesis by the recombinant NS5B. We first showed that NS5B formed a complex with the 3'-end of HCV RNA by binding to both the poly(U-U/C)-rich and X regions of the 3'-untranslated region as well as part of the NS5B-coding sequences. Within the X region, NS5B bound stem II and the single-stranded region connecting stem-loops I and II. Truncation of 40 nt or more from the 3'-end of the X region abolished its template activity, whereas X RNA lacking 35 nt or less from the 3'-end retained template activity, consistent with the NS5B-binding site mapped. Furthermore, NS5B initiated RNA synthesis from a specific site within the single-stranded loop I. All of the RNA templates that have a double-stranded stem at the 3'-end had the same RNA initiation site. However, the addition of single-stranded nucleotides to the 3'-end of X RNA or removal of double-stranded structure in stem I generated RNA products of template size. These results indicate that HCV NS5B initiates RNA synthesis from a single-stranded region closest to the 3'-end of the X region. These results have implications for the mechanism of HCV RNA replication and the nature of HCV RNA templates in the infected cells.     

Requirements for kissing-loop-mediated dimerization of human immunodeficiency virus RNA.

Sequences from the 5' end of type 1 human immunodeficiency virus RNA dimerize spontaneously in vitro in a reaction thought to mimic the initial step of genomic dimerization in vivo. Dimer initiation has been proposed to occur through a "kissing-loop" interaction involving a specific RNA stem-loop element designated SL1: the RNA strands first interact by base pairing through a six-base GC-rich palindrome in the loop of SL1, whose stems then isomerize to form a longer interstrand duplex. We now report a mutational analysis aimed at defining the features of SL1 RNA sequence and secondary structure required for in vitro dimer formation. Our results confirm that mutations which destroy complementarity in the SL1 loop abolish homodimer formation, but that certain complementary loop mutants can heterodimerize. However, complementarity was not sufficient to ensure dimerization, even between GC-rich loops, implying that specific loop sequences may be needed to maintain a conformation that is competent for initial dimer contact; the central GC pair of the loop palindrome appeared critical in this regard, as did two or three A residues which normally flank the palindrome. Neither the four-base bulge normally found in the SL1 stem nor the specific sequence of the stem itself was essential for the interaction; however, the stem structure was required, because interstrand complementarity alone did not support dimer formation. Electron microscopic analysis indicated that the RNA dimers formed in vitro morphologically resembled those isolated previously from retroviral particles. These results fully support the kissing-loop model and may provide a framework for systematically manipulating genomic dimerization in type 1 human immunodeficiency virus virions.     

Physical properties of the complementary T4 RNA

The complementary transcribed T4 RNA after self-annealing and RNAase treatment was isolated by gel chromatography and then used for further studies. From salt-dependent RNAase resistance and melting studies it is evident that this RNA represents a genuine double-stranded structure. The base content of the isolated double-stranded RNA was found to be the same as total T4 mRNA. Sucrose gradient analysis and hydroxyapatite chromatography of T4 RNA, annealed early and late RNA, and of the isolated double-stranded RNA, gave results indicating that the complementary RNA is part of a RNA molecule and further that the size of the complementary regions are independent of the RNA molecules. Partial digestion of pulse-labelled late RNA with phosphodiesterase I prior to annealing with unlabelled early RNA, showed that the complementary regions on the mRNA are not located to the 5'- or 3'-end but randomly distributed along the T4 RNA molecules.     

In vitro analysis of the interaction between the FinO protein and FinP antisense RNA of F-like conjugative plasmids

The FinO protein regulates the transfer potential of F-like conjugative plasmids through its interaction with FinP antisense RNA and its target, traJ mRNA. FinO binds to and protects FinP from degradation and promotes duplex formation between FinP and traJ mRNA in vitro. The FinP secondary structure consists of two stem-loop domains separated by a 4-base spacer and terminated by a 6-base tail. Previous studies suggested FinO bound to the smooth 14-base pair helix of stem-loop II. In this investigation, RNA mobility shift analysis was used to study the interaction between a glutathione S-transferase (GST)-FinO fusion protein and a series of synthetic FinP and traJ mRNA variants. Mutations in 16 of the 28 bases in stem II of FinP that are predicted to disrupt base pairing did not significantly alter the GST-FinO binding affinity. Removal of the single-stranded regions on either side of stem-loop II led to a dramatic decrease in GST-FinO binding to FinP and to the complementary region of the traJ mRNA leader. While no evidence for sequence-specific contacts was found, the results suggest that FinO recognizes the overall shape of the RNA and is influenced by the length of the single-stranded regions flanking the stem-loop.     

Selective binding by the RNA binding domain of PKR revealed by affinity cleavage

The RNA-dependent protein kinase (PKR) is regulated by the binding of double-stranded RNA (dsRNA) or single-stranded RNAs with extensive duplex secondary structure. PKR has an RNA binding domain (RBD) composed of two copies of the dsRNA binding motif (dsRBM). The dsRBM is an alpha-beta-beta-beta-alpha structure present in a number of proteins that bind RNA, and the selectivity demonstrated by these proteins is currently not well understood. We have used affinity cleavage to study the binding of PKR's RBD to RNA. In this study, we site-specifically modified the first dsRBM of PKR's RBD at two different amino acid positions with the hydroxyl radical generator EDTA.Fe. Cleavage by these proteins of a synthetic stem-loop ligand of PKR indicates that PKR's dsRBMI binds the RNA in a preferred orientation, placing the loop between strands beta1 and beta2 near the single-stranded RNA loop. Additional cleavage experiments demonstrated that defects in the RNA stem, such as an A bulge and two GA mismatches, do not dictate dsRBMI's binding orientation preference. Cleavage of VA(I) RNA, an adenoviral RNA inhibitor of PKR, indicates that dsRBMI is bound near the loop of the apical stem of this RNA in the same orientation as observed with the synthetic stem-loop RNA ligands. This work, along with an NMR study of the binding of a dsRBM derived from the Drosophila protein Staufen, indicates that dsRBMs can bind stem-loop RNAs in distinct ways. In addition, the successful application of the affinity cleavage technique to localizing dsRBMI of PKR on stem-loop RNAs and defining its orientation suggests this approach could be applied to dsRBMs found in other proteins.     

Mutagenesis of the iron-regulatory element further defines a role for RNA secondary structure in the regulation of ferritin and transferrin receptor expression.

Within the 5'-untranslated region of ferritin mRNAs, there is a conserved region of 28 nucleotides (nt) (the iron regulatory element (IRE)) that binds a protein (the IRE-binding protein (IRE-BP)) involved in the iron regulation of ferritin mRNA translation. We have examined the role of RNA secondary structure on the interaction of the IRE with the IRE-BP. First, the rat light ferritin IRE possesses a structure similar to that of the bullfrog heavy ferritin IRE (Wang, Y.-H., Sczekan, S. R., and Theil, E. C. (1990) Nucleic Acids Res. 18, 4463-4468). This includes an extended stem, interrupted at various points by bulge nucleotides and a 6-nt single-stranded loop (CAGUGU) at its top. Computer predictions and mapping results suggest the presence of a 3-nt (UGC) bulge 5 bases 5' of the loop in the rat IRE. Second, disruption of the base pairing in the upper stem alters IRE secondary structure and reduces the affinity with which the IRE-BP binds the IRE. Third, increasing the size of the loop or the distance between the UGC bulge and the loop reduces the IRE/IRE-BP interaction. Our results indicate that several aspects of IRE secondary structure are important for its high affinity binding to the IRE-BP.     

Primary structure of yeast mitochondrial DNA-coded phenylalanine-tRNA.

Mitochondrial tRNAPhe from Saccharomyces cerevisiae isolated by two-dimensional gel electrophoresis was sequenced by fingerprinting uniformly labeled 32 P-tRNA as well as by 5'-end postlabeling techniques. Its sequence was found to be: pG-C-U-U-U-U-A-U-A-G-C-U-U-A-G-D-G-G-D-A-A-A-G-C-m22G-A-U-A-A-A-phi-U-G-A-A-m1G-A-phi-U-U-A-U-U-U-A-C-A-U-G-U-A-G-U-phi-C-G-A-U-U-C-U-C-A-U-U-A-A-G-G-G-C-A-C-C-A. The secondary structure we propose, in order to maximize base pairing in the phiC stem and to allow tertiary interaction between G15 and C46, excludes U50 from base pairing giving a bulge in the phiC stem. No conclusion can be drawn concerning the endosymbiotic theory of mitochondria evolution by comparing the primary structure of mt. tRNAPhe with other sequenced tRNAsPhe. This mt.tRNAPhe lacks some of the structural elements reported to be involved in the yeast cytoplasmic phenylalanyl-tRNA ligase recognition site and cannot be aminoacylated by purified yeast cytoplasmic phenylalanyl-tRNA ligase.     

Predicted structures of apolipoprotein II mRNA constrained by nuclease and dimethyl sulfate reactivity: stable secondary structures occur predominantly in local domains via intraexonic base pairing

Analyses of apolipoprotein II mRNA with chemical and enzymatic probes showed that double- and single-stranded regions were distributed uniformly along the mRNA except for a large (72 nucleotides) single-stranded region containing the translation stop codon. Secondary structure models constrained by the experimental data were made by varying the distance (along the mRNA) over which base pairing was allowed. Four prominent secondary structures were seen with restrictions of 165, 330, or 659 nucleotides suggesting that such structures from via local interactions over distances of 50-120 nucleotides. Predicted long range interactions involve only 2-3 base pairs while local interactions involve helices of 4-10 base pairs. Predicted helices of greater than or equal to 4 base pairs occur primarily within exons, raising the possibility that prominent secondary structures in mRNAs may be largely due to intraexonic base pairing. Tests of single- and double-stranded domains by oligonucleotide-directed RNase H cleavage and primer extension were in accord with the structure model and with nuclease and chemical modification data. The model predicting base pairing between the coding and the 3' noncoding regions was tested by RNase H cleavage followed by oligo(dT)-cellulose chromatography to separate 5' and 3' mRNA fragments. Most (82%) of the 5' fragment remained associated with the 3' noncoding region in a structure with a tm = 50 degrees C in 0.2 M Na+ suggesting that this stem could be stable in vivo. This stem may be stable in the isolated mRNA, but would likely occur transiently in polyribosomal apolipoprotein II mRNA due to ribosome transit through the 5' side of the stem. Alternate structures may occur in this region during ribosome transit and play a role in translation termination or in determining the susceptibility of the mRNA to degradation.     

Use of circular permutation to assess six bulges and four loops of DNA-packaging pRNA of bacteriophage phi29.

A 120-base phage phi29 encoded RNA (pRNA) has a novel role in DNA packaging. This pRNA possesses five single-base bulges, one three-base bulge, one bifurcation bulge, one bulge loop, and two stem loops. Circularly permuted pRNAs (cpRNA) were constructed to examine the function of these bulges and loops as well as their adjacent sequences. Each of the five single-base bulges was nonessential. The bifurcation bulge could be deleted and replaced with a new opening to provide flexibility for maintaining an overall correct folding in three-way junction. All of these nonessential bulges or their adjacent bases could be used as new termini for cpRNAs. The three-base (C18C19A20) bulge was dispensable for procapsid binding, but was indispensable for DNA packaging. The secondary structure around this CCA bulge and the phylogenetically conserved bases within or around it were investigated. Bases A14C15U16 were confirmed, by compensatory modification, to pair with U103G102A101. A99 was needed only to allow the proper folding of CCA bulge in the appropriate sequence order and distance constraints. Beyond these, the seemingly phylogenetic conservation of other bases has little role in pRNA activity. Each of the three stem loops was essential for procapsid binding, DNA packaging, and phage assembly. Disruption of the middle of any one of the loops resulted in dramatic reductions in procapsid binding, subsequent DNA packaging, and phage assembly activities. However, disruption of the loops at sequences that were close to double-stranded regions of the RNA did not interfere with pRNA activity significantly. Our results suggest that double-stranded helical regions near these loops were most likely not involved in interactions with components of the DNA-packaging machinery. Instead, these regions appear to be merely present to serve as a scaffolding to display the single-stranded loops that are important for pRNA tertiary structure or for interaction with the procapsid or other packaging components.     

Solution structure of a five-adenine bulge loop within a DNA duplex.

The three-dimensional solution structure of a DNA molecule of the sequence 5'-d(GCATCGAAAAAGCTACG)-3' paired with 5'-d(CGTAGCCGATGC)-3' containing a five-adenine bulge loop (dA(5)-bulge) between two double helical stems was determined by 2D (1)H and (31)P NMR, infrared, and Raman spectroscopy. The DNA in both stems adopt a classical B-form double helical structure with Watson-Crick base pairing and C2'-endo sugar conformation. In addition, the two dG/dC base pairs framing the dA(5)-bulge loop are formed and are stable at least up to 30 degrees C. The five adenine bases of the bulge loop are localized at intrahelical positions within the double helical stems. Stacking on the double helical stem is continued for the first four 5'-adenines in the bulge loop. The total rise (the height) of these four stacked adenines roughly equals the diameter of the double helical stem. The stacking interactions are broken between the last of these four 5'-adenines and the fifth loop adenine at the 3'-end. This 3'-adenine partially stacks on the other stem. The angle between the base planes of the two nonstacking adenines (A10 and A11) in the bulge loop reflects the kinking angle of the global DNA structure. The neighboring cytosines opposite the dA(5)-bulge (being parts of the bulge flanking base pairs) do not stack on one another. This disruption of stacking is characterized by a partial shearing of these bases, such that certain sequential NOEs for this base step are preserved. In the base step opposite the loop, an extraordinary hydrogen bond is observed between the phosphate backbone of the 5'-dC and the amino proton of the 3'-dC in about two-thirds of the conformers. This hydrogen bond probably contributes to stabilizing the global DNA structure. The dA(5)-bulge induces a local kink into the DNA molecule of about 73 degrees (+/-11 degrees ). This kinking angle and the mutual orientation of the two double helical stems agree well with results from fluorescence resonance energy transfer measurements of single- and double-bulge DNA molecules.     

Conserved nucleotides in the TAR RNA stem of human immunodeficiency virus type 1 are critical for Tat binding and trans activation: model for TAR RNA tertiary structure.

Interaction between the human immunodeficiency virus type 1 (HIV-1) trans-activator Tat and its cis-acting responsive RNA element TAR is necessary for activation of HIV-1 gene expression. We investigated the hypothesis that the essential uridine residue at position 23 in the bulge of TAR RNA is involved in intramolecular hydrogen bonding to stabilize an unique RNA structure required for recognition by Tat. Nucleotide substitutions in the two base pairs of the TAR stem directly above the essential trinucleotide bulge that maintain base pairing but change sequence prevent complex formation with Tat in vitro. Corresponding mutations tested in a trans-activation assay strongly affect the biological activity of TAR in vivo, suggesting an important role for these nucleotides in the Tat-TAR interaction. On the basis of these data, a model is proposed which implicates uridine 23 in a stable tertiary interaction with the GC pair directly above the bulge. This interaction would cause widening of the major groove of the RNA, thereby exposing its hydrogen-bonding surfaces for possible interaction with Tat. The model also predicts a gap between uridine 23 and the first base pair in the stem above, which would require one or more unpaired nucleotides to close, but does not predict any other role for such nucleotides. In accordance with this prediction, synthetic propyl phosphate linkers of equivalent length to 1 or 2 nucleotides, were found to be fully acceptable substitutes in the bulge above uridine 23, demonstrating that neither the bases nor the ribose moieties at these positions are implicated in the recognition of TAR RNA by Tat.