Modifications of the 3'-UTR stem-loop of infectious bursal disease virus are allowed without influencing replication or virulence

Many questions regarding the initiation of replication and translation of the segmented, double-stranded RNA genome of infectious bursal disease virus (IBDV) remain to be solved. Computer analysis shows that the non-polyadenylated extreme 3′-untranslated regions (UTRs) of the coding strand of both genomic segments are able to fold into a single stem–loop structure. To assess the determinants for a functional 3′-UTR, we mutagenized the 3′-UTR stem–loop structure of the B-segment. Rescue of infectious virus from mutagenized cDNA plasmids was impaired in all cases. However, after one passage, the replication kinetics of these viruses were restored. Sequence analysis revealed that additional mutations had been acquired in most of the stem–loop structures, which compensated the introduced ones. A rescued virus with a modified stem–loop structure containing four nucleotide substitutions, but preserving its overall secondary structure, was phenotypically indistinguishable from wild-type virus, both in vitro (cell culture) and in vivo (chickens, natural host). Sequence analysis showed that the modified stem–loop structure of this virus was fully preserved after four serial passages. Apparently, it is the stem–loop structure and not the primary sequence that is the functional determinant in the 3′-UTRs of IBDV.     

Bacillus subtilis RNase J1 endonuclease and 5′ exonuclease activities in the turnover of ΔermC mRNA

RNase J1, a ribonuclease with 5′ exonuclease and endonuclease activities, is an important factor in Bacillus subtilis mRNA decay. A model for RNase J1 endonuclease activity in mRNA turnover has RNase J1 binding to the 5′ end and tracking to a target site downstream, where it makes a decay-initiating cleavage. The upstream fragment from this cleavage is degraded by 3′ exonucleases; the downstream fragment is degraded by RNase J1 5′ exonuclease activity. Previously, ΔermC mRNA was used to show 5′-end dependence of mRNA turnover. Here we used ΔermC mRNA to probe RNase J1-dependent degradation, and the results were consistent with aspects of the model. ΔermC mRNA showed increased stability in a mutant strain that contained a reduced level of RNase J1. In agreement with the tracking concept, insertion of a strong stem–loop structure at +65 resulted in increased stability. Weakening this stem–loop structure resulted in reversion to wild-type stability. RNA fragments containing the 3′ end were detected in a strain with reduced RNase J1 expression, but were undetectable in the wild type. The 5′ ends of these fragments mapped to the upstream side of predicted stem–loop structures, consistent with an impediment to RNase J1 5′ exonuclease processivity. A ΔermC mRNA deletion analysis suggested that decay-initiating endonuclease cleavage could occur at several sites near the 3′ end. However, even in the absence of these sites, stability was further increased in a strain with reduced RNase J1, suggesting alternate pathways for decay that could include exonucleolytic decay from the 5′ end.     

Genome 3'-end repair in dengue virus type 2

Genomes of RNA viruses encounter a continual threat from host cellular ribonucleases. Therefore, viruses have evolved mechanisms to protect the integrity of their genomes. To study the mechanism of 3′-end repair in dengue virus-2 in mammalian cells, a series of 3′-end deletions in the genome were evaluated for virus replication by detection of viral antigen NS1 and by sequence analysis. Limited deletions did not cause any delay in the detection of NS1 within 5 d. However, deletions of 7–10 nucleotides caused a delay of 9 d in the detection of NS1. Sequence analysis of RNAs from recovered viruses showed that at early times, virus progenies evolved through RNA molecules of heterogeneous lengths and nucleotide sequences at the 3′ end, suggesting a possible role for terminal nucleotidyl transferase activity of the viral polymerase (NS5). However, this diversity gradually diminished and consensus sequences emerged. Template activities of 3′-end mutants in the synthesis of negative-strand RNA in vitro by purified NS5 correlate well with the abilities of mutant RNAs to repair and produce virus progenies. Using the Mfold program for RNA structure prediction, we show that if the 3′ stem–loop (3′ SL) structure was abrogated by mutations, viruses eventually restored the 3′ SL structure. Taken together, these results favor a two-step repair process: non-template-based nucleotide addition followed by evolutionary selection of 3′-end sequences based on the best-fit RNA structure that can support viral replication.     

Duplex Scorpion primers in SNP analysis and FRET applications

Scorpions are fluorogenic PCR primers with a probe element attached at the 5′-end via a PCR stopper. They are used in real-time amplicon-specific detection of PCR products in homogeneous solution. Two different formats are possible, the ‘stem–loop’ format and the ‘duplex’ format. In both cases the probing mechanism is intramolecular. We have shown that duplex Scorpions are efficient probes in real-time PCR. They give a greater fluorescent signal than stem–loop Scorpions due to the vastly increased separation between fluorophore and quencher in the active form. We have demonstrated their use in allelic discrimination at the W1282X locus of the ABCC7 gene and shown that they can be used in assays where fluorescence resonance energy transfer is required.     

Characterization of the E.coli poly(A) polymerase: nucleotide specificity, RNA-binding affinities and RNA structure dependence

Polyadenylation of RNA molecules in bacteria and chloroplasts has been implicated as part of the RNA degradation pathway. The polyadenylation reaction is performed in Escherichia coli mainly by the enzyme poly(A) polymerase I (PAP I). In order to understand the molecular mechanism of RNA polyadenylation in bacteria, we characterized the biochemical properties of this reaction in vitro using the purified enzyme. Unlike the PAP from yeast nucleus, which is specific for ATP, E.coli PAP I can use all four nucleotide triphosphates as substrates for addition of long ribohomopolymers to RNA. PAP I displays a high binding activity to poly(U), poly(C) and poly(A) ribohomopolymers, but not to poly(G). The 3′-ends of most of the mRNA molecules in bacteria are characterized by a stem–loop structure. We show here that in vitro PAP I activity is inhibited by a stem–loop structure. A tail of two to six nucleotides located 3′ to the stem–loop structure is sufficient to overcome this inhibition. These results suggest that the stem–loop structure located in most of the mRNA 3′-ends may function as an inhibitor of polyadenylation and degradation of the corresponding RNA molecule. However, RNA 3′-ends produced by endonucleolytic cleavage by RNase E in single-strand regions of mRNA molecules may serve as efficient substrates for polyadenylation that direct these molecules for rapid exonucleolytic degradation.     

Single nucleotide polymorphism detection by combinatorial fluorescence energy transfer tags and biotinylated dideoxynucleotides

Combinatorial fluorescence energy transfer (CFET) tags, constructed by exploiting energy transfer and combinatorial synthesis, allow multiple biological targets to be analyzed simultaneously. We here describe a multiplex single nucleotide polymorphism (SNP) assay based on single base extension (SBE) using CFET tags and biotinylated dideoxynucleotides (biotin-ddNTPs). A library of CFET-labeled oligonucleotide primers was mixed with biotin-ddNTPs, DNA polymerase and the DNA templates containing the SNPs in a single tube. The nucleotide at the 3′-end of each CFET-labeled oligonucleotide primer was complementary to a particular SNP in the template. Only the CFET-labeled primer that is fully complementary to the DNA template was extended by DNA polymerase with a biotin-ddNTP. We isolated the DNA extension fragments that carry a biotin at the 3′-end by capture with streptavidin-coated magnetic beads, while the unextended primers were eliminated. The biotinylated fluorescent DNA fragments were subsequently analyzed in a multicolor fluorescence electrophoresis system. The distinct fluorescence signature and electrophoretic mobility of each DNA extension product in the electropherogram coded the SNPs without the use of a sizing standard. We simultaneously distinguished six nucleotide variations in synthetic DNA templates and a PCR product from the retinoblastoma tumor suppressor gene. The use of CFET-labeled primers and biotin-ddNTPs coupled with the specificity of DNA polymerase in SBE offered a multiplex method for detecting SNPs.     

Binding of human SLBP on the 3'-UTR of histone precursor H4-12 mRNA induces structural rearrangements that enable U7 snRNA anchoring

In metazoans, cell-cycle-dependent histones are produced from poly(A)-lacking mRNAs. The 3′ end of histone mRNAs is formed by an endonucleolytic cleavage of longer precursors between a conserved stem–loop structure and a purine-rich histone downstream element (HDE). The cleavage requires at least two trans-acting factors: the stem–loop binding protein (SLBP), which binds to the stem–loop and the U7 snRNP, which anchors to histone pre-mRNAs by annealing to the HDE. Using RNA structure-probing techniques, we determined the secondary structure of the 3′-untranslated region (3′-UTR) of mouse histone pre-mRNAs H4–12, H1t and H2a–614. Surprisingly, the HDE is embedded in hairpin structures and is therefore not easily accessible for U7 snRNP anchoring. Probing of the 3′-UTR in complex with SLBP revealed structural rearrangements leading to an overall opening of the structure especially at the level of the HDE. Electrophoretic mobility shift assays demonstrated that the SLBP-induced opening of HDE actually facilitates U7 snRNA anchoring on the histone H4–12 pre-mRNAs 3′ end. These results suggest that initial binding of the SLBP functions in making the HDE more accessible for U7 snRNA anchoring.     

The conserved 3′X terminal domain of hepatitis C virus genomic RNA forms a two-stem structure that promotes viral RNA dimerization

The 3′X domain of hepatitis C virus is a strongly conserved structure located at the 3′ terminus of the viral genomic RNA. This domain modulates the replication and translation processes of the virus in conjunction with an upstream 5BSL3.2 stem–loop, and contains a palindromic sequence that facilitates RNA dimerization. Based on nuclear magnetic resonance spectroscopy and gel electrophoresis, we report here that domain 3′X adopts a structure composed of two stem–loops, and not three hairpins or a mixture of folds, as previously proposed. This structure exposes unpaired terminal nucleotides after a double-helical stem and palindromic bases in an apical loop, favoring genomic RNA replication and self-association. At higher ionic strength the domain forms homodimers comprising an intermolecular duplex of 110 nucleotides. The 3′X sequences can alternatively form heterodimers with 5BSL3.2. This contact, reported to favor translation, likely involves local melting of one of the 3′X stem–loops.     

Identification of antisense nucleic acid hybridization sites in mRNA molecules with self-quenching fluorescent reporter molecules

We describe a physical mRNA mapping strategy employing fluorescent self-quenching reporter molecules (SQRMs) that facilitates the identification of mRNA sequence accessible for hybridization with antisense nucleic acids in vitro and in vivo, real time. SQRMs are 20–30 base oligodeoxynucleotides with 5–6 bp complementary ends to which a 5′ fluorophore and 3′ quenching group are attached. Alone, the SQRM complementary ends form a stem that holds the fluorophore and quencher in contact. When the SQRM forms base pairs with its target, the structure separates the fluorophore from the quencher. This event can be reported by fluorescence emission when the fluorophore is excited. The stem–loop of the SQRM suggests that SQRM be made to target natural stem–loop structures formed during mRNA synthesis. The general utility of this method is demonstrated by SQRM identification of targetable sequence within c-myb and bcl-6 mRNA. Corresponding antisense oligonucleotides reduce these gene products in cells.     

The 5' stem-loop regulates expression of collagen alpha1(I) mRNA in mouse fibroblasts cultured in a three-dimensional matrix

The stability of collagen α1(I) mRNA is regulated by its 5′ stem–loop, which binds a cytoplasmic protein in a cap-dependent manner, and its 3′-untranslated region (UTR), which binds αCP. When cultured in a three-dimensional gel composed of type I collagen, mouse fibroblasts had decreased collagen α1(I) mRNA steady-state levels, which resulted from a decreased mRNA half-life. In cells cultured in gel, hybrid mouse–human collagen α1(I) mRNA with a wild-type 5′ stem–loop decayed faster than the same mRNA with a mutated stem–loop. When the 5′ stem–loop was placed in a heterologous mRNA, the mRNA accumulated to a lower level in cells grown in gel than in cells grown on plastic. This suggests that the 5′ stem–loop down-regulates collagen α1(I) mRNA. Protein binding to the 5′ stem–loop was reduced in cells grown in gel, which was associated with destabilization of the collagen α1(I) mRNA. In addition to the binding of a cytoplasmic protein, there was also a nuclear binding activity directed to the collagen α1(I) 5′ stem–loop. The nuclear binding was increased in cells grown in gel, suggesting that it may negatively regulate expression of collagen α1(I) mRNA. Binding of αCP, a protein involved in stabilization of collagen α1(I) mRNA, was unchanged by the culture conditions.     

Limited complementarity between U1 snRNA and a retroviral 5′ splice site permits its attenuation via RNA secondary structure

Multiple types of regulation are used by cells and viruses to control alternative splicing. In murine leukemia virus, accessibility of the 5′ splice site (ss) is regulated by an upstream region, which can fold into a complex RNA stem–loop structure. The underlying sequence of the structure itself is negligible, since most of it could be functionally replaced by a simple heterologous RNA stem–loop preserving the wild-type splicing pattern. Increasing the RNA duplex formation between U1 snRNA and the 5′ss by a compensatory mutation in position +6 led to enhanced splicing. Interestingly, this mutation affects splicing only in the context of the secondary structure, arguing for a dynamic interplay between structure and primary 5′ss sequence. The reduced 5′ss accessibility could also be counteracted by recruiting a splicing enhancer domain via a modified MS2 phage coat protein to a single binding site at the tip of the simple RNA stem–loop. The mechanism of 5′ss attenuation was revealed using hyperstable U1 snRNA mutants, showing that restricted U1 snRNP access is the cause of retroviral alternative splicing.     

A complex RNA motif defined by three discontinuous 5-nucleotide-long strands is essential for Flavivirus RNA replication

Tertiary or higher-order RNA motifs that regulate replication of positive-strand RNA viruses are as yet poorly understood. Using Japanese encephalitis virus (JEV), we now show that a key element in JEV RNA replication is a complex RNA motif that includes a string of three discontinuous complementary sequences (TDCS). The TDCS consists of three 5-nt-long strands, the left (L) strand upstream of the translation initiator AUG adjacent to the 5′-end of the genome, and the middle (M) and right (R) strands corresponding to the base of the Flavivirus-conserved 3′ stem–loop structure near the 3′-end of the RNA. The three strands are arranged in an antiparallel configuration, with two sets of base-pairing interactions creating L-M and M-R duplexes. Disrupting either or both of these duplex regions of TDCS completely abolished RNA replication, whereas reconstructing both duplex regions, albeit with mutated sequences, fully restored RNA replication. Modeling of replication-competent genomes recovered from a large pool of pseudorevertants originating from six replication-incompetent TDCS mutants suggests that both duplex base-pairing potentials of TDCS are required for RNA replication. In all cases, acquisition of novel sequences within the 3′M-R duplex facilitated a long-range RNA–RNA interaction of its 3′M strand with either the authentic 5′L strand or its alternative (invariably located upstream of the 5′ initiator), thereby restoring replicability. We also found that a TDCS homolog is conserved in other flaviviruses. These data suggest that two duplex base-pairings defined by the TDCS play an essential regulatory role in a key step(s) of Flavivirus RNA replication.     

Loop-mediated isothermal amplification of DNA

We have developed a novel method, termed loop-mediated isothermal amplification (LAMP), that amplifies DNA with high specificity, efficiency and rapidity under isothermal conditions. This method employs a DNA polymerase and a set of four specially designed primers that recognize a total of six distinct sequences on the target DNA. An inner primer containing sequences of the sense and antisense strands of the target DNA initiates LAMP. The following strand displacement DNA synthesis primed by an outer primer releases a single-stranded DNA. This serves as template for DNA synthesis primed by the second inner and outer primers that hybridize to the other end of the target, which produces a stem–loop DNA structure. In subsequent LAMP cycling one inner primer hybridizes to the loop on the product and initiates displacement DNA synthesis, yielding the original stem–loop DNA and a new stem–loop DNA with a stem twice as long. The cycling reaction continues with accumulation of 10⁹ copies of target in less than an hour. The final products are stem–loop DNAs with several inverted repeats of the target and cauliflower-like structures with multiple loops formed by annealing between alternately inverted repeats of the target in the same strand. Because LAMP recognizes the target by six distinct sequences initially and by four distinct sequences afterwards, it is expected to amplify the target sequence with high selectivity.     

Physical and functional interactions of the tumor suppressor protein p53 and DNA polymerase alpha-primase

The wild-type form of p53 contains an intrinsic 3′–5′-exonuclease activity. As p53 forms a complex with DNA polymerase α-primase (pol-prim) in vivo this finding suggests that p53 might cooperate with pol-prim to stabilize the genetic information of living cells. To test this hypothesis, exonuclease-free DNA pol-prim was expressed alone or together with p53 for purification. Pol-prim formed a complex with p53, which was purified by ion exchange and immunoaffinity chromatography from baculovirus-infected insect cells. The p53-containing pol-prim fractions removed a 3′-unpaired nucleotide with a 1.5–2-fold higher rate than a paired nucleotide, whereas the four subunit pol-prim did not have any exonuclase activity. Therefore, only p53/pol-prim was able to elongate a primer-template that contained a 3′-unpaired primer end in vitro. To achieve this, the 3′–5′-exonuclease activity of p53 excised the unpaired nucleotide at the 3′-end of the primer and created a paired 3′-end, which pol-prim was able to elongate. The exonuclease activity of p53 as well as the elongation of a primer with a mispaired 3′-end was inhibited specifically by the anti-p53 monoclonal antibodies PAb240 and PAb421.     

New approach to real-time nucleic acids detection: folding polymerase chain reaction amplicons into a secondary structure to improve cleavage of F?rster resonance energy transfer probes in 5′-nuclease assays

The article describes a new technology for real-time polymerase chain reaction (PCR) detection of nucleic acids. Similar to Taqman, this new method, named Snake, utilizes the 5′-nuclease activity of Thermus aquaticus (Taq) DNA polymerase that cleaves dual-labeled Förster resonance energy transfer (FRET) probes and generates a fluorescent signal during PCR. However, the mechanism of the probe cleavage in Snake is different. In this assay, PCR amplicons fold into stem–loop secondary structures. Hybridization of FRET probes to one of these structures leads to the formation of optimal substrates for the 5′-nuclease activity of Taq. The stem–loop structures in the Snake amplicons are introduced by the unique design of one of the PCR primers, which carries a special 5′-flap sequence. It was found that at a certain length of these 5′-flap sequences the folded Snake amplicons have very little, if any, effect on PCR yield but benefit many aspects of the detection process, particularly the signal productivity. Unlike Taqman, the Snake system favors the use of short FRET probes with improved fluorescence background. The head-to-head comparison study of Snake and Taqman revealed that these two technologies have more differences than similarities with respect to their responses to changes in PCR protocol, e.g. the variations in primer concentration, annealing time, PCR asymmetry. The optimal PCR protocol for Snake has been identified. The technology’s real-time performance was compared to a number of conventional assays including Taqman, 3′-MGB-Taqman, Molecular Beacon and Scorpion primers. The test trial showed that Snake supersedes the conventional assays in the signal productivity and detection of sequence variations as small as single nucleotide polymorphisms. Due to the assay’s cost-effectiveness and simplicity of design, the technology is anticipated to quickly replace all known conventional methods currently used for real-time nucleic acid detection.     

Role of helical constraints of the EBS1–IBS1 duplex of a group II intron on demarcation of the 5′ splice site

Recognition of the 5′ splice site by group II introns involves pairing between an exon binding sequence (EBS) 1 within the ID3 stem–loop of domain 1 and a complementary sequence at the 3′ end of exon 1 (IBS1). To identify the molecular basis for splice site definition of a group IIB ai5γ intron, we probed the solution structure of the ID3 stem–loop alone and upon binding of its IBS1 target by solution NMR. The ID3 stem was structured. The base of the ID3 loop was stacked but displayed a highly flexible EBS1 region. The flexibility of EBS1 appears to be a general feature of the ai5γ and the smaller Oceanobacillus iheyensis (O.i.) intron and may help in effective search of conformational space and prevent errors in splicing as a result of fortuitous base-pairing. Binding of IBS1 results in formation of a structured seven base pair duplex that terminates at the 5′ splice site in spite of the potential for additional A-U and G•U pairs. Comparison of these data with conformational features of EBS1–IBS1 duplexes extracted from published structures suggests that termination of the duplex and definition of the splice site are governed by constraints of the helical geometry within the ID3 loop. This feature and flexibility of the uncomplexed ID3 loop appear to be common for both the ai5γ and O.i. introns and may help to fine-tune elements of recognition in group II introns.     

Polarity of human replication protein A binding to DNA

Replication protein A (RPA), the nuclear single-stranded DNA binding protein is involved in DNA replication, nucleotide excision repair (NER) and homologous recombination. It is a stable heterotrimer consisting of subunits with molecular masses of 70, 32 and 14 kDa (p70, p32 and p14, respectively). Gapped DNA structures are common intermediates during DNA replication and NER. To analyze the interaction of RPA and its subunits with gapped DNA we designed structures containing 9 and 30 nucleotide gaps with a photoreactive arylazido group at the 3′-end of the upstream oligonucleotide or at the 5′-end of the downstream oligonucleotide. UV crosslinking and subsequent analysis showed that the p70 subunit mainly interacts with the 5′-end of DNA irrespective of DNA structure, while the subunit orientation towards the 3′-end of DNA in the gap structures strongly depends on the gap size. The results are compared with the data obtained previously with the primer–template systems containing 5′- or 3′-protruding DNA strands. Our results suggest a model of polar RPA binding to the gapped DNA.     

Solution structure of the apical stem-loop of the human hepatitis B virus encapsidation signal

Hepatitis B virus (HBV) replication is initiated by HBV RT binding to the highly conserved encapsidation signal, epsilon, at the 5′ end of the RNA pregenome. Epsilon contains an apical stem–loop, whose residues are either totally conserved or show rare non-disruptive mutations. Here we present the structure of the apical stem–loop based on NOE, RDC and ¹H chemical shift NMR data. The ¹H chemical shifts proved to be crucial to define the loop conformation. The loop sequence 5′-CUGUGC-3′ folds into a UGU triloop with a CG closing base pair and a bulged out C and hence forms a pseudo-triloop, a proposed protein recognition motif. In the UGU loop conformations most consistent with experimental data, the guanine nucleobase is located on the minor groove face and the two uracil bases on the major groove face. The underlying helix is disrupted by a conserved non-paired U bulge. This U bulge adopts multiple conformations, with the nucleobase being located either in the major groove or partially intercalated in the helix from the minor groove side, and bends the helical stem. The pseudo-triloop motif, together with the U bulge, may represent important anchor points for the initial recognition of epsilon by the viral RT.     

Identification of antisense RNA stem–loops that inhibit RNA–protein interactions using a bacterial reporter system

Many well-characterized examples of antisense RNAs from prokaryotic systems involve hybridization of the looped regions of stem–loop RNAs, presumably due to the high thermodynamic stability of the resulting loop–loop and loop–linear interactions. In this study, the identification of RNA stem–loops that inhibit U1A protein binding to the hpII RNA through RNA–RNA interactions was attempted using a bacterial reporter system based on phage λ N-mediated antitermination. As a result, loop sequences possessing 7–8 base complementarity to the 5′ region of the boxA element important for functional antitermination complex formation, but not the U1 hpII loop, were identified. In vitro and in vivo mutational analysis strongly suggested that the selected loop sequences were binding to the boxA region, and that the structure of the antisense stem–loop was important for optimal inhibitory activity. Next, in an attempt to demonstrate the ability to inhibit the interaction between the U1A protein and the hpII RNA, the rational design of an RNA stem–loop that inhibits U1A-binding to a modified hpII was carried out. Moderate inhibitory activity was observed, showing that it is possible to design and select antisense RNA stem–loops that disrupt various types of RNA–protein interactions.