The influence of the non-nucleotide insert on the hybridization properties of oligonucleotides

The effect of different non-nucleotide inserts incorporated into oligonucleotide chains on their hybridization properties was studied by the method of thermal denaturation. Various types of alkyldiols and oligoethylene glycols were used as inserts modifying oligonucleotide backbone. Such modification of oligonucleotides caused the destabilization of their complementary complexes. It was shown that the hybridization properties of the modified oligonucleotides depend on several features of inserts: the type, number, length of insertions, and positions of interrupted dinucleotide steps in oligonucleotide chain.     

Cleavage of synthetic substrates containing non-nucleotide inserts by restriction endonucleases. Change in the cleavage specificity of endonuclease SsoII.

A study was made of the interaction between restriction endonucleases recognizing CCNGG (SsoII and ScrFI) or CCA/TGG (MvaI and EcoRII) DNA sequences and a set of synthetic substrates containing 1,3-propanediol, 1,2-dideoxy-D-ribofuranose or 9-[1'-hydroxy-2'-(hydroxymethyl)ethoxy] methylguanine (gIG) residues replacing either one of the central nucleosides or dG residues in the recognition site. The non-nucleotide inserts (except for gIG) introduced into the recognition site both increase the efficiency of SsoII and change its specificity. A cleavage at the noncanonical position takes place, in some cases in addition to the correct ones. Noncanonical hydrolysis by SsoII occurs at the phosphodiester bond adjacent to the point of modification towards the 5'-end. With the guanine base returned (the substrate with gIG), the correct cleavage position is restored. ScrFI specifically cleaves all the modified substrates. DNA duplexes with non-nucleotide inserts (except for the gIG-containing duplex) are resistant to hydrolysis by MvaI and EcoRII. Prompted by the data obtained we discuss the peculiarities of recognition by restriction endonucleases of 5-membered DNA sequences which have completely or partially degenerated central base pairs. It is suggested that SsoII forms a complex with DNA in an 'open' form.     

Hybridization of the bridged oligonucleotides with DNA: thermodynamic and kinetic studies

Hybridization properties of oligonucleotides containing non-nucleotide inserts designed on the basis of synthetic abasic sites, oligomethylene diols or oligoethylene glycols have been characterized. The influence of the inserts which generate extrahelical anucleotidic bulges on thermodynamics, kinetics of hybridization of bridged oligonucleotide with DNA has been studied by UV-melting and stopped-flow techniques. Circular dichroism spectrometry data show that anucleotidic bulges in the middle of the duplex does not alter the B-form helix conformation. Nevertheless, the insert induces destabilization of the duplex structure, caused mostly by the considerable enhancement of the dissociation rates. Free energy increments for the extrahelical anucleotidic bulges can be described in the nearest-neighbor approximation. The thermodynamic effect of the insert lengthening obeys a simple Jacobson-Stockmayer entropy extrapolation. Independently of the insert type, the free energy term is directly proportional to the logarithm of the number of bonds between the oligonucleotide fragments. The behavior of hydrophobic inserts formed by 10-hydroxydecyl-1-phospate units is an exception to the rule.     

Change in the cleavage site of synthetic substrates of SsoII restriction endonucleases upon introduction of non-nucleotide inserts in the recognition segment]

The cleavage of synthetic DNA duplexes containing 1,3-propanediol, 1,2-dideoxy-D-ribofuranose or 9-[1'-hydroxy-2'-(hydroxymethyl)ethoxy]methylguanine (glG) residues instead of one of dG residues or one of the nucleosides of the central base pair of the recognition site by SsoII restriction endonuclease (decreases CCNGG) has been studied. It is found that the non-nucleotide insertions (except for glG) result in a change of the SsoII cleavage site and an increase of the efficiency of the cleavage. The novel noncanonical cleavage occurs at the phosphodiester bond adjoining the non-nucleotide insert from the 5'-end.     

A convenient method for the synthesis of phosphoramidite non-nucleotide inserts for preparation of functionalized oligonucleotides

A simple approach to the synthesis of amidophosphite synthons of achiral non-nucleotide inserts using 4-(2-(4,4??-dimethoxytrityloxy)ethyl)morpholine-2,3-dione as a backbone of key precursor was suggested. Non-nucleotide synthons were synthesized using this approach that were suitable for synthesis of acridine-containing oligonucleotide derivatives, as well as oligonucleotides with branched carbohydrate-phosphate backbone.     

Displacement of a DNA binding protein by Dda helicase

Bacteriophage T4 Dda helicase has recently been shown to be active as a monomer for unwinding of short duplex oligonucleotides and for displacing streptavidin from 3′-biotinylated oligonucleotides. However, its activity for streptavidin displacement and DNA unwinding has been shown to increase as the number of Dda molecules bound to the substrate molecule increases. A substrate was designed to address the ability of Dda to displace DNA binding proteins. A DNA binding site for the Escherichia coli trp repressor was introduced into an oligonucleotide substrate for Dda helicase containing single-stranded overhang. Here we show that a Dda monomer is insufficient to displace the E.coli trp repressor from dsDNA under single turnover conditions, although the substrate is unwound and the repressor displaced when the single-stranded overhang is long enough to accommodate two Dda molecules. The quantity of product formed increases when the substrate is able to accommodate more than two Dda molecules. These results indicate that multiple Dda molecules act to displace DNA binding proteins in a manner that correlates with the DNA unwinding activity and streptavidin displacement activity. We suggest a cooperative inchworm model to describe the activities of Dda helicase.     

T4 endonuclease V exists in solution as a monomer and binds to target sites as a monomer

Endonuclease V, a N-glycosylase/lyase from T4 bacteriophage that initiates the repair of cyclobutane pyrimidine dimers in DNA, has been reported to form a monomer-dimer equilibrium in solution [Nickell and Lloyd (1991) Biochemistry 30, 8638], although the enzyme has only been crystallized in the absence of substrate as a monomer [Morikawa et al. (1992) Science 256, 523]. In this study, analytical gel filtration and sedimentation equilibrium techniques were used to rigorously characterize the association state of the enzyme in solution. In contrast to the previous report, at 100 mM KCl endonuclease V was found to exist predominantly as a monomer in solution by both of these techniques; no evidence for dimerization was seen. To characterize the oligomeric state of the enzyme at its target sites on DNA, the enzyme was bound to oligonucleotides containing a single site specific pyrimidine dimer or tetrahydrofuran residue. These complexes were analyzed by nondenaturing gel electrophoresis at various acrylamide concentrations in order to determine the molecular weights of the enzyme-DNA complexes. The results from these experiments demonstrate that endonuclease V binds to cyclobutane pyrimidine dimer and tetrahydrofuran site containing DNA as a monomer.     

Retroviral DNA Integration

DNA integration is a unique enzymatic process shared by all retroviruses and retrotransposons. During integration, double-stranded linear viral DNA is inserted into the host genome in a process catalyzed by the virus-encoded integrase (IN). The mechanism involves a series of nucleophillic attacks, the first of which removes the terminal 2 bases from the 3′ ends of the long terminal repeats and of the second which inserts the viral DNA into the host genome. IN specifically recognizes the DNA sequences at the termini of the viral DNA, juxtaposing both ends in an enzyme complex that inserts the viral DNA into a single site in a concerted manner. Small duplications of the host DNA, characteristic of the viral IN, are found at the sites of insertion. At least two host proteins, HMG-I(Y) and BAF, have been shown to increase the efficiency of the integration reaction.     

Structural insights into the substrate specificity of the endonuclease activity of the influenza virus cap-snatching mechanism

The endonuclease activity within the influenza virus cap-snatching process is a proven therapeutic target. The anti-influenza drug baloxavir is highly effective, but is associated with resistance mutations that threaten its clinical efficacy. The endonuclease resides within the N-terminal domain of the PA subunit (PA_N) of the influenza RNA dependent RNA polymerase, and we report here complexes of PA_N with RNA and DNA oligonucleotides to understand its specificity and the structural basis of baloxavir resistance mutations. The RNA and DNA oligonucleotides bind within the substrate binding groove of PA_N in a similar fashion, explaining the ability of the enzyme to cleave both substrates. The individual nucleotides occupy adjacent conserved pockets that flank the two-metal active site. However, the 2′ OH of the RNA ribose moieties engage in additional interactions that appear to optimize the binding and cleavage efficiency for the natural substrate. The major baloxavir resistance mutation at position 38 is at the core of the substrate binding site, but structural studies and modeling suggest that it maintains the necessary virus fitness via compensating interactions with RNA. These studies will facilitate the development of new influenza therapeutics that spatially match the substrate and are less likely to elicit resistance mutations.     

Controlled ligation of oligodeoxyribonucleotides of DNA-ligase of the T4 phage

The enzymatic ligation of 5-10-membered synthetic oligodeoxyribonucleotides forming the complementary DNA-like duplexes has been studied. The possibility of selective DNA ligase catalyzed ligation of 5'-adenylylated derivatives of oligonucleotides in the absence of rATP and also the selective joining of cohesive ends in the presence of blunt ends in the complex mixtures of oligonucleotides at definite concentrations of rATP have been demonstrated. The influence of length and sequence of short synthetic DNA-duplexes on the efficiency of ligation has been shown. We have identified the unusual octanucleotide dpTATAATAT, that being able to form concatemer complexes could not be polymerized by T4 DNA ligase.     

DNA-induced polymerization of HIV-1 integrase analyzed with fluorescence fluctuation spectroscopy

Human immunodeficiency virus type 1 (HIV-1) integrase is essential for viral replication. Integrase inserts the viral DNA into the host DNA. We studied the association of integrase to fluorescently labeled oligonucleotides using fluorescence correlation spectroscopy. The binding of integrase to the fluorescent oligonucleotides resulted in the appearance of bright spikes during fluorescence correlation spectroscopy measurements. These spikes arise from the formation of high molecular mass protein-DNA complexes. The fluorescence of the free DNA was separated from the spikes with a statistical method. From the decrease of the concentration of free oligonucleotides, a site association constant was determined. The DNA-protein complexes were formed rapidly in a salt-dependent manner with site association constants ranging between 5 and 40 microm(-1) under different conditions. We also analyzed the kinetics of the DNA-protein complex assembly and the effect of different buffer components. The formation of the fluorescent protein-DNA complex was inhibited by guanosine quartets, and the inhibition constant was determined at 1.8 +/- 0.6 x 10(8) m(-1). Displacement of bound DNA with G-quartets allowed the determination of the dissociation rate constant and proves the reversibility of the association process.     

Use of Modified Flap Structures for Study of Base Excision Repair Proteins

To investigate interactions between proteins participating in the long-patch pathway of base excision repair (BER), DNA duplexes with flap strand containing modifications in sugar phosphate backbone within the flap-forming oligonucleotides were designed. When the flap-forming oligonucleotide consisted of two sequences bridged by a decanediol linker located in the flap strand near the branch point, the efficiency and position of cleavage by flap endonuclease 1 (FEN1) differed from those for natural flap. The cleavage rate of chimeric structure by FEN1 was lower than that of a normal substrate. When we introduced the second modification in the flap-forming oligonucleotide, the cleavage rate decreased significantly. To estimate efficiency of recognition and processing of the chimeric structures by BER proteins, we studied the rate of DNA synthesis by DNA polymerase beta (Pol beta) and the rate of nucleotide excision at the 3'-end of the initiating primer by apurinic/apyrimidinic endonuclease 1 (APE1) compared with those for the natural DNA duplexes. Efficiency of strand-displacement DNA synthesis catalyzed by Pol beta was shown to be higher for flap structures containing non-nucleotide linkers. The chimeric structures were processed by the 3'-exonuclease activity of APE1 with efficiency lower than that for a normal flap structure. Thus, DNA duplexes with modifications in sugar phosphate backbone can be used to mimic intermediates of the long-patch pathway of BER in reconstituted systems containing FEN1. Based on chimeric and natural oligonucleotides, photoreactive DNA structures were designed. The photoreactive dCMP moiety was introduced into the 3'-end of DNA primer via the activity of Pol beta. The photoreactive DNA duplexes--3'-recessed DNA, nicked DNA, and flap structures containing natural and chimeric oligonucleotides--were used for photoaffinity labeling of BER proteins.     

Oligonucleotides labeled with single fluorophores as sensors for deoxynucleotide triphosphate binding by DNA polymerases

Oligonucleotides labeled with a single fluorophore (fluorescein or tetramethylrhodamine) have been used previously as fluorogenic substrates for a number of DNA modifying enzymes. Here, it is shown that such molecules can be used as fluorogenic probes to detect the template-dependent binding of deoxynucleotide triphosphates by DNA polymerases. Two polymerases were used in this work: the Klenow fragment of the Escherichia coli DNA polymerase I and the Bacillus stearothermophilus polymerase, Bst. When complexes of these polymerases with dye-labeled hairpin-type oligonucleotides were mixed with various deoxynucleotide triphosphates in the presence of Sr²⁺ as the divalent metal cation, the formation of ternary DNA-polymerase-dNTP complexes was detected by concentration-dependent changes in the fluorescence intensities of the dyes. Fluorescein- and tetramethylrhodamine-labeled probes of identical sequences responded differently to the two polymerases. With Bst polymerase, the fluorescence intensities of all probes increased with the next correct dNTP; with Klenow polymerase, tetramethylrhodamine-labeled probes increased their fluorescence, but the intensity of fluorescein-labeled probes decreased on formation of ternary complexes with the correct incoming nucleotides. The use of Sr²⁺ as the divalent metal ion allowed the formation of catalytically inactive ternary complexes and obviated the need for using 2′,3′-dideoxy-terminated oligonucleotides as would have been needed in the case of Mg²⁺ as the metal ion.     

Nuclease resistance and RNase H sensitivity of oligonucleotides bridged by oligomethylenediol and oligoethylene glycol linkers

The properties of new chimeric oligodeoxynucleotides made of short sequences (tetramers, pentamers, octamers, and decamers) bridged by hexamethylenediol and hexaethylene glycol linkers have been investigated. These chimeric oligonucleotides showed an improved resistance toward snake venom 3'-phosphodiesterase, with an increased stability when a terminal 3'-3'-internucleotide phosphodiester bond is present. It also has been demonstrated that the hybrid complexes formed by bridged oligonucleotides and a complementary 20-mer RNA are able to elicit the activity of ribonuclease H (RNase H) from Escherichia coli. The substrate properties of chimeric oligonucleotides depend on the length of the oligonucleotide fragments bridged by linkers. Introduction of a nonnucleotide spacer into the native oligonucleotide only slightly hampers the extent of the RNA hydrolysis in the hybrid complexes, whereas a modification of the site of reaction is observed as a possible consequence of the steric disturbance due to the aliphatic linkers. Hence, these new chimeric oligonucleotides, namely, short oligonucleotide fragments bridged by nonnucleotide linkers, demonstrate a favorable combination of exonuclease resistance and high substrate activity toward RNase H. As a consequence, these chimeric oligonucleotides could be proposed as new, promising analogs to be used in the antisense strategy.     

Differential requirements for cis and trans V(D)J cleavage: effects of substrate length

The assembly of productive synaptic complexes is a critical, but poorly understood, regulatory step in V(D)J recombination. Several lines of evidence suggest that there may be important differences between recombination involving sites situated in cis (on the same DNA molecule) and in trans (on separate molecules). Because biochemical experiments using both purified RAG proteins and crude extracts have failed to detect trans cleavage of plasmid substrates it has been thought that there is a substantial bias against trans synapsis. In conflict with these results are more recent studies showing that purified RAG proteins can catalyze trans cleavage of short oligonucleotide substrates. Furthermore, recent experiments have detected efficient trans cleavage of plasmid substrates in vivo. We sought to investigate why these different systems yield such divergent results. We found that, unexpectedly, the ability of both purified RAG proteins and crude extracts to cleave DNA substrates in trans is a function of substrate length. Our data raise two critical issues: first, oligonucleotides, which are the most commonly used substrates to study V(D)J recombination in vitro, do not mimic the behavior of plasmid substrates; second, in the trans cleavage reaction current purified RAG systems do not accurately reflect the in vivo situation. We propose a unifying model to explain the effects of substrate length and coniguration (cis or trans) on the efficiency of synapsis.     

Computational Investigation of Locked Nucleic Acid (LNA) Nucleotides in the Active Sites of DNA Polymerases by Molecular Docking Simulations

Aptamers constitute a potential class of therapeutic molecules typically selected from a large pool of oligonucleotides against a specific target. With a scope of developing unique shorter aptamers with very high biostability and affinity, locked nucleic acid (LNA) nucleotides have been investigated as a substrate for various polymerases. Various reports showed that some thermophilic B-family DNA polymerases, particularly KOD and Phusion DNA polymerases, accepted LNA-nucleoside 5′-triphosphates as substrates. In this study, we investigated the docking of LNA nucleotides in the active sites of RB69 and KOD DNA polymerases by molecular docking simulations. The study revealed that the incoming LNA-TTP is bound in the active site of the RB69 and KOD DNA polymerases in a manner similar to that seen in the case of dTTP, and with LNA structure, there is no other option than the locked C3′-endo conformation which in fact helps better orienting within the active site.     

Molecular requirements for degradation of a modified sense RNA strand by Escherichia coli ribonuclease H1

The structural requirements for DNA/RNA hybrids to be suitable substrates for RNase H1 are well described; however the tolerance level of this enzyme towards modifications that do not alter the duplex conformation is not clearly understood, especially with respect to the sense RNA strand. In order to investigate the molecular requirements of Escherichia coli RNase H1 (termed RNase H1 here) with respect to the sense RNA strand, we synthesized a series of oligonucleotides containing 2'-deoxy-2'-fluoro-beta-D-ribose (2'F-RNA) as a substitute for the natural beta-D-ribose sugars found in RNA. Our results from a series of RNase H1 binding and cleavage studies indicated that 2'F-RNA/DNA hybrids are not substrates of RNase H1 and ultimately led to the conclusion that the 2'-hydroxyl moiety of the RNA strand in a DNA/RNA hybrid is required for both binding and hydrolysis by RNase H1. Through the synthesis of a series of chimeric sense oligonucleotides of mixed RNA and 2'F-RNA composition, the gap requirements of RNase H1 within the sense strand were examined. Results from these studies showed that RNase H1 requires at least five or six natural RNA residues within the sense RNA strand of a hybrid substrate for both binding and hydrolysis. The RNase H1-mediated degradation patterns of these hybrids agree with previous suggestions on the processivity of RNase H1, mainly that the binding site is located 5' to the catalytic site with respect to the sense strand. They also suggest, however, that the binding and catalytic domains of RNase H1 might be closer than has been previously suggested. In addition to the above, physicochemical studies have revealed the thermal stabilities and relative conformations of these modified heteroduplexes under physiological conditions. These findings offer further insights into the physical binding and catalytic properties of the RNase H1-substrate interaction, and have been incorporated into a general model summarizing the mechanism of action of this unique enzyme.     

Mapping U2 snRNP--pre-mRNA interactions using biotinylated oligonucleotides made of 2''-OMe RNA.

Biotinylated 2'-OMe RNA oligonucleotides complementary to two separate regions of human U2 snRNA have been used as affinity probes to study U2 snRNP--pre-mRNA interactions. Both oligonucleotides bind specifically and allow highly selective removal of U2 snRNP from HeLa cell nuclear extracts. Pre-mRNA substrates can also be specifically affinity selected through oligonucleotides binding to U2 snRNP particles in splicing complexes. Stable binding of U2 snRNP to pre-mRNA is blocked by the pre-binding of an oligonucleotide to the branch site complementary region of U2 snRNA, but not by an oligonucleotide binding to the 5' terminus of U2. Both oligonucleotides affinity select the intron product, but not the intron intermediate, when added after spliceosome assembly has taken place. The effect of 2'-OMe RNA oligonucleotides on splicing complex formation has been used to demonstrate that complexes containing U2 snRNP and unspliced pre-mRNA are precursors to functional spliceosomes.