DNA/RNA heteroduplex oligonucleotide technology for regulating lymphocytes in vivo.

Manipulating lymphocyte functions with gene silencing approaches is promising for treating autoimmunity, inflammation, and cancer. Although oligonucleotide therapy has been proven to be successful in treating several conditions, efficient in vivo delivery of oligonucleotide to lymphocyte populations remains a challenge. Here, we demonstrate that intravenous injection of a heteroduplex oligonucleotide (HDO), comprised of an antisense oligonucleotide (ASO) and its complementary RNA conjugated to α-tocopherol, silences lymphocyte endogenous gene expression with higher potency, efficacy, and longer retention time than ASOs. Importantly, reduction of Itga4 by HDO ameliorates symptoms in both adoptive transfer and active experimental autoimmune encephalomyelitis models. Our findings reveal the advantages of HDO with enhanced gene knockdown effect and different delivery mechanisms compared with ASO. Thus, regulation of lymphocyte functions by HDO is a potential therapeutic option for immune-mediated diseases.

Programmable DNA-augmented hydrogels for controlled activation of human lymphocytes.

Contractile forces within the planar interface between T cell and antigen-presenting surface mechanically stimulate T cell receptors (TCR) in the mature immune synapses. However, the origin of mechanical stimulation during the initial, i.e., presynaptic, microvilli-based TCR activation in the course of immune surveillance remains unknown and new tools to help address this problem are needed. In this work, we develop nucleic acid nanoassembly (NAN)-based technology for functionalization of hydrogels using isothermal toehold-mediated reassociation of RNA/DNA heteroduplexes. Resulting platform allows for regulation with NAN linkers of 3D force momentum along the TCR mechanical axis, whereas hydrogels contribute to modulation of 2D shear modulus. By utilizing different lengths of NAN linkers conjugated to polyacrylamide gels of different shear moduli, we demonstrate an efficient capture of human T lymphocytes and tunable activation of TCR, as confirmed by T-cell spreading and pY foci.

DNA-RNA Heteroduplex Oligonucleotide for Highly Efficient Gene Silencing.

Heteroduplex oligonucleotides (HDOs) were a novel type of nucleic acid drugs based on an antisense oligonucleotide (ASO) strand and its complementary RNA (cRNA ) strand. HDOs were originally designed to improve the properties of RNase H-dependent ASOs and we reported in our first paper that HDOs conjugated with an α-tocopherol ligand (Toc-HDO ) based on a gapmer ASO showed 20 times higher silencing effect to liver apolipoprotein B (apoB) mRNA in vivo than the parent ASO. Thereafter the HDO strategy was found to be also effective for improving the properties of ASOs modulating blood-brain barrier function and ASO antimiRs which are RNase H-independent ASOs. Therefore, the HDO strategy has been shown to be versatile technology platform to develop effective nucleic acid drugs.

Gapmer Antisense Oligonucleotides Targeting 5S Ribosomal RNA Can Reduce Mature 5S Ribosomal RNA by Two Mechanisms.

In this study, we demonstrate that 5S ribosomal RNA (rRNA), a highly structured and protein-bound RNA, is quite difficult to reduce with antisense oligonucleotides (ASOs). However, we found a single accessible site that was targetable with a high-affinity complementary ASO. The ASO appeared to bind to the site, recruit RNaseH1, and cause degradation of the 5S RNA. Intriguingly, we also observed that the same ASO induced an accumulation of pre-5S RNA, which may contribute to reduced levels of mature 5S rRNA. As expected, ASO mediated reduction of 5S RNA, and modest inhibition of processing of pre-5S RNA resulted in nucleolar toxicity. However, the toxicity induced was minimal compared with actinomycin D, consistent with its modest effects on pre-5S rRNA. Mechanistically, we show that the accumulation of pre-5S rRNA required ASO hybridization to the cognate rRNA sequence but was independent of RNaseH1 activity. We found that Ro60 and La, proteins known to bind misprocessed RNAs, likely sequester the ASO-pre-5S rRNA species and block RNaseH1 activity, thus identifying another example of competitive mechanisms mediated by proteins that compete with RNaseH1 for binding to ASO-RNA heteroduplexes.

Inulin Derivatives Obtained Via Enhanced Microwave Synthesis for Nucleic Acid Based Drug Delivery.

A new class of therapeutic agents with a high potential for the treatment of different socially relevant human diseases is represented by Nucleic Acid Based Drugs (NABD), including small interfering RNAs (siRNA), decoy oligodeoxynucleotides (decoy ODN) and antisense oligonucleotides (ASOs). Although NABD can be engineered to be specifically directed against virtually any target, their susceptibility to nuclease degradation and the difficulty of delivery into target tissues severely limit their use in clinical practice and require the development of an appropriate nanostructured delivery system. For delivery of NABD, Inulin (Inu), a natural, water soluble and biocompatible polysaccharide, was derivatized by Spermine (Spm), a flexible molecule with four amine groups that, having pKa values in the range between 8-11, is mainly in the protonated form at pH 7.4. The synthesis of related copolymers (Inu-Spm) was performed by a two step reaction, using a method termed Enhanced Microwave Synthesis (EMS) which has the advantage, compared to conventional microwave reaction, that high amount of energy can be applied to the reaction system, by administering microwave irradiation and simultaneously controlling the temperature in the reaction vessel with cooled air. The synthesized inulin derivatives were characterized by FT-IR spectra and (1)H-NMR. INU-Spm derivatives with a degree of derivatization of about 14 % mol/mol were obtained. These polycations were tested to evaluate their ability to form non covalent complexes with genetic material (polyplexes). Agarose gel retardation assays showed that the obtained copolymers are able to electrostatically interact with DNA duplex to form polyplexes at different c/p weight ratios. Moreover, light scattering studies, performed to analyze size and z-potential of polyplexes, evidenced that copolymers are able to interact with genetic material leading to the formation of nanoscaled systems. In addition, biocompatibility of polyplexes was demonstrated by performing cytotoxicity assays on a 16HBE cell line. Transfection studies, performed by using siRNA able to silence luciferase expression, demonstrate the efficiency of polyplexes to transfect the same cell line, with a reduction of luciferase expression to about 70%. These results encourage us to work with these copolymers to obtain an efficient and feasible inulin based NABD delivery system.

The use of hairpin DNA duplexes as HIV-1 fusion inhibitors: synthesis, characterization, and activity evaluation.

Discovery of new drugs for the treatment of AIDS that possess unique structures associated with novel mechanisms of action are of great importance due the rapidity with which drug-resistant HIV-1 strains evolve. Recently we reported on a novel class of DNA duplex-based HIV-1 fusion inhibitors modified with hydrophobic groups. The present study describes a new category of hairpin fusion inhibitor DNA duplexes bearing a 3 nucleotide loop located at either the hydrophobic or hydrophilic end. The new loop structures were designed to link 2 separate duplex-forming oligodeoxynucleotides (ODNs) to make helix-assembly easier and more thermally stable resulting in a more compact form of DNA duplex based HIV-1 fusion inhibitors. A series of new hairpin duplexes were tested for anti-HIV-1 cell-cell membrane fusion activity. In addition, Tm, CD, fluorescent resonance energy transfer assays, and molecular modeling analyses were carried out to define their structural activity relationships and possible mechanisms of action.

Sequence-specific base pair mimics are efficient topoisomerase IB inhibitors.

Topoisomerase IB controls DNA topology by cleaving DNA transiently. This property is used by inhibitors, such as camptothecin, that stabilize, by inhibiting the religation step, the cleavage complex, in which the enzyme is covalently attached to the 3'-phosphate of the cleaved DNA strand. These drugs are used in clinics as antitumor agents. Because three-dimensional structural studies have shown that camptothecin derivatives act as base pair mimics and intercalate between two base pairs in the ternary DNA-topoisomerase-inhibitor complex, we hypothesized that base pairs mimics could act like campthotecin and inhibit the religation reaction after the formation of the topoisomerase I-DNA cleavage complex. We show here that three base pair mimics, nucleobases analogues of the aminophenyl-thiazole family, once targeted specifically to a DNA sequence were potent topoisomerase IB inhibitors. The targeting was achieved through covalent linkage to a sequence-specific DNA ligand, a triplex-forming oligonucleotide, and was necessary to position and keep the nucleobase analogue in the cleavage complex. In the absence of triplex formation, only a weak binding to the DNA and topoisomerase I-mediated DNA cleavage was observed. The three compounds were equally active once conjugated, implying that the intercalation of the nucleobase upon triplex formation is the essential feature for the inhibition activity.

DHX9 pairs with IPS-1 to sense double-stranded RNA in myeloid dendritic cells.

The innate immune system is equipped with many molecular sensors for microbial DNA/RNA to quickly mount antimicrobial host immune responses. In this paper, we identified DHX9, a DExDc helicase family member, as an important viral dsRNA sensor in myeloid dendritic cells (mDCs). Knockdown of DHX9 expression by small heteroduplex RNA dramatically blocked the ability of mDCs to produce IFN-α/ß and proinflammatory cytokines in response to polyinosine-polycytidylic acid, influenza A, and reovirus. DHX9 could specifically bind polyinosine-polycytidylic acid via its double-strand RNA binding motifs. DHX9 interacted with IPS-1 via the HelicC-HA2-DUF and CARD domains of DHX9 and IPS-1, respectively. Knockdown of DHX9 expression in mDCs blocked the activation of NF-κB and IFN regulatory factor 3 by dsRNA. Collectively, these results suggest that DHX9 is an important RNA sensor that is dependent on IPS-1 to sense pathogenic RNA.

DNA-based strategies for blocking HMGB1 cytokine activity: design, synthesis and preliminary in vitro/in vivo assays of DNA and DNA-like duplexes.

In this work we report the design and synthesis of kinked oligonucleotide duplexes as potential inhibitors of HMGB1, a cytokine which triggers a broad range of immunological effects. We found that the designed ligands can interact with HMGB1, as evidenced by circular dichroism spectroscopy, and are able to block some extracellular effects induced by the protein, such as cellular proliferation and migration, as we demonstrated by in vitro biological assays. After selecting the most stable and active kinked duplex, we synthesized the corresponding PNA/DNA chimeric duplex which resulted to be more resistant to enzymatic degradation, and showed a biological activity comparable to that of the natural duplex. Preliminary in vivo assays in a mouse inflammatory model, showed a significant decrease of the mortality after administration of the PNA/DNA kinked duplex to LPS-treated mice.

The critical DNA flanking sequences of a CpG oligodeoxynucleotide, but not the 6 base CpG motif, can be replaced with RNA without quantitative or qualitative changes in Toll-like receptor 9-mediated activity.

Double- and single-stranded oligodeoxynucleotides containing unmethylated cytosine-guanosine (CpG) dinucleotides (CpG-ODN) activate immune cells via TLR9. In this report we synthesized hybrid DNA-RNA molecules (HDR) in order to further explore the structure-immune function relationship of CpG-ODN in TLR9 signaling and the potential immunomodulatory properties of RNA. We demonstrate that replacement of the deoxyadenosine flanking sequences, critical for the immune activating properties of CpG-ODN, with a similar number of adenosines, although not guanosines, cytosines, or uracils, maintains complete immunostimulatory activity of the hybrid oligonucleotide in vitro, whereas a similar RNA replacement of even 1 base of the required unmethylated 6 base DNA motif (purine-purine-CpG-pyrimidine-pyrimidine) results in a complete loss of activity. Regardless of whether the critical flanking sequence was RNA or DNA there was no significant change in the quantitative or qualitative immune-stimulating activity, or TLR-specificity of the resulting sequences, thus underscoring the relatively permissive functional role of the flanking sequence, and the more specific role of the motif in mediating TLR9 signaling. These data further support a potential role for RNA in immunomodulation.

Nucleotides and heteroduplex DNA preserve the active conformation of Pseudomonas aeruginosa MutS by preventing protein oligomerization.

MutS, a component of the mismatch repair system begins the DNA reparation process by recognizing base/base mismatches or small insertion/deletion loops. We have cloned the mutS gene from the human opportunistic pathogen Pseudomonas aeruginosa and analysed the biochemical properties of the encoded protein. Complementation of the hypermutator phenotype of a P. aeruginosa mutS mutant strain indicated that the isolated gene was functional. When purified MutS was incubated at 37 degrees C in the absence of ligands, a rapid inactivation of the oligonucleotide binding capability and ATPase activity occurred. However, the presence of ATP, ADP or heteroduplex oligonucleotides, but not homoduplex oligonucleotides, prevented the protein from being inactivated. The analysis of the protein by native PAGE indicated that the active conformation state correlates with the presence of MutS dimer. Analysis by gel-filtration chromatography showed that the inactive protein formed by incubation at 37 degrees C in the absence of ligands corresponds to the formation of a high molecular mass oligomer. The kinetic analysis of the oligomer formation showed that the extent of the reaction was markedly dependent on the temperature and the presence of MutS ligands. However, the protein inactivation apparently occurred before the maximum extent of MutS oligomerization. Further analysis of the MutS oligomers by electron microscopy showed the presence of regular structures consisting of four subunits, with each subunit probably representing a MutS homodimer. It is concluded that MutS possesses an intrinsic propensity to form oligomeric structures and that the presence of physiological ligands, such as nucleotides or heteroduplex DNA, but not homoduplex DNA, plays an important role in keeping the protein in an active conformation by preventing protein oligomerization.

Ribonuclease H attack of leukaemic fused transcripts AML1-MTG8 (ETO) by DNA/RNA chimeric hammerhead ribozymes.

BACKGROUND: Catalytic anti-sense oligonucleotides might be useful tools for controlling specific gene expression. However, to obtain effective oligonucleotides of the desired function in vivo is still a difficult task. RESULTS: To evaluate the usefulness of synthesized DNA/RNA hammerhead ribozymes targeting AML1-MTG8 (ETO) leukaemic fusion transcripts in vivo, we analysed their effects on cell growth and the mechanism of action using isolated cell nuclei. These ribozymes inhibited the growth of leukaemic cell lines expressing the AML1 -MTG8 and degraded AML1-MTG8 mRNA in isolated nuclei of these cells. However, the reactions gave rise to additional cleavage products. Systematic cleavage analyses using an anti-sense oligonucleotide array revealed that the cleavage was induced by endogenous RNase H at specific sites, in accordance with their calculated melting temperature (Tm) values. With suppression of RNase H by sulfhydryl agents, the DNA/RNA ribozyme had a ribozyme catalytic activity. In addition, the ribozymes and anti-sense oligonucleotides suppressed the AML1-MTG8 protein in the leukaemic cells. CONCLUSIONS: The DNA/RNA ribozymes inhibited cell growth primarily via anti-sense effects, the main role of which was the activation of RNase H-digestion by their DNA arms. In addition, the isolated nuclei provided a useful assay system for modelling in vivo conditions for the quantitative evaluation of anti-sense/ribozyme activity.

Heteroduplex DNA and ATP induced conformational changes of a MutS mismatch repair protein from Thermus aquaticus.

ATP hydrolysis by MutS homologues is required for the function of these proteins in mismatch repair. However, the function of ATP hydrolysis in the repair reaction is not very clear. We have examined the role of ATP hydrolysis in oligomerization of Thermus aquaticus (Taq) MutS protein in solution. Analytical gel filtration and cross-linking of MutS protein with disuccinimidyl suburate suggest that TaqMutS is a dimer in the presence of ATP. ATP binding and hydrolysis by TaqMutS reduces the heteroduplex-DNA binding by the protein. Using limited proteolysis we detected extensive conformational changes of the TaqMutS protein in the presence of ATP and heteroduplex DNA. Heteroduplex-DNA binding is necessary for the observed conformational changes since F39A mutant protein defective in DNA binding does not display ATP-induced conformational changes. The implications of the observed conformational changes in the MutS protein are discussed with respect to two different models proposed for the role of ATP hydrolysis by MutS in DNA mismatch repair.

Physicochemical and biochemical properties of 2',5'-linked RNA and 2',5'-RNA:3',5'-RNA "hybrid" duplexes.

In recent publications, oligonucleotides joined by 2',5'-linkages were found to bind to complementary single-stranded RNA but to bind weakly, or not at all, to single-stranded DNA [e.g., P. A. Giannaris and M. J. Damha (1993) Nucleic Acids Res. 21, 4742-4749]. In this work, the biochemical and physicochemical properties of 2',5'-linked oligoribonucleotides containing mixed sequences of the four nucleobases (A, G, C, and U) were evaluated. CD spectra of RNA:2', 5'-RNA duplexes were compared with the spectra of DNA:DNA, RNA:RNA, and DNA:RNA duplexes of the same base sequence. The CD results indicated that the RNA:2',5'-RNA duplex structure more closely resembles the structure of the RNA:DNA hybrid, being more A-form than B-form in character. The melting temperature (Tm) values of the backbone-modified duplexes were compared with the Tm values of the unmodified duplexes. The order of thermal stability was RNA:RNA > DNA:DNA approximately RNA:DNA approximately DNA:RNA > RNA:2',5'-RNA > 2',5'-RNA:2',5'-RNA >> DNA:2',5'-RNA (undetected). RNA:2',5'-RNA duplexes are not substrates of the enzyme RNase H (Escherichia coli, or HIV-1 reverse transcriptase), but they can inhibit the RNase H-mediated cleavage of a natural DNA:RNA substrate. Structural models that are consistent with the selective association properties of 2',5'-linked oligonucleotides are discussed.

Sequence-specific interaction of alpha-beta-anomeric double-stranded DNA with the p50 subunit of NF kappa B: application to the decoy approach.

The potential use of alpha-beta-anomeric duplex oligonucleotides to inhibit transcription factor activity by the decoy approach is investigated in this report. Indeed, several alpha-beta-anomeric heteroduplexes display a sequence-specific interaction with the p50 subunit of the transcription factor NF kappa B. Used in a decoy approach, these duplexes interact strongly enough with this transcription factor to modulate the expression of a reporter gene, under the control of NF kappa B. However, all the alpha-beta-anomeric heteroduplexes do not interact with the p50 subunit; the sequence of the chirally natural beta-anomeric strand may explain the different recognition properties of the protein. The analysis of the appropriate beta-anomeric sequences is consistent with a preferential interaction of the p50 subunit with one strand of double-stranded DNA.

[Generic interrelations of purple bacteria in the genus Rhodopseudomonas]. / Rodstvennye vzaimootnosheniia pupurnykh bakterii roda Rhodopseudomonas.

The technique of DNA--DNA hybridization was used to study relations offween purple nonsulfur bacteria (the family Rhodospirillaceae). The level of homologies with Rhodopseudomonas sphaeroides 8259 was nearly the same for different species (8-17%) in the genus Rhodopseudomonas under the conditions optimal for hybridization. The same level of homologies was found for the DNA of Rhodospirillum rubrum, a species belonging to another genus of purple nonsulfur bacteria (13%). Rhodomicrobium vannielli was most remote from R. sphaeroides 8259 (3%). Similar results were obtained under other conditions of hybridization. The intraspecial heterogeneity of R. sphaeroides was studied in this work. The thermal stability of hybrid duplexes was analysed. The results are indicative of a considerable divergence of different R. sphaeroides strains (delta T50 = 2.1-11.6).