Pt(2+)-containing derivatives of oligodeoxyribonucleotides were used to evaluate the ligand affinity to the template sites of Klenow fragment of DNA polymerase I from E. coli and DNA polymerase alpha from human placenta. The values of Kd and Gibb's energy (delta G degree) for the complexes of oligodeoxyribonucleotides and their derivatives with the template sites of these enzymes were determined from the effects protecting the enzyme from inactivation by Pt(2+)-containing oligonucleotides. Kd and delta G degree values of the complexes made by DNA polymerases and orthophosphate, triethylphosphate, d(pC)n, d(pT)n, d(pG)n, d(pA)n (where n = 1-25), heterooligonucleotides of various length and structure, and oligothymidylates with partially and completely ethylated internucleotide phosphates were evaluated. The obtained data enabled us to suggest 19-20 mononucleotide units of the template to interact with the protein. Only one template internucleotide phosphate forms a Me(2+)-dependent electrostatic contact (delta G = -1.1...-1.7 kcal/mol) and a hydrogen bond (delta G = -4.4...-4.9 kcal/mol) with the enzyme. It is likely that the mononucleoside units of the template form hydrophobic contacts with the enzymes. The efficiency of such interaction changes with the hydrophobicity of the bases: C less than T less than G approximately A. For both homo- and heterooligonucleotides the contributions of nucleoside units to the affinity of the templates to the enzymes is due to the complementary interactions with the primers. A hypothetical model for the template-primer interaction with DNA polymerases is suggested.
The values of K d and Gibbs energy (ΔG°) have been measured for complexes of the template site of DNA polymerase I Klenow fragment with the homo‐oligonucleotides d(pC) n , d(pT) n , d(pG) n and d(pA) n and hetero‐oligonucleotides of various structures and lengths. These parameters were evaluated from the protective effect of the oligonucleotide on enzyme inactivation by the affinity reagents d(Tp)2C[Pt2+(NH3)2OH](pT)7 and d[(Tp)2C(Pt2+(NH3)2OH)p]3T of the template site. The present results and previously reported data [(1985) Biorg. Khim. 13, 357–369] indicate that the nucleoside components of the template form complexes as a result of their hydrophobic interactions with the enzyme. Only one template internucleotide phosphate forms an Me2+‐dependent electrostatic contact and a hydrogen bond with the enzyme. The 19–20‐nucleotide fragments of the template appear to interact with the protein molecule.
Strains of Mycobacterium smegmatis, a mycobacterium which shares genetic sequences, grows more rapidly, and is nonpathogenic in man as compared with Mycobacterium tuberculosis, were utilized for the initial development of new antimycobacterial therapy. (3, 4). Drug resistance and multidrug resistance in tuberculosis originates in spontaneous mutations, which occur at predictable rates in tubercle bacilli. The mutations are not linked, and the rise of drug-resistant organisms is the result of these preexisting mutations rather than a result of drug treatment or another mechanism not yet established or understood (5). Thus, the emergence of drug resistance is the direct result of the survival of random preexisting mutations and the selection of the mutations-carrying organisms, due to the killing of drug-sensitive organisms by effective drugs.To assess the potential efficacy of modified antisense oligonucleotides against mycobacteria and drug-resistant mycobacteria in particular, we have utilized the bacterium Mycobacterium smegmatis, which is closely related to M. tuberculosis and is predictive as to the clinical outcome after a drug is shown to be effective in an in vitro screening system (6-9). Justification for the use of M. smegmatis as a common and acceptable model for the development of a therapeutic modality against drug-resistant tuberculosis is due to the following well-acknowledged factors: (i) M
The use of various nanoparticles is a promising way to solve the current problem of drug delivery in medicine and biology. Nanocomposites consisting of titanium dioxide and oligonucleotides noncovalently attached to nanoparticles through the polylysine linker (TiO2 x PL-DNA) have been designed to deliver of DNA fragments into cells. Three forms of TiO2 nanoparticles (amorphous, anatase, and brookite) were used for construction of nanocomposites. The size, morphology, and chemical composition of TiO2 nanoparticles and TiO2 x PL-DNA nanocomposites were characterized. DNA fragments in the proposed nanocomposites were shown to retain their ability to form complementary complexes. TiO2 x PL-DNA nanocomposites independently on the form of nanoparticles were shown by confocal microscopy to penetrate into HeLa cells without any transfection agents and physical impact. The presented type of nanocomposites can be applied in the thriving technology of drug delivery to achieve high therapeutic and biological efficacy.
Nanoparticles are used to solve the current drug delivery problem. We present a high-performance method for efficient and selective action on nucleic acid target in cells using unique TiO2·PL-DNA nanocomposites (polylysine-containing DNA fragments noncovalently immobilized onto TiO2 nanoparticles capable of transferring DNA). These nanocomposites were used for inhibition of human influenza A (H3N2) virus replication in infected MDCK cells. They showed a low toxicity (TC50 ≈ 1800 μg/ml) and a high antiviral activity (>99.9% inhibition of the virus replication). The specificity factor (antisense effect) appeared to depend on the delivery system of DNA fragments. This factor for nanocomposites is ten-times higher than for DNA in the presence of lipofectamine. IC50 for nanocomposites was estimated to be 1.5 μg/ml (30 nM for DNA), so its selectivity index was calculated as ~1200. Thus, the proposed nanocomposites are prospective for therapeutic application.
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