The effect of template secondary structure on vaccinia DNA polymerase.

Vaccinia virus DNA polymerase will utilize a substrate consisting of phi X174 DNA primed with a strand of a unique restriction fragment, but the reaction is inefficient. Examination of the reaction products by alkaline agarose gel electrophoresis revealed a few discrete fragments, each corresponding to an extended primer strand. This result implies that specific barriers exist on the phi X174 template which impede, but do not completely halt, the progress of the enzyme. Only a few per cent of the template molecules were completely copied. Similar findings were reported by Sherman and Gefter using Escherichia coli DNA polymerase II and fd DNA (J. Mol. Biol. (1976) 103, 61-76). Several observations suggest that the barriers are regions of template secondary structure. Some barriers are more effective than others, and they increase in both effectiveness and number as the temperature is decreased. The same barriers are observed with T4 DNA polymerase, but none are detected with E. coli DNA polymerase I. Finally, the major barriers are located in regions of the phi X174 sequence known to contain hairpin structures of relatively high stability. The exact stopping point of one of the major barriers is within the duplex stem of a hairpin structure. These results show that DNA polymerases are a useful probe of the secondary structure of a single-stranded DNA.     

Influence of template inactivators on the binding of DNA polymerase to DNA

The agents daunomycin, ethidium bromide, distamycin A and cytochrome c inhibit DNA dependent DNA polymerase I (E. coli) reaction competitively to DNA. The influence of these template inactivators on the binding of DNA polymerase to native as well as denatured DNA has been determined by affinity chromatography. Cytochrome c blocks the binding of the enzyme to double-stranded and to single-stranded DNA Sepharose. In contrast to these results daunomycin, ethidium bromide or distamycin A reduce the binding affinity only with denatured DNA Sepharose as matrix. These data are discussed with respect to the modification by template inactivators of the affinity of DNA to the different binding sites of the DNA polymerase.     

Supercoiling-dependent site-specific binding of HU to naked Mu DNA.

Using HU chemical nucleases to probe HU-DNA interactions, we report here for the first time site-specific binding of HU to naked DNA. An unique feature of this interaction is the absolute requirement for negative DNA supercoiling for detectable levels of site-specific DNA binding. The HU binding site is the Mu spacer between the L1 and L2 transposase binding sites. Our results suggest recognition of an altered DNA structure which is induced by DNA supercoiling. We propose that recruitment of HU to this naked DNA site induces the DNA bending required for productive synapsis and transpososome assembly. Implications of HU as a supercoiling sensor with a potential in vivo regulatory role are discussed. Finally, using HU nucleases we have also shown that non-specific DNA binding by HU is stimulated by increasing levels of supercoiling.     

Systemic administration of naked DNA: gene transfer to skeletal muscle

Skeletal muscle is a promising target tissue for the gene therapy of both muscle and non-muscle disorders. Gene transfer into muscle tissue can produce a variety of physiologically active proteins and may ultimately be applied to the treatment of many diseases. A variety of methods have been studied to transfer genes into skeletal muscle, including viral and non-viral vectors. In this review, we discuss recent developments in the non-viral delivery of genes to muscles.     

Anti-tumor effect of intravenous TNFalpha gene delivery naked plasmid DNA using a hydrodynamics-based procedure

High levels of foreign gene expression in mouse hepatocytes can be achieved by the rapid injection of a large volume of naked plasmid (pDNA) into animals via the tail vein, the so-called hydrodynamics-based procedure. In this study, we evaluated the efficacy of hydrodynamics-based tumor necrosis factor alpha (TNFalpha) transfer for tumor treatment, in which the naked pDNA encoding TNFalpha was administered into the tail vein following an intravenous injection of B16 melanoma cells. The mice treated with TNFalpha-expressing pDNA displayed a profound reduction in lung metastasis. These results suggest that the hydrodynamics-based transfer of naked pDNA is a convenient and efficient method of TNFalpha gene therapy against metastatic tumors.     

Reiterative template switching: the effect of single-strand homopolymeric DNA on non-template-directed nucleotide addition by DNA polymerase

Template switching occurs when DNA polymerase juxtaposes two discontinuous DNA molecules with 3'-terminally complementary ends generated through non-template-directed nucleotide addition. We examined whether juxtaposition of homopolymeric single-stranded oligonucleotides affects non-templated addition. We hypothesized that if DNA polymerase first juxtaposed the two substrates, then the non-template-directed nucleotide addition of any deoxynucleotide would decrease in the presence of its non-complementary template. For dATP, product formation was unaffected by non-complementary substrates. In contrast, dCTP and dGTP incorporation decreased to varying degrees while dTTP incorporation increased in the presence of oligodeoxythymidine but decreased for other non-complementary homopolymers. Interestingly, the presence of complementary templates strongly influenced the formation of highly periodic products indicative of reiterative template switching. Transient template synapsis was observed and found to be dependent on the non-templated sequence added: 3-4 A:T or 1-2 G:C base pairs were needed for stable synapsis, suggesting that base pairing plays a more important role in the active site of the enzyme than previously thought.     

The ionic strength effect on the DNA complexation by DOPC - gemini surfactants liposomes

Liposome dispersions obtained from the mixture of gemini surfactants of the type alkane-α,ω-diyl-bis(alkyldimethylammonium bromide) and helper lipid DOPC create complexes with DNA showing a regular inner microstructure, identified by small angle X-ray diffraction as condensed lamellar phase (L_α^c). In addition to the L_α^c phase, a coexisting lamellar phase L_B was also identified in the complexes formed, with periodicities in the range ~ 8.8-5.7 nm, at ionic strengths corresponding to 50-200 mM NaCl. The periodicities of L_B phase did not correspond to those identified in liposome dispersion without DNA using small angle neutron scattering. The observed phase separation is shown to depend on the interplay between the surface charge density of cationic liposomes, ionic strength and method of complex preparation. The effect of ionic strength on complex formation was studied by isothermal titration calorimetry and zeta potential measurements. High ionic strength reduces the fraction of bound DNA in the complexes, and the isoelectric point is attained at a ratio of DNA/gemini surfactant which is lower than the one that can be estimated by calculation based on nominal charges of CLs and DNA.     

The statistical correlation of nucleotides in protein-coding DNA sequences

The statistical correlation of nucleotides in a DNA sequence is described by a set of redundanciesD ₁,D ₂,D ₃,... By calculation of {D _n} of 2341 coding regions of nucleic acid sequences it is demonstrated that about 2/3 of sequences has correlation length ≤2, 10% of sequences—correlation with 3-periodicity and others—long range aperiodic correlations. The implications of the results from the interactions of random mutation and natural selection are discussed briefly. Project supported by National Science Foundation of China.     

Binding of positive charged ligands to DNA. The effect of ionic strength, charge and size of the ligand

The electrostatic interaction of extended cationic ligands with DNA has been considered on the basis of the analytical solution of a simplified Poisson--Boltzmann equation for the charged polyion cylinder. The control numerical solution of rigorous Poisson--Boltzmann equation shows that the assumption about the absence of coions in the vicinity of the highly charged polyion cylinder does not significantly influence the accuracy of solution and DNA electrostatic free energy evaluation. It was found that the basic contribution to the free energy of electrostatic ligand-DNA interaction is the mixing entropy change due to release of counterions from the vicinity of DNA. The equation for the dependence of the ligand to DNA binding constant K upon ionic strength c has been derived without introduction of any empirical parameters. This equation is consistent with the experimental data and can be used for the determination of a number of ligand--DNA ionic contacts in a wide range of salt concentrations. The main consequences of Manning and Record et al. theories can be considered as limiting cases of the theory presented. In particular the equation d(lnK)/d(lnc) = -0.88 N by Record et al. has a restricted range of application and it can be used only for a relative approximate estimation of the number of electrostatic bonds in ligand-DNA complexes. The analysis of electrostatic interaction of DNA with ligands which neutralize only part of phosphate groups in the binding site of DNA was also performed.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of bases non-complementary to the template on the efficacy of primer interaction with the Klenow fragment of DNA polymerase I from Escherichia coli

The comparison of the Km and Vmax values for the primers was carried out. The primers were either completely complementary to the template or contained non-complementary bases at different positions with respect to the 3'-end. The addition of NaF, selectively inhibiting 3'----5'-exonuclease activity of the enzyme, was shown to result in the increase of Vmax values by 10% and 30% for complementary and partially complementary primers, respectively, Km values of the latters being unchanged. Km values for d[(pT)10pC] is about 146-fold greater than that for d[(pT)11]. Km values for d[(pT)7pC(pT)2] (20 microM) and d[[(pT)2pC]3pT] (20 microM); d[(pT)4pC(pT)5] (5.0 microM); d[(pC)(pT)7] (1.3 microM) and d[(pT)2pC(pT)7] (1.2 microM) are comparable with those for d[(pT)2] (22 microM), d[(pT)5] (4.1 microM) and d[(pT)7] (1.2 microM), respectively, but not with the decathymidylate d[(pT)10] (0.2 microM). We suggest that it is not the length of the primers but the number of bases in the fragment beginning with the first nucleotide from the 3'-end and ending in the non-complementary base, that determines the efficiency of interaction of the primers containing non-complementary bases with the enzyme. The addition of one link to d(pT)n (n less than or equal to 10) resulted in a 1.8-fold increase in the affinity. When 11 less than n less than 25 the affinity is decreased so that d(pT)22-23 have minimal affinity to the enzyme. The primers containing more than 50 units were found to have about the same affinity (calculated on base concentration) as d(pT)10-11.