5-Nitro-4-(N,N-dimethylaminopropylamino)quinoline (5-nitraquine), a new DNA-affinic hypoxic cell radiosensitizer and bioreductive agent: comparison with nitracrine.

Targeting of electron-affinic radiosensitizers to DNA via noncovalent binding (e.g., intercalation) may offer the potential for increasing sensitizing efficiency. However, it has been suggested that high-affinity DNA binding may compromise sensitization by restricting the mobility of sensitizers along the DNA, and by decreasing rates of extravascular diffusion in tumors. The weak DNA intercalator nitracrine (1-NC) is a more efficient radiosensitizer than related nitroacridines with higher DNA-binding affinities (Roberts et al., Radiat. Res. 123, 153-164, 1990). The present study investigates whether electron-affinic agents of even lower DNA-binding affinity may be superior to nitroacridines. The quinoline analog of 1-NC, 5-nitraquine (5-NO), was shown to have an intrinsic association constant for calf thymus DNA in 20 mM phosphate buffer which was 12-fold lower than that of 1-NC. 5-Nitraquine was not accumulated as efficiently as 1-NC by AA8 cells, but, despite a similar one-electron reduction potential, was 2- to 3-fold more potent than 1-NC as a hypoxia-selective radiosensitizer in vitro when compared on the basis of average intracellular concentration. Thus the radiosensitizing potency of 5-NQ appears not to be compromised by its low DNA-binding affinity. The cytotoxic mechanisms of 5-NQ and 1-NC appear to be similar (hypoxia-selective formation of DNA monoadducts), but 5-NQ is 1200-fold less potent than 1-NC as a cytotoxin. Despite this advantage, 5-NQ was not active in vivo as a radiosensitizer in SCCVII tumors. This lack of activity appears to be due to its relatively high toxicity in vivo (intraperitoneal LD50 of 105 mumol kg-1 in C3H/HeN mice), high one-electron reduction potential (-286 mV), and rapid metabolism to the corresponding amine in mice. The in vitro therapeutic index (hypoxic radiosensitizing potency/aerobic cytotoxic potency) of this weak DNA binder was lower than that of the non-DNA targeted radiosensitizer misonidazole, suggesting that DNA targeting enhances cytotoxicity more than radiosensitization. Development of useful DNA-targeted radiosensitizers may require the exploitation of DNA binding modes different from those of the nitroacridines and nitroquinolines.     

Hypoxia-selective radiosensitization of mammalian cells by nitracrine, an electron-affinic DNA intercalator

The radiosensitizing ability of the 1-nitroacridine nitracrine (NC) is of interest since it is an example of a DNA intercalating agent with an electron-affinic nitro group. NC radiosensitization was evaluated in Chinese hamster ovary cell (AA8) cultures at 4 degrees C in order to suppress the rapid metabolism and potent cytotoxicity of the drug. Under hypoxic conditions, submicromolar concentrations of NC resulted in sensitization (SER = 1.6 at 1 mumol dm-3). Sensitization was also seen under aerobic conditions but a concentration more than 10-fold higher was required. In aerobic cultures NC radiosensitization was independent of whether cells were exposed before and during, or after, irradiation. Postirradiation sensitization was not observed under hypoxic conditions. The time dependence of NC uptake and the development of radiosensitization were similar (maximal at 30 min at 4 degrees C under hypoxia) suggesting that sensitization, unlike cytotoxicity, is due to unmetabolized drug. NC is about 1700 times more potent as a radiosensitizer than misonidazole. This high potency is adequately accounted for by the electron affinity of NC (E(1) value at pH7 of -275 mV versus NHE) and by its accumulation in cells to give intracellular concentrations approximately 30 times greater than in the medium. However, concentrations of free NC appear to be low in AA8 cells, presumably because of DNA binding. If radiosensitization by NC is due to bound rather than free drug, it suggests that intercalated NC can interact very efficiently with DNA target radicals. This is despite a binding ratio in the cell estimated as less than 1 NC molecule/400 base pairs under conditions providing efficient sensitization. This work suggests a new approach in the search for more effective clinical radiosensitizers, and poses questions on the means by which intercalated drugs can interact with DNA damage.     

Changes in resting membrane potential induced by active sensitization in the guinea-pig vas deferens

Smooth muscles hyperresponsiveness is a common feature in anaphylaxis and allergic diseases. The aim of the present work was to investigate whether the enhanced reactivity of sensitized guinea-pig vas deferens was associated with changes in the resting membrane potential (Er) of the smooth muscle cells. Active sensitization was performed by subcutaneous injection of egg albumen. Er was measured in vitro in isolated vas deferens with conventional KCl-filled microelectrodes. Quantification of [3H]ouabain binding sites, measurements of 86Rb efflux, and measurements of Na and K contents were also performed. In normal physiological solution, at 35 degrees C, Er was a mean of -54.1+/-0.3 mV (mean +/- SEM) in control vas deferens. Sensitization resulted in depolarizing Er by about 7 mV. In control and sensitized preparations, the 3H-ouabain binding site concentration, the efflux of 86Rb, and the K content were similar. In guinea-pig vas deferens, active sensitization induced a partial depolarization of the resting membrane potential of the smooth muscle cells, which did not result from a downregulation of Na+ -K+ pump sites.     

Neither delta- nor lambda-tris(phenanthroline)ruthenium(II) binds to DNA by classical intercalation.

Equilibrium binding studies and viscosity experiments are described that characterize the interaction of delta- and lambda-[Ru(o-phen)3]2+ with calf thymus DNA. The mode of binding of these compounds to DNA is a matter of controversy. Both isomers of [Ru(o-phen)3]2+ were found to bind but weakly to DNA, with binding constants of 4.9 (+/- 0.3) x 10(4) M-1 and 2.8 (+/- 0.2) x 10(4) M-1 determined for the delta and lambda isomers, respectively, at 20 degrees C in a solution containing 5 mM Tris-HCl (pH 7.1) and 10 mM NaCl. We determined that the quantity delta log K/delta log [Na+] equals 1.37 and 1.24 for the delta and lambda isomers, respectively. Application of polyelectrolyte theory allows us to use these values to show quantitatively that both the delta and lambda isomers are essentially electrostatically bound to DNA. Viscosity experiments show that binding the lambda isomer does not alter the relative viscosity of DNA to any appreciable extent, while binding of the delta isomer decreases the relative viscosity of DNA. From these viscosity results, we conclude that neither isomer of [Ru(o-phen)3]2+ binds to DNA by classical intercalation.     

Ethidium ion binds more strongly to a DNA double helix with a bulged cytosine than to a regular double helix

Thermodynamic parameters for ethidium intercalation were determined for the double helices formed by the oligonucleotides dCA6G + dCT6G, which form a normal helix, and dCA3CA3G + dCT6G, which form a double helix with the middle cytosine bulged outside of the helix. Ethidium intercalation was measured by monitoring the absorbance at 260 and 283 nm as a function of temperature for a number of concentrations of ethidium. The binding to the normal helix occurs equally at all the intercalation sites, with an enthalpy of binding of -8 kcal mol-1, an entropy of binding of -6 eu, and an equilibrium constant at 25 degrees C of 2.2 X 10(4) M-1. The binding to the bulged double helix was considerably stronger and is consistent with a model in which the intercalation sites on either side of the bulged base bind 10 times stronger than the other sites. Thus, there are two strong binding sites on the perturbed helix with equilibrium constants for binding of 2 X 10(5) M-1 at 25 degrees C in addition to five normal sites. Several other binding models were tested but did not fit the data satisfactorily.     

Molecular characterization of angiotensin II type II receptors in rat pheochromocytoma cells.

The binding sites and biochemical effects of angiotensin (A) II were investigated in rat pheochromocytoma (PC12W) cells. Sarcosine1, [125I]-tyrosine4, isoleucine8-AII ([125I]-SI-AII) bound to a saturable population of sites on membranes with an equilibrium dissociation constant (Kd) of 0.4 nM and a binding site maximum of 254 fmol/mg protein. Competitive displacement of [125I]-SI-AII by agonists and antagonists elucidated a rank order of potency of AIII greater than or equal to AII greater than PD 123177 greater than AI greater than [des-Phe]AII [AII(1-7)] much greater than DuP 753. The stable guanine nucleotide analog 5'-guanylyl imidodiphosphate did not alter the binding affinity or slope of the inhibition curves for AI, AII, AIII, or AII(1-7). Treatment of PC12W cells with AII or AIII did not affect the free intracellular calcium concentration, phosphoinositide metabolism, arachidonate release, cyclic GMP, or cyclic AMP concentrations. [125I]-AII binding sites remained on the cell surface and were not internalized after 2 h at 37 degrees C. Angiotensin II did not stimulate tyrosine, serine, or threonine phosphorylation. Northern analysis of PC12W mRNA with an AT1 receptor gene probe failed to produce an RNA:DNA hybrid at low stringency. These data indicate that PC12W cells express a homogeneous population of AT2 binding sites which differ significantly from AT1 receptors in signal transduction and molecular structure. AT2 sites may act via potentially novel, biochemical pathways or, alternatively, be vestigial receptors.     

Interaction of lidocaine with the cardiac sodium channel: effects of low extracellular pH are consistent with an external blocking site

Brief extracellular application of millimolar concentrations of lidocaine affected sodium currents recorded in isolated rat ventricular myocytes in two ways: 1) a reduction of the maximum current consistent with a channel blocking action, and 2) a negative shift in the voltage dependence of inactivation consistent with an interaction with the inactivated state of the channel. Both effects occurred very rapidly (< 1 s). Decreasing extracellular pH to 6.4 increased the potency for channel block (EC50 1.8 +/- 0.2 mM at pH 7.4 and 0.8 +/- 0.1 mM at pH 6.5) and decreased the potency to shift inactivation (V(1/2) shift -42 mV by 1 mM lidocaine at pH 7.4 and -12.6 mV at pH 6.5). Channel block was slightly less at +90 mV compared to -40 mV at either pH (not statistically significant). The increase in potency for block at decreased extracellular pH, while intracellular pH is buffered, and the lack of voltage dependence of block, suggest that the charged form of lidocaine can block the channel by interacting with a site near the extracellular mouth, although alternative explanations are discussed.     

A non-calcemic Vitamin D analog modulates both nuclear and putative membranal estrogen receptors in cultured human vascular smooth muscle cells

In cultured human vascular smooth muscle cells (VSMC), estradiol-17beta (E2) induced a biphasic effect on DNA synthesis, i.e., stimulation at low concentrations and inhibition at high concentrations. Additionally, E2 increased the specific activity of creatine kinase (CK) in these cells. Observations that novel protein-bound membrane impermeant estrogenic complexes could elicit inhibition of DNA synthesis, suggested interaction via membranal binding sites. Nevertheless other effects, such as increasing CK activity were only seen with native E2 but not with E2-BSA, thus indicating that the classical nuclear receptor pathway was involved. In the present report, we confirm that human VSMC express both ERalpha and ERbeta. Further, pretreatment of cultured VSMC with the Vitamin D non-calcemic analog JK 1624 F2-2 (JKF) increased ERalpha mRNA (100-200%) but decreased ERbeta mRNA (30-40%) expression as measured by real time PCR. ERalpha protein expression assessed by Western blot analysis increased (25-50%) in parallel, whereas ERbeta protein expression declines (25-55%). Using ovalbumin bound to E2 (Ov-E2) linked to Eu (Eu-Ov-E2), to assess specific membrane binding sites, we observed that membranal binding was down regulated by JKF by 70-80%. In contrast, total cell binding of 3[H] E2, that nearly entirely represents intracellular E2 binding, was increased by 60-100% by the same Vitamin D analog. The results provide evidence that the effects of JKF on ERalpha/ERbeta as well as on membranal versus nuclear binding of estrogen are divergent and show differential modulation.     

Reactivity and inhibitor potential of hydroxycitrate isomers with citrate synthase, citrate lyase, and ATP citrate lyase.

The four isomers of hydroxycitrate have been tested as substrates and inhibitors for citrate synthase, citrate lyase, and ATP citrate lyase. None of the isomers served as a substrate for citrate synthase and they were moderate to weak inhibitors of this reaction. Of the four isomers, only (pncit)-(2S)-2-hydroxycitrate did not serve as a substrate for citrate lyase while (pncit)-(4S)-4-hydroxycitrate was the only isomer which did not serve as a substrate for ATP citrate lyase. No consistent pattern of reactivity or inhibitor potency was seen with the different isomeric hydroxycitrates. It is proposed that more than one mode of binding is possible between the isomers and the three different active sites.     

Anticooperative Binding Governs the Mechanics of Ethidium-Complexed DNA

DNA intercalators bind nucleic acids by stacking between adjacent basepairs. This causes a considerable elongation of the DNA backbone as well as untwisting of the double helix. In the past few years, single-molecule mechanical experiments have become a common tool to characterize these deformations and to quantify important parameters of the intercalation process. Parameter extraction typically relies on the neighbor-exclusion model, in which a bound intercalator prevents intercalation into adjacent sites. Here, we challenge the neighbor-exclusion model by carefully quantifying and modeling the force-extension and twisting behavior of single ethidium-complexed DNA molecules. We show that only an anticooperative ethidium binding that allows for a disfavored but nonetheless possible intercalation into nearest-neighbor sites can consistently describe the mechanical behavior of intercalator-bound DNA. At high ethidium concentrations and elevated mechanical stress, this causes an almost complete occupation of nearest-neighbor sites and almost a doubling of the DNA contour length. We furthermore show that intercalation into nearest-neighbor sites needs to be considered when estimating intercalator parameters from zero-stress elongation and twisting data. We think that the proposed anticooperative binding mechanism may also be applicable to other intercalating molecules.     

DNA melting in the presence of fluorescent intercalating oxazole yellow dyes measured with a gel-based assay

We measured the effect of the intercalating oxazole yellow DNA dye quinolinium,4-[(3-methyl-2(3H)-benzoxazolylidene)methyl]-1-[3-(trimethylammonio)propyl]-,diiodide (YO-PRO) and its homodimer (YOYO) on the melting of self-complementary DNA duplexes using a gel-based assay. The assay, which requires a self-complementary DNA sequence, is independent of the optical properties of the molecules in solution. The melting temperature of the DNA is observed to increase in direct proportion to the number of occupied intercalation sites on the DNA, irrespective of whether the dye molecules are in monomer or dimer form. The increase is approximately 2.5 degrees C for each intercalation site occupied in the presence of 38 mM [Na(+)], for dye/duplex ratios in which less than 1/5 of the available intercalation sites are occupied.     

Methyl green and its analogues bind selectively to AT-rich regions of native DNA.

Methyl green has long been used as a DNA stain in histochemistry. The sequence selective binding of the cationic triphenylmethane dyes methyl green, crystal violet and Malachite green to DNA was investigated by DNAase 1 and micrococcal nuclease footprinting. At low concentrations the ligands showed similar footprinting patterns which centred around AT-rich regions with a mild preference for hompolymeric A and T. At higher concentrations the dyes bound to almost all available DNA sites. Models, with and without intercalation are discussed to account for the specific binding.     

Photoisomerizable arylstilbazolium ligands recognize parallel and antiparallel structures of G-quadruplexes

The photoisomerization and DNA interaction studies of three arylstilbazolium derivatives with various samples of nucleic acids (duplexes, triplexes and tetraplexes) are reported. The equilibrium dialysis study revealed high binding affinities of ligands to tetraplex structures. The quadruplex-binding affinity could be switched by light, e.g., the E,E and E,Z isomers of 1,4-bis(vinylquinolinium)benzene (1) interacted with parallel and antiparallel tetraplexes exhibiting different binding selectivity. The E,Z-1 showed higher binding preference for c-myc DNA (a propeller-type quadruplex), whereas the E,E-1 favorably interacted with telomeric DNA (a basket-type quadruplex). The presence of quadruplex DNA hampered photoisomerization of quadruplex-bound ligand.     

86 Characterization and differentiation of binding modes of water-soluble porphyrins at complexation with DNA

The influence of water-soluble cationic meso-tetra-(4?N-oxyethylpyridyl)porphyrin (H₂TOEPyP4) and it’s metallocomplexes with Ni, Cu, Co, and Zn on hydrodynamic and spectral behavior of DNA solutions has been studied by UV/Vis absorption and viscosity measurement. It was shown that the presence of planar porphyrins such as H₂TOEPyP4, NiTOEPyP4, and СuTOEPyP4 leads to an increase in viscosity at relatively small concentrations, and then decrease to stable values. Such behavior is explained by intercalation of these porphyrins in DNA structure because the intercalation mode involves the insertion of a planar molecule between DNA base pairs which results in a decrease in the DNA helical twist and lengthening of the DNA. Further decrease of viscosity is explained by the saturation intercalation sites and occurs outside the binding mode. But, in the case of porphyrins with axial ligands such as CoTOEPyP4 and ZnTOEPyP4, the hydrodynamic parameters decrease, which is explained by self-stacking of these porphyrins in DNA surface. This data are proved by spectral measurements. The results obtained from titration experiments were used for calculation of binding parameters: the binding constant K _b and the number of binding sites per base pair n. Obtained data reveal that K _b varies between 3.4 and 5.4?×?10⁶?M^?1 for a planar porphyrins, a range typical for intercalation mode interactions, and 5.6?×?10⁵?M^?1 and 1.8?×?10⁶?M^?1 for axial porphyrins. In addition, the exclusion parameter n also testifies that at intercalation, (n～2) the adjacent base pairs are removed to place the planar molecules, and for outside binders to pack on the surface needs too few places (n～0.5–1). It is apparent that the binding is somewhat stronger at intercalation. The viscometric and spectrophotometric measurements are in good agreement.     

Asymmetric chloronicotinyl insecticide, 1-[1-(6-chloro-3-pyridyl)ethyl]-2-nitroiminoimidazolidine: preparation,resolution and biological activities toward insects and their nerve preparations

The asymmetric chloronicotinyl insecticide, 1-[1-(6-chloro-3-pyridyl)ethyl]-2-nitroiminoimidazolidine, was prepared, and the absolute configurations of the enantiomers were determined by an X-ray analysis. The insecticidal activity against the housefly measured with metabolic inhibitors showed the (S) enantiomer to be slightly more active than the (R) isomer. Electrophysiological measurements on the American cockroach central nerve cord showed the compounds to elicite the impulses and subsequently blocked them. The neuroblocking potency of the (S) isomer was 5.9 microM, while that of the (R) isomer was as high as 73 microM. The molar concentrations required for 50% inhibition of the specific binding of [3H]imidacloprid to the housefly head membrane preparation were respectively 0.19 microM and 0.95 microM for the (S) and (R) isomers. This enatioselectivity ratio was smaller than 35 for nicotine isomers but greater than 2 for epibatidine isomers.     

X-ray diffraction and infrared circular dichroism of DNA-violamycin B1 complexes

X-ray diffraction and infrared linear dichroism of oriented samples of DNA-violamycin B1 complexes have been studied at different antibiotic/DNA phosphate ratios (r) as a function of relative humidity. Violamycin B1 binds to DNA according to the intercalation as well as to the outside binding model. At low r values, where the intercalation predominates the unwinding angle of DNA helix is between 6 degrees and 12 degrees per intercalation site as followed from the dependence of the pitch of helix versus r. At r greater than or equal to 0.17 the intercalation sites are saturated and the outside binding becomes prevalent; however the violamycin B1 chromophore is still oriented in the plane of DNA bases. Conformational mobility of DNA in the violamycin B1 complexes is largely inhibited compared with pure DNA, but it is higher than that of the daunomycin complexes. At least 30% of DNA in violamycin complexes has A conformation at the medium humidities as followed by IR linear dichroism. In the case of x-ray diffraction the A conformation was not detected. The distance between DNA molecules in the complex is found to be 23.2 A, that is 2 A less than in pure DNA at the same conditions and it does not depend upon r.     

Different Binding Mode in AT and GC Sequences for Unfused-Aromatic Dications

Abstract

We have previously synthesized a 2,5-diphenylfuranamidine dication (4) and presented evidence that this compound binds to AT sequences in DNA by a minor-groove interaction mode but binds to GC sequences by intercalation (1,2). To probe these sequence-dependent binding modes in more detail, and particularly to obtain additional evidence for the binding mode in GC rich sequences, we have synthesized and studied the DNA complexes of 1–3 which have the furan ring of 4 replaced by 2,6-substituted pyridine (1), pyrimidine (2), or triazine (3) ring systems. The three compounds with a six-membered central ring system bind to AT DNA sequences more weakly than the furan compound, but retain the minor-groove binding mode. The pyridine and pyrimidine derivatives bind to GC sequences of DNA more strongly than the furan, but the triazine derivative binds more weakly. The aromatic proton signals of 1–3, as previously observed with 4 shift upfield by approximately 0.5 ppm or greater on complex formation with polyd(G-C)₂. This and other spectroscopic as well as viscosity and kinetics results indicate that 1–4 bind to GC sites in DNA by intercalation. A nonclassical intercalation model, with the twisted-unfused, aromatic ring system intercalated into an intercalation site of matching structure can explain all of our and the literature results for the GC binding mode of these unfused, aromatic compounds.