Drug residue formation from ronidazole, a 5-nitroimidazole. III. Studies on the mechanism of protein alkylation in vitro

Ronidazole (1-methyl-5-nitroimidazole-2-methanol carbamate) is reductively metabolized by liver microsomal and purified NADPH-cytochrome P-450 reductase preparations to reactive metabolites that covalently bind to tissue proteins. Kinetic experiments and studies employing immobilized cysteine or blocked cysteine thiols have shown that the principal targets of protein alkylation ara cysteine thiols. Furthermore, ronidazole specifically radiolabelled with 14C in the 4,5-ring, N-methyl or 2-methylene positions give rise to equivalent apparent covalent binding suggesting that the imidazole nucleus is retained in the bound residue. In contrast, the carbonyl-14C-labeled ronidazole gives approx. 6--15-fold less apparent covalent binding indicating that the carbamoyl group is lost during the reaction leading to the covalently bound metabolite. The conversion of ronidazole to reactive metabolite(s) is quantitative and reflects the amazing efficiency by which this compound is activated by microsomal enzymes. However, only about 5% of this metabolite can be accounted for as protein-bound products under the conditions employed in these studies. Consequently, approx. 95% of the reactive ronidazole metabolite(s) can react with other constituents in the reaction media such as other thiols or water. Based on these results, a mechanism is proposed for the metabolic activation of ronidazole.     

Studies of the binding of Escherichia coli RNA polymerase to DNA. V. T7 RNA chain initiation by enzyme-DNA complexes

Initiation of T7 RNA chains by Escherichia coli RNA polymerase-T7 DNA complexes has been followed using incorporation of λ-³²P-labeled ATP and GTP to determine the relation between the enzyme binding sites and RNA chain initiation sites on the T7 genome. If the period of RNA synthesis is limited to less than two minutes, the stoichiometry of RNA chain initiation can be measured in the absence of chain termination and re-initiation. About 70% of the RNA polymerase holoenzyme molecules in current enzyme preparations are able to rapidly initiate a T7 RNA chain. The ratio of ATP- to GTP-initiated T7 RNA chains is not altered by variations in the number of enzyme molecules added per DNA, nor by alterations in the ionic conditions employed for RNA synthesis. This suggests that RNA chain initiation sites are chosen randomly through binding of RNA polymerase to tight (class A) binding sites on T7 DNA.     

Role of curved DNA in binding of Escherichia coli RNA polymerase to promoters.

The ability of curved DNA upstream of the -35 region to affect the interaction of Escherichia coli RNA polymerase and promoter DNA was examined through the use of hybrid promoters. These promoters were constructed by substituting the curved DNA from two Bacillus subtilis bacteriophage SP82 promoters for the comparable DNA of the bacteriophage lambda promoters lambda pR and lambda pL. The SP82 promoters possessed intrinsic DNA curvature upstream of their -35 regions, as characterized by runs of adenines in phase with the helical repeat. In vitro, the relative affinities of purified sigma 70-RNA polymerase for the promoters were determined in a competition binding assay. Hybrid promoters derived from lambda pR that contained curved DNA were bound by E. coli RNA polymerase more efficiently than was the original lambda pR. Binding of E. coli RNA polymerase to these hybrid promoters was favored on superhelical DNA templates according to gel retardation analysis. Both the supercoiled and relaxed forms of the hybrid lambda pL series were better competitors for E. coli RNA polymerase binding than was the original lambda pL. The results of DNase I footprinting analysis provided evidence for the wrapping of the upstream curved DNA of the hybrid lambda pR promoters around the E. coli RNA polymerase in a tight, nucleosomal-like fashion. The tight wrapping of the upstream DNA around the polymerase may facilitate the subsequent steps of DNA untwisting and strand separation.     

On the binding of tRNA to Escherichia coli RNA polymerase.

The fixation of tRNA to Escherichia coli RNA polymerase has been investigated. Bound and free tRNA have been separated and quantified after filtration through cellulose nitrate filters, centrifugation or sucrose gradients or electrophoresis in polyacrylamide gels. We detect no differences between the fixation of E. coli fMet-tRNAfMet, Met-tRNAmMet or uncharged unfractionated tRNA to RNA polymerase. Tight complexes, with a long residence time, are formed between core enzyme and tRNA with a dissociation constant of less than 1 nM. Complexes exist between tRNA and both monomer and dimer forms of the core enzyme. In the monomer complex, one tRNA is bound per alpha 2 beta beta' unit, whereas in the dimer complex only 0.5 tRNA molecule is fixed per alpha 2 beta beta' unit. In contrast to the core enzyme, very little tRNA fixes tightly to the holoenzyme at salt concentrations greater than 80 mM. At lower salt concentrations tRNA fixation results in a loss of sigma subunit from the holo enzyme to the resulting core enzyme where it binds tightly. DNA fixation reduces the binding of tRNA to RNA polymerase and tRNA fixation reduces the binding of DNA. However, binding of DNA to polymerase is not competitive with binding of tRNA, and ternary complexes between RNA polymerase, DNA and tRNA are shown to exist. Our results are discussed in relation to other studies concerning the effects of tRNA upon RNA polymerase.     

Protein . nucleic-acid reaction kinetics. Theoretical analysis of the binding reaction between DNA and RNA polymerase.

This paper presents methods developed in order to analyze experimental results concerning the binding of Escherichia coli DNA-dependent RNA polymerase to DNA at high and at low DNA concentrations, using the filter retention assay. The basis hypotheses, under which the mathematical expressions for describing the kinetics of binding are derived, are as follows. (a) At low DNA concentration: equivalence and independence of the specific binding sites; first-order dependence of the binding reaction on both DNA and protein concentration. (b) At high DNA concentration: equivalence and independence of the non-specific binding sites; no direct transfer or one-dimensional sliding of the protein along the DNA. Comparison between theoretical predictions and experimental results at high DNA concentration will allow one to determine the relative value of the rates of binding of RNA polymerase to different promoters (between 1 and 2 in T5 DNA). Binding experiments performed at low DNA concentration are reported in this paper: these results and the analysis which is reported allow one to determine the value of the rate constant of formation of non-filterable complexes for the system fd DNA (replicative form) . RNA-polymerase (kappa a = 3.3 X 10(8) M-1 s-1 in 0.1 M NaCl, 0.01 M MgCl2).     

Solubilization and hydrophobic immobilization assay of a cAMP binding protein from Dictyostelium discoideum plasma membranes

A cAMP binding site present on isolated plasma membranes of aggregation-competent $\text{D.}\text{discoideum}$ cells has been solubilized with the nonionic detergent Emulphogene BC-720. An assay has been developed based on the principle of hydrophobic chromatography, in which the detergent solubilized cAMP binding protein is immobilized on alkyl-agarose beads at low detergent concentration. This allows the necessary rapid separation of bound and free [³H]-cAMP by filtration of the beads. The kinetics and nucleotide specificity of the detergent solubilized cAMP binding protein are comparable to those of the cAMP chemotactic receptor on intact cells and plasma membranes. The alkyl-agarose bead assay may have general utility for the assay of detergent solubilized membrane receptors.     

An automated continuous-flow dynamic dialysis technique for investigating protein-ligand binding

An automated, continuous-flow dynamic dialysis technique has been developed to investigate protein-ligand binding. The method depends on a comparison of the diffusion of the low molecular mass ligand, in the presence and absence of protein, through a semipermeable membrane. The ligand passes from the sample compartment of a dialysis cell into the sink compartment through which a constant flow of eluting buffer is maintained. Digitized spectrophotometric determinations of the ligand concentration in the eluting buffer at successive, equally spaced time intervals, punched onto paper tape, provide the primary data (normally about 1000 data points). A mathematical treatment of the data based on a model of the diffusion system, whereby the protein-ligand binding isotherm may be evaluated, is discussed. The validity of the method is demonstrated from studies of the binding of phenol red to bovine serum albumin (BSA) at 15, 20, and 25°C. The method yields a large number of points on the binding isotherm (usually several hundred) which, in terms of a Scatchard model, provide values for the number of binding sites on the BSA molecule and binding constants for the phenol red-BSA interaction. The results obtained are consistent with values reported in the chemical literature but which are based on much scantier data.     

Studies on the mechanism of enzymatic DNA elongation by Escherichia coli DNA polymerase II.

The mechanism of enzymatic elongation by Escherichia coli DNA polymerase II of a DNA primer, which is annealed to a unique position on the bacteriophage fd viral DNA, has been studied. The enzyme is found to dissociate from the substrate at specific positions on the genome which act as “barriers” to further primer extension. It is believed these are sites of secondary structure in the DNA. When the template is complexed with E. coli DNA binding protein many of these barriers are eliminated and the enzyme remains associated with the same primer-template molecule during extensive intervals of DNA synthesis. Despite the presence of E. coli DNA binding protein, at least one barrier on the fd genome remains rate-limiting to chain extension and disturbs the otherwise processive mechanism of DNA synthesis. This barrier is overcome by increasing the concentration of enzyme.In contrast, it is found that DNA polymerase I is not rate-limited by structural barriers in the template, however, it exhibits a non-processive mechanism of elongation.These findings provide a framework for understanding the necessity for participation of proteins other than a DNA polymerase in chain extension during chromosomal replication.     

Homologous RNA polymerase binding to Escherichia coli DNA: a study of the distribution of stable binding sites.

The number and the distribution of the sites of Escherichia coli DNA that form stable complexes with the homologous RNA polymerase (class A sites according to Hinkle and Chamberlin [3]) have been investigated. Almost all the DNA can bind RNA polymerase, even when fragmented at short (undergenic) size; this general non-promoter-specific binding is highly labile and is not temperature-dependent. The range of RNA polymerase/DNA ratios that give rise to the stable temperature-dependent complexes was examined. The amount and the distribution of class A complexes were studied analysing the dissociation of complexes formed by RNA polymerase on DNA fragments of various length. The E. coli genome appears to form 3.8 X 10(3) stable complexes; the majority of these complexes shows a short-range distribution (800-1200 base pairs). The rest is more widely spaced (1200-6000 base pairs).     

Influence of DNA end structure on the mechanism of initiation of DNA unwinding by the Escherichia coli RecBCD and RecBC helicases

Escherichiacoli RecBCD is a bipolar DNA helicase possessing two motor subunits (RecB, a 3′-to-5′ translocase, and RecD, a 5′-to-3′ translocase) that is involved in the major pathway of recombinational repair. Previous studies indicated that the minimal kinetic mechanism needed to describe the ATP-dependent unwinding of blunt-ended DNA by RecBCD in vitro is a sequential n-step mechanism with two to three additional kinetic steps prior to initiating DNA unwinding. Since RecBCD can “melt out” ∼ 6 bp upon binding to the end of a blunt-ended DNA duplex in a Mg²⁺-dependent but ATP-independent reaction, we investigated the effects of noncomplementary single-stranded (ss) DNA tails [3′-(dT)₆ and 5′-(dT)₆ or 5′-(dT)₁₀] on the mechanism of RecBCD and RecBC unwinding of duplex DNA using rapid kinetic methods. As with blunt-ended DNA, RecBCD unwinding of DNA possessing 3′-(dT)₆ and 5′-(dT)₆ noncomplementary ssDNA tails is well described by a sequential n-step mechanism with the same unwinding rate (mk_U = 774 ± 16 bp s^− 1) and kinetic step size (m = 3.3 ± 1.3 bp), yet two to three additional kinetic steps are still required prior to initiation of DNA unwinding (k_C = 45 ± 2 s^− 1). However, when the noncomplementary 5′ ssDNA tail is extended to 10 nt [5′-(dT)₁₀ and 3′-(dT)₆], the DNA end structure for which RecBCD displays optimal binding affinity, the additional kinetic steps are no longer needed, although a slightly slower unwinding rate (mk_U = 538 ± 24 bp s^− 1) is observed with a similar kinetic step size (m = 3.9 ± 0.5 bp). The RecBC DNA helicase (without the RecD subunit) does not initiate unwinding efficiently from a blunt DNA end. However, RecBC does initiate well from a DNA end possessing noncomplementary twin 5′-(dT)₆ and 3′-(dT)₆ tails, and unwinding can be described by a simple uniform n-step sequential scheme, without the need for the additional k_C initiation steps, with a similar kinetic step size (m = 4.4 ± 1.7 bp) and unwinding rate (mk_obs = 396 ± 15 bp s^− 1). These results suggest that the additional kinetic steps with rate constant k_C required for RecBCD to initiate unwinding of blunt-ended and twin (dT)₆-tailed DNA reflect processes needed to engage the RecD motor with the 5′ ssDNA.     

Doxorubicin hinders DNA condensation promoted by the protein bovine serum albumin (BSA)

In this work, we have studied the interaction between the anticancer drug doxorubicin (doxo) and condensed DNA, using optical tweezers. To perform this task, we use the protein bovine serum albumin (BSA) in the working buffer to mimic two key conditions present in the real intracellular environment: the condensed state of the DNA and the abundant presence of charged macromolecules in the surrounding medium. In particular, we have found that, when doxo is previously intercalated in disperse DNA, the drug hinders the DNA condensation process upon the addition of BSA in the buffer. On the other hand, when bare DNA is firstly condensed by BSA, doxo is capable to intercalate and to unfold the DNA condensates at relatively high concentrations. In addition, a specific interaction between BSA and doxo was verified, which significantly changes the chemical equilibrium of the DNA–doxo interaction. Finally, the presence of BSA in the buffer stabilizes the double‐helix structure of the DNA–doxo complexes, preventing partial DNA denaturation induced by the stretching forces.     

Ganglioside headgroup disorder as a sequel to lectin binding

Evidence is presented that gangliosides show a measurable tendency to exist in clusters in lipid bilayer systems; and that these clusters are subject to disruption by a lectin binding event.     

A simple hydrogenase-linked assay for ferredoxin and flavodoxin.

Ferredoxin or flavodoxin mediates electron flow from H₂-hydrogenase to metronidazole[1-(2-hydroxyethyl)-2-methyl-5-nitroimidazole] to cause the reduction of the latter compound. The reduction of metronidazole in solution is irreversible because the reduced compound further decomposes. Since metronidazole loses its absorption peak at 320 nm upon reduction, the rate of reduction can be monitored spectrophotometrically. When a solution of metronidazole at 0.1 to 0.5 mm is supplemented with ferredoxin- andflavodoxin-free hydrogenase and placed under H₂, the rate of metronidazole reduction is proportional to the amount of ferredoxin or flavodoxin added. This forms the basis for an assay that can measure 10 to 1000 ng of ferredoxin or 100–1000 ng of flavodoxin/ml of assay mixture.