Cooperative binding of adenosine by polyuridylic acid: a further analysis

The dialysis data of Huang and Ts'o for the cooperative binding of adensine to polyuridylic acid are analyzed here using a grand-partition function Ising model method similar to that originally employed for polyelectrolytes by Rice and Nagasawa. An appropriate modification permitting the treatment of the sliding degeneracy of the two polyuridylic acid strands is also included. In addition to the previously estimated stacking energy of about ?6 kcal/mole one also obtains the free energy change F? for the transfer of a single adenosine molecule from a fixed site in solution to a fixed site on the polyuridylic acid. This binding energy falls in the range F? = ?140 to +620 cal/mole, indicating that binding in the 1:2 (purine: pyrimidine) complex is either very weak or repulsive. The absence of any comparable cooperative stacking of adenosines in solution at the same concentration together with the likely repulsive character of the binding implies that the stacking energy must contain a significant contribution from other processes than simple stacking of adenosines. A generalization of the theory to treat multicomponent binding and longer-range interactions is effected, and the form applicable to simultaneous binding of both adenosine and guanosine by polyuridylic acid is presented.     

The interaction of aflatoxin B1 with polynucleotides and its effect on ribonucleic acid polymerase

1. The interaction of aflatoxin B(1) with different polynucleotides was studied spectrophotometrically. Equations were derived that enable the degree of binding to be determined without first determining the extinction coefficient of the bound form. 2. The interaction with calf thymus DNA obeys first-order relationships with an association constant of 0.40mm(-1), but there is some evidence for a secondary binding process from results obtained at 390nm. 3. The spectral shifts decreased in the order polyadenylic acid+polyuridylic acid>DNA>polyadenylic acid>polyadenylic acid+polyinosinic acid. Polycytidylic acid, polyuridylic acid, polyinosinic acid (both single- and triple-stranded), AMP, CMP, GMP and UMP did not interact with aflatoxin. It was concluded that there is a requirement for the amino group of adenine (or possibly guanine) for binding of aflatoxin to polynucleotides to occur. 4. Binding is reversed by increasing ionic strength, and by Mn(2+) and Mg(2+) in the concentration range studied (0-5mm). The effect of the Mn(2+) or Mg(2+) was far greater than would be expected on the basis of their ionic strength. With both the bivalent cations and sodium chloride the reversal is greatest with double-stranded polynucleotides. 5. Inhibition in vitro of the DNA-dependent RNA polymerase of Escherichia coli by aflatoxin B(1) was detected only in the absence of Mg(2+) and at concentrations of Mn(2+) below the optimum for RNA synthesis in vitro. 6. The degree of inhibition (maximally 30%) was dependent on the concentration of Mn(2+) and decreased during incubation.     

The binding of deoxyguanosine to polycytidylic acid: an application of the thermodynamic model of monomer-polymer complex formation.

The thermodynamic model (equation 1) for formation of monomer-polymer complexes developed for better interpretation of the sigmoidal isotherms for the binding of adenosine to polyuridylic acid (2) and chemically modified polyuridylic acids (3) has been successfully applied to reproduce the isotherms for both the duplex binding of deoxyguanosine (d-G) to polycytidylic acid (at pH 6.8) and the triplex binding at pH 4.1. The value for the equilibrium constant, K, of the triplex complex (per unit of C-G-C) is ～2000 at the optimum value of n = 5 (n is the number of d-G units in the smallest complex that can form). The value of K for the duplex complex is 555 and the optimum value of n is 4.The value of ΔG for the triple helical complex is 4.15 kcal/mole, the value of w (the stacking free energy of the d-G units in the complex) is 2.05 kcal/mole. For the double helical complex at pH 6.8, ΔG° is 3.45 kcal/mole, w = 1.55 kcal/mole.It is also shown that equation (1) predicts that the shape and mid-point slope (i.e., w) of a binding isotherm depends only on the value of n; and thus the isotherms for rA-poly U (n = 5) and dG-poly C (n = 5) have the same mid-point slopes, and thus the same values of w. The difference between ΔG° and w is taken as a relative measure of the free energy of hydrogen bonding; values are calculated for the rA-poly U, the dG-poly C triple helix, and the dG-poly C double helical complexes.     

Cooperative binding of 2,2′‐bipyridine into polynucleotide poly(A)–poly(U‐) in an alkaline aqueous solution

UV absorption data analysis has been used to evaluate equilibrium constants of the pH‐induced interaction of 2,2′‐Bipy with polyadenylnic‐polyuridylic acid in aqueous solution. The conditional probabilities hard model has been adopted in treatment of concentration diagrams calculated by the soft modelling‐based Multivariate Curve Resolution‐Alternating Least Squares approach. Intrinsic binding constant (lgK_g = 1.93), and the cooperativity parameter (ω = 340), were calculated as the best fit. The plot of the experimental binding constant versus 2,2′‐Bipy equilibrium concentration shows two modes of ligand with polymer interactions. The equilibrium hard model correctly reproduced the binding constant variations observed in the experiment. The results indicated that ligand binding in two steps is governed by a cooperative process, that is, the enhancement of deprotonated structure stability. It would appear that proposed calculation approach can be used in future combined hard modelling theoretical and soft modelling experimental works. © 2013 Wiley Periodicals, Inc. Biopolymers 99:621–627, 2013.     

The attachment of polyuridylic acid to reticulocyte ribosomes

The attachment of polyuridylic acid to reticulocyte ribosomes was studied by using polyadenylic acid, which inhibits the attachment reaction only, while permitting translation of polyuridylic acid bound to ribosomes. After addition of polyadenylic acid the amount of polyphenylalanine synthesized under standard conditions was taken as a measure of the bound polyuridylic acid. In this way certain parameters of the attachment reaction and the subsequent translation of attached polyuridylic acid were defined: (1) polyuridylic acid-ribosome interaction at 37 degrees requires only Mg(2+) at an optimum concentration of 8mm; (2) K(+) (required for translation) is a non-competitive inhibitor of the attachment reaction; (3) optimum polyphenylalanine synthesis directed by attached polyuridylic acid occurs at 5mm-Mg(2+) concentration; (4) from kinetic studies single ribosomes appear to participate in the attachment reaction.     

The effects of polyuridylic acid on phenylalanine incorporation by subcellular fractions from carbon tetrachloride-poisoned rat liver

1. Ribosomes and microsomes isolated from the livers of rats that had received carbon tetrachloride 1hr. previously had decreased endogenous capacity to incorporate amino acid. 2. The capacity of the isolated structures to respond to a synthetic messenger, polyuridylic acid, and to incorporate phenylalanine was investigated. 3. It was found that ribosomes from carbon tetrachloride-treated animals, prepared with detergent and at high ionic strength, could be restored to the same specific activity as control particles with polyuridylic acid but that these particles required more Mg(2+) in the incubation mixture. 4. Microsomes could also be stimulated to control activities with polyuridylic acid, but had a narrow optimum range of Mg(2+) concentration. 5. Microsomes prepared from poisoned animals could be preprogrammed with polyuridylic acid to a significantly greater degree than could control particles, and this response was greater with increasing Mg(2+) concentrations. These data suggested that in carbon tetrachloride poisoning the messenger-ribosome interaction had been altered. 6. Attempts to deprogramme particles from control and treated animals resulted in decreased endogenous activity of both particles and a decreased capacity for the treated particles to be restored with the synthetic messenger. 7. It is suggested that two effects are present in carbon tetrachloride poisoning, namely an alteration of the messenger-ribosome interaction and an increased lability of the ribosome, as either separate or related events.     

Modification of polyuridylic acid by bisulfite. II: Studies on ribosomal binding and enzymatic hydrolysis

The reaction of polyuridylic acid with sodium bisulfite produces modified polymers in which up to 95% of the uracil residues have been converted to uracil-6-sulfonate residues. A 91.6% bisulfite-saturated polymer was found to resist hydrolysis by spleen phosphodiesterase and phosphorolysis by polynucleotide phosphorylase. Digestion by pancreatic ribonuclease was successful and gave the bisulfite adduct of uridine-3-phosphate. Treatment of this nucleotide adduct with acid phosphatase afforded the bisulfite adduct of uridine. The ability of polyuridylic acid to bind to ribosomes, and to stimulate the binding of phenylalanine tRNA to ribosomes was abolished by progressive bisulfite saturation of the polymer. The rate of decline of these functionsf with increasing bisulfite content, was less sharp than the loss of phenyl-alanine coding ability o, the modified polymer.     

IN VlTRO BINDING OF PHENYLALANYL-tRNA TO NEONATAL AND ADULT MOUSE BRAIN RIBOSOMES

The ability of brain ribosomes, isolated from mice of various ages, to bind phenylalanyl-tRNA was measured under various reaction conditions. In the presence of template RNA (polyuridylic acid) the binding could be measured by both enzymic and non-enzymic assays. In general, the binding requirements for the brain system were similar to those previously described for microbial and eukaryotic systems. Although previous studies have shown that ribosomes obtained from increasingly older mow brain tissue were less active in polyphenylalanine synthesis, no significant differences in phenylalanyl-tRNA binding to polysome complexes could be detected. The binding of phenylalanyl-tRNA by ribosomes isolated from both neonatal and mature mouse brain tissue was similar with regard to GTP and polyuridylic acid dependence, magnesium ion concentration and reaction kinetics. Similar binding of phenylalanyl-tRNA by young and mature brain ribosomes was also measured with ribonucleoprotein particles previously stripped with puromycin. The results are discussed in light of the rapid alteration of macromolecular synthesis during postnatal brain development and the possible role of the interaction between ribosomes and tRNA.     

The cooperative binding of large ligands to a one-dimensional lattice: the steric hindrance effect

The cooperative binding of monomeric ligands to a long lattice of a linear polymer with complete or partial steric hindrance is treated using a matrix method. Results and typical calculations of the model are represented. Non-saturated cooperative binding as well as two-step (biphasic) binding isotherms can be interpreted by the steric hindrance model. This is applicable to the analysis of the binding of surfactants to polymer. The usefulness and the limitation also are discussed.     

Pressure-induced dissociation of tight couple ribosomes

Ribosomes from Escherichia coli have been shown to undergo subunit dissociation at elevated hydrostatic pressure. This holds for both crude and highly purified ribosomes. No inhibitory effect could be detected by addition of either the S100 supernatant, or tRNA, polyuridylic acid, and spermine. Light scattering experiments at pressures up to 1000 bar reveal different susceptibility of tight couple and loose couple ribosomes toward pressure dissociation. Tight couples are subjected to EF-Tu-catalyzed binding of aminoacyl-tRNA, thus yielding a model system of the elongating ribosome before the peptidyl transfer step. High pressure dissociation of this compound suggests that enzymatic binding converts tight couples into loose couples. A hypothesis referring to conformational changes during the elongation cycle is presented.     

Proton magnetic resonance study of the binding of purine to polyuridylic acid

The interaction of unsubstituted purine with polyuridylic acid in D₂O solution at neutral pD has been studied by high resolution proton magnetic resonance spectroscopy. The poly U proton resonances were shifted to higher fields by the added purine, indicating that purine binds to the uracil bases of the polymer by base stacking. Severe broadening of the purine proton resonances was also observed, providing strong evidence for the intercalation of purine between adjacent uracil bases of the polymer. The line widths of the poly U proton resonances were not noticeably broadened in the presence of purine; thus, the binding of purine to poly U does not result in a more rigid or ordered structure for the polymer.     

The physical and enzymatic properties of Escherichia coli recA protein display anion-specific inhibition.

The enzymatic activities of Escherichia coli recA protein are sensitive to ionic composition. Here we report that sodium glutamate (NaGlu) is much less inhibitory to the DNA strand exchange, DNA-dependent ATPase, and DNA binding activities of the recA protein than is NaCl. Both joint molecule formation and complete exchange of DNA strands occur (albeit at reduced rates) at NaGlu concentrations as high as 0.5 M whereas concentrations of NaCl greater than 0.2 M are sufficient for complete inhibition. The single-stranded DNA (ssDNA)-dependent ATPase activity is even less sensitive to inhibition by NaGlu; ATP hydrolysis stimulated by M13 ssDNA is unaffected by 0.5 M NaGlu and is further stimulated by E. coli ssDNA binding protein approximately 2-fold. Finally, NaGlu has essentially no effect on the stability of recA protein-epsilon M13 DNA complexes, with concentrations of NaGlu as high as 1.5 M failing to dissociate the complexes. Surprisingly, NaGlu also has little effect on the concentration of NaCl required to disrupt the recA protein-epsilon M13 DNA complex, demonstrating that destabilization is dependent on both the concentration and type of anionic rather than cationic species. Quantitative analysis of DNA binding isotherms establishes that the intrinsic binding affinity of recA protein is affected by the anionic species present and that the cooperativity parameter is relatively unaffected. Consequently, the sensitivity of recA protein-ssDNA complexes to disruption by NaCl does not result from the competitive effects associated with cation displacement from the ssDNA upon protein binding but rather results from anion displacement upon complex formation. The magnitude of this anion-specific effect on ssDNA binding is large relative to that of other nucleic acid binding proteins.     

Factors causing release of ribosomal subunits from isolated nuclei of regenerating rat liver in vitro.

Incubation medium II causes release of ribosomal subunits from isolated prelabeled nuclei of regenerating rat liver in vitro (Sato, T., Ishikawa, K. and Ogato, K. (1976) Biochim. Biophys. Acta 000, 000-000). The effects of individual components of this medium on release of subunits were studied and the following results were obtained. 1. Dialyzed cytosol was effective in causing release of total labeled RNA, but its effect on release of labeled ribosomal subunits was rather lower than that of low molecular yeast RNA. Spermidine inhibited the release of total labeled RNA as well as that of labeled ribosomal subunits. 2. Low molecular yeast RNA was the most effective component for inducing release of labeled ribosomal subunits. Homologous ribosomal RNA was as effective as yeast RNA. Cytoplasmic ribosomes, prepared by washing with solution of high salt concentration, and their subunits were also effective. 3. Transfer RNA was not so effective as yeast RNA and ribosomal RNA and even after heat treatment it had little effect. 4. Among the homopolyribonucleotides tested, polyuridylic acid had a strong effect but polyadenylic acid, polycytidylic acid and polyinosinic acid had no effect. 5. The effects of yeast RNA and polyuridylic acid in causing release of labeled ribosomal subunits were dependent upon their concentrations in the reaction mixture. The characteristics of the factors which cause release of labeled ribosomal subunits in vitro are discussed on the basis of the results.     

Romanowsky dyes and the Romanowsky-Giemsa effect. 4. Binding of azure B to DNA

We investigated the binding of azure B to DNA (calf thymus) over a wide range of concentrations of the dye (CF) and the nucleic acid (CN) using absorption spectroscopy [CF and CN represent the total concentrations of the ye (F) and the mononucleotide units (N) of the DNA, respectively]. The binding isotherms of the dye to DNA in aqueous solutions were determined. In addition, we analysed the composition of insoluble DNA/azure B precipitates that are formed in presence of an excess of azure B. These precipitates are of particular interest, because Giemsa staining is usually performed using high dye concentrations. Azure B easily forms dimers in aqueous solutions. When determining the binding isotherms, the equilibrium between free monomers and dimers must be taken into account. Therefore, we determined the dimerisation constant (Kd) of azure B from the concentration dependency of its absorption spectra in water at the standard temperature T = 298 K (25 degrees C), Kd = 6.5 X 10(3) M-1 (experimental conditions: tris buffer, pH 7.2; concentration of Na ions, CNa = 0.002 M). As the CNa value increases, the dimerisation constant rises rapidly. When the azure B concentration is very low and there is an excess of DNA, ordinary Scatchard and Langmuir isotherms are observed. Monomer dye cations are bound to DNA, these cations being in equilibrium with free monomers in the solution. In order to obtain the Scatchard binding constant (Ks) and the binding parameter (n) spectroscopically, it is necessary to determine the extinction coefficient (epsilon Fb) of the monomer bound (b) dye molecules (F) at one analytical wave number (upsilon a). The three constants can be determined simultaneously using an iterative technique that combines Scatchard isotherms and the Benesi-Hildebrand extrapolation, CN----infinity. We obtained Ks = 1.8 X 10(5) M-1 and n = 0.18 (25 degrees C; tris buffer, pH 7.2; CNa = 0.002 M). At very low dye (CF) and competitor (CNa) concentrations, only 18% of the anionic binding sites of the DNA are capable of binding the dye cations. With increasing CNa values the concentration of bound azure B cations decreases rapidly. The Na cations displace the bound dye cations and act as a competitor. The Ks value also greatly depends on the competitor concentration (CNa).(ABSTRACT TRUNCATED AT 400 WORDS)     

GTP and Protein Synthesis in Cell-Free Systems

Abstract

Two supernatant fractions, T1 and T2, have been isolated and partially purified from rat liver and rabbit reticulocytes. In a cell-free system programmed with polyuridylic acid, both fractions are needed for phenylalanine polymerization. T1 factor and GTP are required for the enzymatic binding of phenylalanil-tRNA to template charged ribosomes. In the course of the binding reaction, GTP is hydrolyzed while no dipeptide formation can be detected. T2 factor coincides with a ribosome-linked GTPase, which is not stimulated by the addition of polyuridylic acid and phenylalanil-tRNA.     

Further observations on the polynucleotide-induced stimulation of protein synthesis by cell-free preparations from rabbit reticulocytes.

1. The effect of high-molecular-weight RNA from reticulocyte polyribosomes (messenger RNA) on protein synthesis by subcellular fractions derived from reticulocytes, reported by Arnstein, Cox & Hunt (1964), has now been studied in detail. Optimum response of the cell-free system requires 30-50mm-K(+) and approx. 5mm-Mg(2+) in the pH range 7.4-7.6. 2. RNA stimulates the incorporation into protein of both free amino acids and of aminoacyl residues from s-RNA. Stimulation by either RNA or polyuridylic acid is dependent on a labile factor or enzyme, which is present in the ;pH5 fraction' and may be concerned with the formation of new polysomes. Quantitatively the response of the cell-free system to RNA is similar to that of polyuridylic acid, and there appears to be competition between messenger RNA and polyuridylic acid or polyadenylic acid.     

Hydroxamic acid-containing hydrogels for nonabsorbed iron chelation therapy: synthesis, characterization, and biological evaluation

Iron overload is a severe clinical condition and can be largely prevented by the use of iron-specific chelating agents. A successful iron chelator needs to be orally active, nontoxic, and selective. In this study, hydrogels containing pendant hydroxamic acid groups have been synthesized as potential nonabsorbed chelators for iron in the gastrointestinal tract. The synthetic method employed to introduce hydroxamic acid groups to polymer chains involved reaction of polymer gels based on N-acryloxysuccinimide, acryloyl chloride, and (2-hydroxyethyl)acrylate monomers with hydroxylamine. These hydroxamic acid-functionalized polymer gels swell favorably in water and effectively sequester iron. In vitro iron-binding properties of these hydrogels were evaluated from their binding isotherms by use of iron(II) alone and in the presence of other competing metal ions. These polymers bind iron over a broad pH range. The iron-binding properties of the polymers were found to depend on the concentration of hydroxamate groups on polymer chains. The in vivo iron-binding efficacy of the polymers was evaluated in rat as the animal model. The polymers prevented an increase in serum hemoglobin and hematocrit levels in the animals, thus suggesting the prevention of systemic absorption of dietary iron from the gastrointestinal tract. The animals also maintained normal body weight during the treatment period, indicating the absence of any apparent toxicity associated with these polymers.     

The effect of a single intraperitoneal dose of the hepatocarcinogen 4-dimethylaminoazobenzene on the rough-surfaced endoplasmic reticulum of the liver of the rat

1. Changes in the structure and function of the rough-surfaced endoplasmic reticulum of the rat liver as deduced by electron microscopy, polysome analysis and the amino acid-incorporating activity of microsome fractions have been followed at various time-intervals after a single intraperitoneal dose of the hepatocarcinogen 4-dimethylaminoazobenzene. 2. The earliest effect observed was detachment of polysomes and disorganization and vesiculation of the cisternae of the rough-surfaced endoplasmic reticulum. This occurred after 6hr. 3. Subsequent to this was a phase of polysome disaggregation accompanied by impaired amino acid-incorporating activity by microsomes together with a much enhanced stimulating effect of polyuridylic acid on amino acid uptake. This reached a maximum at 24hr. 4. By 40hr. polysomes had re-formed and the amino acid-incorporating activity, together with the polyuridylic acid effect, were similar to those in controls. 5. It was not until 112hr. that something like the normal structure of the rough-surfaced endoplasmic reticulum was re-established. 6. It is not yet possible to relate these changes specifically with the process of azo-dye carcinogenesis.     

Characterization of the extracellular ribonuclease of Tetrahymena pyriformis W

Several investigations have indicated that Tetrahymena pyriformis secretes ribonuclease activity into culture media. The extracellular ribonuclease from strain W has been purified and partially characterized. The molecular weight was determined by gel filtration to be 26,500. The amino acid composition of the enzyme was compared with those of the three intracellular ribonucleases characterized by Trangas, and substantial differences were demonstrated. The extracellular enzyme hydrolyzed both polyadenylic and polyuridylic acids, indicating lack of absolute base specificity. The hydrolysis of polyadenylic acid followed normal Michaelis-Menten kinetics, but substrate inhibition occurred at high concentrations of polyuridylic acid. The hydrolysis of polyuridylic acid was competitively inhibited by 2'- and 3'-cytidine, guanine, and uridine nucleotides, and by 2'AMP. No inhibition of the hydrolysis of Torula yeast RNA was detected. The kinetic properties of the extracellular ribonuclease are compared with those of the intracellular enzymes.