Quantitative analysis of chromatin structure by circular dichroism

Quantitative analysis of the circular dichroism of nucleohistones and protein-free DNA was carried out in order to determine the structure and the role of the linker region DNA in chromatin, in terms of the conformational change of chromatin as a function of the ionic strength. It is shown clearly that the circular dichroism of Hl-depleted chromatin isolated from calf thymus is determined only by the ratio of the core region to the linker region and demonstrated by the linear combination of the spectrum of protein-free DNA and that of the nucleosome core in 5 mm-Tris · HCl, 1 mm-EDTA (pH 7.8). The calculated spectrum for the linker region in the H1-depleted chromatin was in good agreement with that of protein-free DNA. From the difference spectra between nucleohistones and protein-free DNA, it is suggested that the chromatin has an additional winding of DNA other than 146 base-pairs of DNA around the histone core. By decreasing the ionic strength to values lower than 5 mm-Tris · HCl, 1 mm-EDTA, the ellipticity of H1-depleted chromatin increased greatly between 250 nm and 300 nm while the increase was small in the case of chromatin and the nucleosome core. Nucleosomes with linker region DNA but without histone H1 also show great increase in ellipticity in this range of wavelengths as the ionic strength is decreased. Therefore, the linker region in H1-depleted chromatin plays an important role in the conformational changes brought about by changes in the ionic strength, and the conformational changes caused in the DNA of chromatin by decreasing the ionic strength are suppressed by the presence of histone H1.     

Membrane proton conductivity and energy-dependent fluxes of hydrogen ions in bacteria Enterococcus hirae grown in media with different pH values

It was shown that the proton conductivity of Enterococcus hirae ATCC9790 membrane increases three times as pH of the growth medium decreases from 8.5 to 5.5. The changes in proton conductivity are interrelated to the values of membrane and redox potentials of the cell, which in turn vary depending on the pH value of growth medium. The energy-dependent H+ efflux for cells fermenting sugar (the glucose) decreases 1.5 times as pH decreases from 8.5 to 5.5; in this case, the N,N'-dicyclohexylcarbodiimide at lower pH values suppresses the H+ efflux more intensively than at higher pH values, the H+ efflux nonsensitive to N,N'-dicyclohexylcarbodiimide being practically unchanged. The H+ efflux in the ATPase mutant MS116 is significantly (approximately 3 times) lower than that in the precursor strain and does not depend on pH. The results show that the proton conductivity of the membrane of this bacterium depends on pH of the growth medium. It is possible that the energy-dependent H+ efflux through F1F0-ATPase is interrelated with membrane proton conductivity.     

The self-association of chicken-erythrocyte histones.

The self-association of the separate histone fractions isolated from chicken erythrocytes has been studied in solution at a number of different pH values and ionic strengths. The apparent molecular weights of the histones were determined over a range of macromolecular concentrations using the techniques of osmotic pressure and sedimentation equilibrium. Histone F2c (H5) did not associate under any of the conditions investigated whereas the other histone fractions all appeared to undergo self-association forming dimers, dimers of dimers, etc. The degree of association increased with the pH and ionic strength of the medium. The tendency to aggregate increased in the order; histone F2c (H5) (non-aggregating), histone F2b (H2B), histone F2a2 (H2A), histone F3 (H3), histone F2a1 (H4) (highly aggregating). In the case of histone F2a2 (H2A) at pH 3.0 and ionic strength 0.1, the apparent weight-average molecular weight was determined at a number of macromolecular concentrations at five different temperatures. The self-association was analysed according to the method of Adams (published by Beckman Instruments Inc. in 1967) and shown to be a monomer-dimer-tetramer equilibrium. The association constants were evaluated at each of the temperatures studied and from their variation with temperature the values of the enthalpy and entropy of association were calculated. The intermolecular association was characterised by only a small change in enthalpy but a large, positive, change in entropy. This suggests that the association of histones at acid pH is due to hydrophobic interactions between the relatively uncharged segments of like polypeptide chains.     

Properties of the genome in normal and SV40 transformed WI38 human diploid fibroblasts. II. Metabolism and binding of histones.

Composition, metabolism and extractability of histone fractions from WI38 human diploid fibroblasts and SV40 transformed WI38 fibroblasts are compared. Two alternate procedures were used for isolation of nuclei which allow for either optimal recovery of arginine-rich histones F3 (III) and F2a1 (IV) or for optimal retention of lysine-rich F1 (I) and slightly lysine rich F2b (II b2). While the relative amount of each histone fraction was found to be similar in normal and SV40 transformed cells, substantial increases in the levels of F 3 acetylation and F1 and F2a2 phosphorylation are reported for the histones of SV40 transformed cells. Differences in extractability of arginine-rich histones with 0.25 M HCl are also reported. While F 3 is extracted more rapidly than F 2a1 from nuclei of normal WI38 fibroblasts, the reverse is true in SV40 transformed WI38 cells. These differences are discussed in relation to modification reactions, binding of histones to DNA and SV40-induced alterations in gene readout.     

pH-induced structural changes in bacteriorhodopsin studied by Fourier transform infrared spectroscopy.

Previous C13-NMR studies showed that two of the four internal aspartic acid residues (Asp-96 and Asp-115) of bacteriorhodopsin (bR) are protonated up to pH = 10, but no accurate pKa of these residues has been determined. In this work, infrared spectroscopy with the attenuated total reflection technique was used to characterize pH-dependent structural changes of ground-state, dark-adapted wild-type bacteriorhodopsin and its mutant (D96N) with aspartic acid-96 replaced by asparagine. Data indicated deprotonation of Asp-96 at high pH (pKa = 11.4 +/- 0.1), but no Asp-115 titration was observed. The analysis of the whole spectral region characteristic to complex conformational changes in the protein showed a more complicated titration with an additional pKa value (pKa1 = 9.3 +/- 0.3 and pKa2 = 11.5 +/- 0.2). Comparison of results obtained for bR and the D96N mutant of bR shows that the pKa approximately 11.5 characterizes not a direct titration of Asp-96 but a protein conformational change that makes Asp-96 accessible to the external medium.     

Removal of high phenol concentrations with adapted activated sludge in suspended form and entrapped in calcium alginate /cross-linked poly(N-vinyl pyrrolidone) hydrogels

The present work evaluates the aerobic removal of 0.25-2 g/L of phenol by adapted activated sludge in batch and continuous reactors, in suspended form and trapped in polymeric hydrogel beads of calcium alginate(1%) and cross-linked poly(N-vinyl pyrrolidone), x-PVP (4%). The mechanical and chemical resistance of the entrapping hydrogel was also evaluated in three different media: (I) rich in phosphate and ammonium ions; (II) using alternate P and N sources, and (III) without nutrients. The adapted consortium removed phenol concentrations up to 2 g/L more efficiently in the immobilized systems. A decrease in phenol removal rate was observed as the food/microorganisms (F/M) ratio increased. A zero-order kinetics was observed with phenol concentrations > 1 g/L and a first-order kinetics at concentrations < 1 g/L. The best response (100% removal) was in the continuous reactors using type II medium, with a hydraulic residence time (HRT) of 12.5 h, an influent pH = 5, and an F/M ratio below 0.25. The immobilizing matrix deteriorated after 170 h of use in continuous reactors, especially with media I and II, probably due to the attrition forces, to chemical weakness of the material, and to the pressure of the bacterial growth inside the bead.     

Effect of albumin conformation on the binding of ciprofloxacin to human serum albumin: a novel approach directly assigning binding site

Human serum albumin (HSA) is known to exist as N (pH approximately 7), B (pH approximately 9), and F (pH approximately 3.5) isomeric forms and an equilibrium intermediate state (I) accumulate in the urea induced unfolding pathway of HSA around 4.8-5.2 M urea concentrations. These states displayed characteristic structure and functions. To elucidate the ciprofloxacin (CFX) binding behavior of HSA, the binding of ciprofloxacin with these conformational states of human serum albumin (HSA) has been investigated by fluorescence spectroscopy. The binding constant (K) for N, B, F, and I conformation of HSA were 6.92 x 10(5), 3.87 x 10(5), 4.06 x 10(5), and 2.7 x 10(5) M(-1) and the number of binding sites (n) were 1.26,1.21, 1.16, and 1.19, respectively. The standard free energy changes (DeltaGbinding(0)) of interaction were found to be -33.3 (N isomer), -31.8 (B isomer), -32 (F isomer), and -30.0 kJ mol(-1) respectively. By using unfolding pathway of HSA, domain II of HSA has been assigned to possess binding site of ciprofloxacin. Plausible correlation between stability of CFX-N and CFX-B complexes and drug distribution have been discussed. At plasma concentration of HSA fraction of free CFX, which contributes potential to its rate of transport across cell membrane, was found to be approximately 80% more for B isomers compared to N isomers of HSA. The conformational changes in two physiologically important isomers of HSA (N and B isomers) upon ciprofloxacin binding were evaluated by measuring far, near-UV CD, and fluorescence properties of the CFX-HSA complex.     

Coordination properties of Cu(II) and Ni(II) ions towards the C-terminal peptide fragment -ELAKHA- of histone H2B

The coordination properties of the peptide Ac-GluLeuAlaLysHisAla-amide, the C-terminal 102-107 fragment of histone H2B towards Cu(II) and Ni(II) ions were studied by means of potentiometry and spectroscopic techniques (UV/Vis, CD, EPR and NMR). It was found that the peptide has a unique ability to bind Cu(II) ions at physiological pH values at a Cu(II): peptide molar ratio 1:2, which is really surprising for blocked hexapeptides containing one His residue above position 3. At physiological pH values the studied hexapeptide forms a CuL(2) complex {N(Im),2N(-)}, while in acidic and basic pH values the equimolar mode is preferred. In basic solutions Ac-GluLeuAlaLysHisAla-amide may bound through a {4N(-)} mode forming a square-planar complex, in which the imidazole ring is not any more coordinated or it has been removed in an axial position. On the contrary, Ni(II) ions form only equimolar complexes, starting from a distorted octahedral complex at about neutral pH values to a planar complex, where hexapeptide is bound through a {N(Im),3N(-)} mode in equatorial plane. The results may be of importance in order to reveal more information about the toxicity caused by metals and furthermore their influence to the physiologic metabolism of the cell.     

pH-induced co-operative effects in hysteretic enzymes. 2. pH-induced co-operative effects in a cell-wall beta-glucosyltransferase

A beta-glucosyltransferase, extracted and purified from the cell walls of isolated soybean cells, displays hysteretic behaviour. The enzyme is monomeric and has a negative co-operative between pH 5.5 and 7.5. Below and above these pH values, the enzyme follows, or approaches, classical Michaelis-Menten kinetics. The free enzyme and the enzyme-glucose complex exhibit, upon pH jumps, conformational transitions which may be followed by monitoring the fluorescence of enzyme-bound toluidinylnaphthalene sulfonate. Taken together these results are consistent with the model of pH-induced co-operativity described in the preceding paper in this journal. This special type of co-operativity relies on a change of the pK value of a strategic ionizable group located outside the active site in a region (or a domain) of the protein which undergoes the conformational transition. The result that at 'low' and 'high' pH values, the enzyme follows or approaches Michaelis-Menten kinetics is explained by assuming that the conformational changes do not affect the active site.     

Effect of axial coordination on the kinetics of assembly and folding of the two halves of horse heart cytochrome C

The kinetics of the assembly of two complementary fragments of oxidized horse heart cytochrome c (cyt c), namely the heme-containing fragment-(1-56) and the fragment-(57-104), have been characterized at different pH values. At neutral pH the fragment-(1-56) is hexacoordinated and has two histidines axially ligated to the heme-Fe(III) (Santucci, R., Fiorucci, L., Sinibaldi, F., Polizio, F., Desideri, A., and Ascoli, F. (2000) Arch. Biochem. Biophys. 379, 331-336), thus mimicking what occurs in the folding intermediate of cyt c. The kinetics of the formation of the complex between the two fragments are characterized at pH 7.0 by a slow rate constant that is independent of the concentration of the reactants; conversely, at a low pH the kinetics are much faster and depend on the concentration of the fragments. This behavior suggests that the rate-limiting step observed in the recombination process of the fragments at neutral pH (that leads to the final coordination of Met-80) has to be ascribed to the detachment of the "misligated" histidine. Thus, the faster recombination rate at a low pH can be related to the fact that histidine is protonated and not able to coordinate to the metal. Furthermore, the independence of the rate constant on the concentration of the reactants observed at pH 7.0 can be accounted for by the occurrence of a conformational transition, which takes place immediately after the two fragments collapse together, likely simulating what induces the detachment of the misligated histidine during cytochrome folding.     

Conformation of the HMG17-nucleosome complex

The nucleosome core binds more than two molecules of HMG17 at low ionic strength (8.9 mM Tris-HCl/8.9 mM boric acid/0.25 mM Na2EDTA, pH 8.3). Circular dichroism of the complexes showed only minor conformational changes of the nucleosome core DNA on binding of HMG17, with no detectable change in the histone secondary structure. The fluorescence of N-(3-pyrene) maleimide bound to -SH groups at Cys-110 of H3 histones in the core particle suggested that the structure of the histone octamer assembly changed little upon binding of HMG17 to the nucleosome. These observations support the idea that even a high level of HMG17 binding, e.g., four HMGs per nucleosome, alone, does not open up the core particle.     

Nucleosome conformation: pH and organic solvent effects.

Monomer nucleosomes (nu 1) from chicken erythrocyte nuclei were examined in aqueous buffers (8 greater than pH greater than 3) and in solvent mixtures (i.e., water and ethanol, ethylene glycol, dioxane, dimethyl sulfoxide, 2-methyl-2,4-pentanediol, polyethylene glycol, sucrose, or urea). Circular dichroism, laser Raman spectroscopy of nu 1, and the fluorescence of nu 1 labeled with N-(3-pyrene) maleimide on thiol groups of H3 histone were employed to detect conformational transitions in nu 1. The results of pH studies were as follows: 5.5 greater than pH greater than 4.8, suppression of DNA ellipticity and no change of histone alpha-helix; 4.6 greater than pH greater than 4.2 an irreversible increase in the B character of DNA, a slight loss of histone alpha-helix, and a parallel loss of pyrene excimer fluorescence; 4 greater than pH, aggregation of nu 1 and protonation of the DNA bases C and A. Results obtained in the studies of nu 1 in solvent mixtures included the following: sharp conformational transitions that variously involved an increase in the B character of DNA, a slight loss of histone alpha-helix, and a loss of pyrene excimer. Different solvents required different concentrations to effect these conformational changes.     

Conformational relaxations of urea- and guanidine hydrochloride-unfolded ferricytochrome c.

Several recent studies of protein the unfolded proteins. In urea- and guanidine HCl-unfolded ferricytochrome c (horse heart), an acid-induced spin state transformation of the heme group has been detected by the heme absorptions, Trp-59 fluorescence, and the intrinsic viscosity of protein. Kinetics of this second conformational transition, by the temperature jump and stopped flow methods, are complex. One rapid reaction (tau1), pH-independent, occurs in a 50-mus range; the second reaction (tau2), in a 1-ms range, depends linearly upon pH and is faster at the alkaline side; a third reaction (tau3), in a 1-s range, shows a sigmoidal transition at pH 5.1 and is faster at the acidic side. The results are consistent with a kinetic scheme which involves protein conformational changes in the transformation of the heme coordination state. The kinetics, along with previous equilibrium studies, indicate that ligand or charge interactions within a protein molecule are not completely prohibited even in strongly denaturing conditions, such as in high concentrations of urea and guanidine HCl. Thus, local structures of peptide chain associated with these interactions can exist in the unfolded protein.     

Kinetic studies of the interaction between MS2 phage and F pilus of Escherichia coli.

The kinetics of the binding reaction of MS2 phage to free F pili, which were highly purified from Escherichia coli, has been studied using a membrane filter assay. The rate of dissociation (kd) of the MS2-phage--F-pilus complex is very slow and follows first-order kinetics with a half-life of 4.2 h at 30 degrees C in the standard buffer. The dissociation rate is rather insensitive to temperature, but becomes more rapid at high ionic strength or at basic pH. In a 0.25 M ionic strength buffer, the half-life of the complex is about 1.0 min. The rate of association is very fast and follows second-order kinetics with the rate constant for association (ka) being 8 x 10(7) M-1 s-1 at 30 degrees C in the standard buffer. The rate of association is almost insensitive to ionic strength but slightly sensitive to pH or temperature. Monovalent cations can also promote the binding reaction as well as divalent cations but the complex formed with monovalent cation is unstable. A study of the kinetics of dissociation suggests that there are two types of interaction between MS2 phage and F pilus; one is a strong interaction formed with divalent cations and the other is a weak one formed with monovalent cations. The physical nature of the bonds involved in the former and the latter seems to be mainly electrostatic and non-electrostatic respectively. The mechanism of the binding reaction is discussed.     

Homotropic allosteric control in clostridial glutamate dehydrogenase: different mechanisms for glutamate and NAD+?

Clostridial glutamate dehydrogenase mutants with the 5 Trp residues in turn replaced by Phe showed the importance of Trp 64 and 449 in cooperativity with glutamate at pH 9. These mutants are examined here for their behaviour with NAD+ at pH 7.0 and 9.0. The wild-type enzyme displays negative NAD+ cooperativity at both pH values. At pH 7.0 W243F gives Michaelis-Menten kinetics, and the same behaviour is shown by W243F and also W310F at pH 9.0, but not by W64F or W449F. W243 and W310 are apparently much more important than W64 and W449 for the coenzyme negative cooperativity, implying that different conformational transitions are involved in cooperativity with the coenzyme and with glutamate.     

The influence of the copolymer composition on the diltiazem hydrochloride release from a series of pH-sensitive poly[(<Emphasis Type="Italic">N</Emphasis>-isopropylacrylamide)-<Emphasis Type="Italic">co</Emphasis>-(methacrylic acid)] hydrogels

A series of poly[(N-isopropylacrylamide)-co-(methacrylic acid)] (P[(N-iPAAm)-co-(MAA)]) hydrogels was investigated to determine the composition that exhibits a better pH-modulated release of diltiazem hydrochloride (DIL.HCl). For this purpose hydrogel slabs were loaded with DIL.HCl by the immersion method, and its release under acidic medium (0.1N HCl, pH 1.2) and in phosphate buffer pH 7.2, using United States Pharmacopeia (USP) 24 Apparatus 1, was investigated. According to the results from the slabs, copolymers with 85% mol N-iPAAm content were selected to prepare tablets with different particle size. The effect of pH and particle size changes on DIL.HCl release from these last hydrogel tablets was investigated by a stepwise pH variation of the dissolution medium. The amount of DIL.HCl released from high N-iPAAm content copolymer slabs under acidic pH medium was not only very low but it was also released at a slow rate. In the 85% N-iPAAm tablets, significant differences between and within release profiles were found as a function of particle size and pH, respectively. A relationship between particle size and release rate has been found. The lower DIL.HCl release at acidic pH from enriched N-iPAAm copolymers is interpreted by a cooperative thermal- and pH-collapse. Although for the whole range of copolymer composition a dependence of the equilibrium of swelling on the pH was found, DIL.HCl release experiments indicated that hydrogels with 85% mol N-iPAAm are the more adequate to be used for modulated drug delivery systems. Additionally, the particle size of the tablet can be used to tailor the release rate.     

Transport of protons and potassium ions across the membranes of bacteria Enterococcus hirae depends on ATP and nicotineamide adenine dinucleotides

The transport of protons and potassium ions across the membranes of the bacteria Enterococcus hirae growing in an alkaline medium (pH 8.0) or under experimental conditions (pH 7.5) during glucose fermentation accomplished by a KtrI-system of absorption of potassium ions, which can interact with F0F1-ATPase to form at H(+)-K(+)-pump, has been studied. It was found on cells with a high membrane permeability that the administration of nicotinamideadenine dinucleotides results in the potassium absorption, which is insensitive to the inhibitor of F0F1-ATPase N,N'-dicyclohexylcarbodiimide. It is assumed that, along with the KtrI system, which interacts with F0F1-ATPase, a separate or another K+ absorption system operates in these bacteria under particular conditions, which is dependent on NAD(+)+NADH. Presumably, these interact with this system, changing its conformational state required for the transition to the "active" form.     

Heme and pH-dependent stability of an anionic horseradish peroxidase

Horseradish peroxidase A1 thermal stability was studied by steady-state fluorescence, circular dichroism and differential scanning calorimetry at pH values of 4, 7 and 10. Changes in the intrinsic protein probes, tryptophan fluorescence, secondary structure, and heme group environment are not coincident. The T(m) values measured from the visible CD data are higher than those measured from Trp fluorescence and far-UV CD data at all pH values showing that the heme cavity is the last structural region to suffer significant conformational changes during thermal denaturation. However ejection of the heme group leads to an irreversible unfolding behavior at pH 4, while at pH 7 and 10 refolding is still observed. This is putatively correlated with the titration state of the heme pocket. Thermal transitions of HRPA1 showed scan rate dependence at the three pH values, showing that the denaturation process was kinetically controlled. The denaturation process was interpreted in terms of the classic scheme, N<-->U-->D and fitted to far-UV CD ellipticity. A good agreement was obtained between the experimental and theoretical T(m) values and percentages of irreversibility. However the equilibrium between N and U is probably more complex than just a two-state process as revealed by the multiple T(m) values.