Structural rearrangements induced by glycerol increase the permeability of bilayer lipid membranes for amphotericin

It has been shown that structural rearrangements induced by glycerol in bilayer lipid membranes (BLM) containing cholesterol facilitate the transmembrane transport of amphotericin B molecules in the direction of glycerol gradient. The addition of amphotericin B to the same side with glycerol results in a change in bilayer selectivity from the cation to the anion one. Besides, the final conductivity is blocked by tetraethylammonium from the solution with no amphotericin B added. It testifies to the transport of amphotericin molecules to the opposite side of the membrane. The transport effect depends on the cholesterol content in bilayer, ionic strength of the medium and slightly depends on temperature. It is concluded that transport of amphotericin B in such conditions differs from the diffusive one and is due to the formation of intermediate lipid phases in the course of structural rearrangements of bilayers.     

Structural transformations of oligonucleosomes from pigeon erythrocyte chromatin

The methods of velocity sedimentation and circular dichroism have been used to investigate structural rearrangements of pigeon erythrocyte oligonucleosomes isolated after digestion with micrococcal nuclease (oligonucleosomes-M) or pancreatic DNase I (oligonucleosomes-D), in the wide range of ionic strength (mu from 0.005 to 0.5). The electrophoretic analysis of DNA isolated from the oligonucleosomes has revealed internal cuts in the DNA chain of oligonucleosomes-D. In spite of this fact the conformational parameters of DNA in both types of oligonucleosomes are practically indistinguishable, and their optical and hydrodynamic properties vary in a similar way with increasing ionic strength of the solution. The specificity of DNase I action results in the ability of oligonucleosomes-D to form homogeneous associates at mu = 0.065, which seems to be due to the existence of elongated intact ends of linker DNA in oligonucleosomes-D. It has been shown that the integrity of oligonucleosomes-D in a wide range of ionic strength is maintained by histones H1 and H5, because after their dissociation the sedimentation coefficient sharply decreases. The results obtained reveal the multifunctional role of lysine-rich histones and intact linker in the processes of compaction and association of oligonucleosomes.     

The effect of thin filament activation on the attachment of weak binding cross-bridges: A two-dimensional x-ray diffraction study on single muscle fibers

To study possible structural changes in weak cross-bridge attachment to actin upon activation of the thin filament, two-dimensional (2D) x-ray diffraction patterns of skinned fibers from rabbit psoas muscle were recorded at low and high calcium concentration in the presence of saturating concentrations of MgATPgammaS, a nucleotide analog for weak binding states. We also studied 2D x-ray diffraction patterns recorded under relaxing conditions at an ionic strength above and below 50 mM, because it had been proposed from solution studies that reducing ionic strength below 50 mM also induces activation of the thin filament. For this project a novel preparation had to be established that allows recording of 2D x-ray diffraction patterns from single muscle fibers instead of natural fiber bundles. This was required to minimize substrate depletion or product accumulation within the fibers. When the calcium concentration was raised, the diffraction patterns recorded with MgATPgammaS revealed small changes in meridional reflections and layer line intensities that could be attributed in part to the effects of calcium binding to the thin filament (increase in I380, decrease in first actin layer line intensity, increase in I59) and in part to small structural changes of weakly attached cross-bridges (e.g., increase in I143 and I72). Calcium-induced small-scale structural rearrangements of cross-bridges weakly attached to actin in the presence of MgATPgammaS are consistent with our previous observation of reduced rate constants for attachment and detachment of cross-bridges with MgATPgammaS at high calcium. Yet, no evidence was found that weakly attached cross-bridges change their mode of attachment toward a stereospecific conformation when the actin filament is activated by adding calcium. Similarly, reducing ionic strength to less than 50 mM does not induce a transition from nonstereospecific to stereospecific attachment.     

Laser flash photolysis studies of the kinetics of reduction of ferredoxins and ferredoxin-NADP+ reductases from Anabaena PCC 7119 and spinach: electrostatic effects on intracomplex electron transfer

The influence of electrostatic forces on the formation of, and electron transfer within, transient complexes between redox proteins was examined by comparing ionic strength effects on the kinetics of the electron transfer reaction between reduced ferredoxins (Fd) and oxidized ferredoxin-NADP+ reductases (FNR) from Anabaena and from spinach, using laser flash photolysis techniques. With the Anabaena proteins, direct reduction by laser-generated flavin semiquinone of the FNR component was inhibited by complex formation at low ionic strength, whereas Fd reduction was not. The opposite results were obtained with the spinach system. These observations clearly indicate structural differences between the cyanobacterial and higher plant complexes. For the complex formed by the Anabaena proteins, the results indicate that electrostatic forces are not a major contributor to complex stability. However, the rate constant for intracomplex electron transfer had a biphasic dependence on ionic strength, suggesting that structural rearrangements within the transient complex facilitate electron transfer. In contrast to the Anabaena complex, electrostatic forces are important for the stabilization of the spinach Fd:FNR complex, and changes in ionic strength had little effect on the limiting rate constant for intracomplex electron transfer. This suggests that in this case the geometry of the initial collisional complex is optimal for reaction. These results provide a clear illustration of the differing roles that electrostatic interactions may play in controlling electron transfer between two redox proteins.     

Effect of ionic strength on the organization and dynamics of tryptophan residues in erythroid spectrin: a fluorescence approach

The ionic strength of the medium plays an important role in the structure and conformation of erythroid spectrin. The spectrin dimer is a flexible rod at physiological ionic strength. However, lower ionic strength results in elongation and rigidification (stiffening) of spectrin as shown earlier by electron microscopy and hydrodynamic studies. The ionic strength induced structural transition does not involve any specific secondary structural changes. In this article, we have used a combination of fluorescence spectroscopic approaches that include red edge excitation shift (REES), fluorescence quenching, time-resolved fluorescence measurements, and chemical modification of the spectrin tryptophans to assess the environment and dynamics of tryptophan residues of spectrin under different ionic strength conditions. Our results show that while REES, fluorescence anisotropy, lifetime, and chemical modification of spectrin tryptophans remain unaltered in low and high ionic strength conditions, quenching of tryptophan fluorescence by the aqueous quencher acrylamide (but not the hydrophobic quencher trichloroethanol) and resonance energy transfer to a dansyl-labeled fatty acid show differences in tryptophan environment. These results, which report tertiary structural changes in spectrin upon change in ionic strength, are relevant in understanding the molecular details underlying the conformational flexibility of spectrin.     

Cystathionine β-synthase (CBS) domains 1 and 2 fulfill different roles in ionic strength sensing of the ATP-binding cassette (ABC) transporter OpuA

The cystathionine β-synthase module of OpuA in conjunction with an anionic membrane surface acts as a sensor of internal ionic strength, which allows the protein to respond to osmotic stress. We now show by chemical modification and cross-linking studies that CBS2-CBS2 interface residues are critical for transport activity and/or ionic regulation of transport, whereas CBS1 serves no functional role. We establish that Cys residues in CBS1, CBS2, and the nucleotide-binding domain are more accessible for cross-linking at high than low ionic strength, indicating that these domains undergo conformational changes when transiting between the active and inactive state. Structural analyses suggest that the cystathionine β-synthase module is largely unstructured. Moreover, we could substitute CBS1 by a linker and preserve ionic regulation of transport. These data suggest that CBS1 serves as a linker and the structured CBS2-CBS2 interface forms a hinge point for ionic strength-dependent rearrangements that are transmitted to the nucleotide-binding domain and thereby affect translocation activity.     

Effect of the ionic strength and pH on the equilibrium structure of a neurofilament brush

Using the numerical model of Scheutjens and Fleer, we investigated, on a self-consistent field level, the equilibrium structure of the neurofilament brush formed by projection domains of the constituent NF-H, NF-M, and NF-L proteins. The phosphorylation of such a brush is a major regulatory process that triggers the relocation of the H tails from the NF core to the brush periphery. We explore how the pH and the ionic strength affect the rearrangements in the NF brush structure upon phosphorylation. We demonstrate that the translocation of H tails in an individual NF occurs as a sharp cooperative transition below and up to the physiological salt concentration. Regularities of this process are reminiscent of the collapse-to-stretching transition in a cylindrical polyelectrolyte brush in a poor solvent. The effect of pH at physiological ionic strength is noticeable only in the acidic range and is more pronounced for a dephosphorylated NF.     

Reversibility of Structural Rearrangements in Mononucleosomes Induced by Ionic Strength

Using fluorescence microscopy of single particles with Förster resonance energy transfer recording, structural rearrangements that occurred in nucleosomes formed on the 603 DNA template at high ionic strength were studied. Within the range of 0.7–1.3 M KCl, large-scale changes occurred in the nucleosome structure, including the formation of at least two states differing in the degree of DNA unwrapping from the histone octamer and affecting from 13 to 35 and more pairs of nucleotides. Content of the fraction of nucleosomes with modified structure varied from 60% at 0.7 M KCl to 100% at 1.3 M KCl. Preservation of the association between core histones and DNA in the new conformational states ensured reversibility of structural changes when KCl concentration was reduced to a physiological level. Reversibility was ~100% upon transition from 0.7 M to 0.15 KCl and decreased to ~50% upon transition from 1.3 M to 0.15 KCl.     

Kinetic and spectroscopic characterization of the putative monooxygenase domain of human MICAL-1

MICALs form a conserved multidomain protein family essential for cytoskeletal rearrangements. To complement structural information available, we produced the FAD-containing monooxygenase-like domain of human MICAL-1 (MICAL-MO) in forms differing for the presence and location of a His-tag, which only influences the protein yields. The K(m) for NADPH of the NADPH oxidase reaction is sensitive to ionic strength and type of ions. The apparent k(cat) (pH 7) is limited by enzyme reduction by NADPH, which occurs without detectable intermediates, as established by anaerobic rapid reaction experiments. The sensitivity to ionic strength and type of ions and the pH dependence of the steady-state kinetic parameters extend MICAL-MO similarity with enzymes of the p-hydroxybenzoate hydroxylase class at the functional level. The reaction is also sensitive to solvent viscosity, providing a tool to monitor the conformational changes predicted to occur during turnover. Finally, it was confirmed that MICAL-MO promotes actin depolymerization, and it was shown that F-actin, but not G-actin, stimulates NADPH oxidation by increasing k(cat) and k(cat)/K(NADPH) (≈5 and ≈200-fold, respectively) with an apparent K(m) for actin of 4.7μM, under conditions that stabilize F-actin. The time-course of NADPH oxidation shows substrate recycling, indicating the possible reversibility of MICAL effect.     

Structural changes in the contractile proteins of muscle fiber studied by polarization ultraviolet fluorescence microscopy. IX. The effect of the pH and ionic strength of the solution on the conformational restructurings of F-actin induced by the binding of heavy meromyosin

The dependence of F-actin conformational changes induced by the F-actin-HMM complex on pH and ionic strength was found by polarized ultraviolet fluorescence microscopy. It is discovered that pH affects sufficiently the cooperativity of F-actin structural changes, while the ionic strength affects their depth. The actomyosin complex was supposed to be at least in two structural states, differing in their orientation as well as in flexibility of F-actin monomers.     

Conformational transitions of calmodulin as studied by vacuum-uv CD

CD measurements were made for calmodulin and its calcium (Ca²⁺) complexes at different ionic strengths and Ca²⁺ concentrations. Calmodulin at an ionic strength of 0.00M and in the absence of Ca²⁺ exists as an α-helical protein with a negligible amount of β-sheet. An increase in ionic strength, whether or not Ca²⁺ is present, increases α-helix at the expense of “other” (coil) structure. The changes in β-sheet and β-turns are insignificant. Binding of Ca²⁺ at low ionic strength occurs in stages with at least one folding intermediate before attaining the final stable state. Binding of Ca²⁺ at an ionic strength of 0.165M causes only a slight increase in α-helix, so that the secondary structure of the protein depends on ionic strength and is insensitive to the nature of the cation (i.e., Ca²⁺). Thus, the activation of calmodulin by Ca²⁺ must be due to a structural reorientation rather than to a major secondary structural alteration. The CD estimation of secondary structure with 4 mol Ca²⁺/calmodulin (61% α-helix, 2% antiparallel β-sheet, 2% parallel β-sheet, 21% β-turns, and 14% other) is in excellent agreement with the x-ray results.     

Cation-induced regulatory mechanism of GTPase activity dependent on polypeptide initiation factor 2.

Initiation factor IF-2 ribosome dependent GTP hydrolysis (uncoupled GTPase) presents a bell-shaped pH profile which is shifted by changes in ionic strength. At low ionic strength (I = 25 mM) the maximal hydrolytic activity occurs at pH 7.5; when the ionic strength is increased the pH optimum of the reaction is shifted toward more acidic values. Such behavior can be satisfactorily explained as the effect of an electrostatic potential developed by a neighboring polyanion, presumably RNA, on the catalytic site. The addition of fMet-tRNAfMet or AcPhe-tRNAPhe and messenger RNA (coupled GTPase) changes the ionic strength--pH characteristics of the reaction. Thus there is an effect, direct or indirect, of components located at the ribosomal P site. Investigation of the effect of neighboring polyanions on the catalytic activity of the factor-dependent ribosomal GTPases can be seen to provide information about their functional significance that is complementary to that gained from direct structural studies.     

X-ray diffraction testing for weak-binding crossbridges in relaxed bony fish muscle fibres at low ionic strength

Equatorial X-ray diffraction patterns from single skinned fibres from bony fish muscle (turbot) were obtained with the fibres at 6 degrees C bathed in relaxing solutions of 170 down to 26 mM ionic strength. Diffraction patterns from rigor fibres were also obtained as controls. Unlike fibres from rabbit muscle, which show very clear evidence of substantial crossbridge formation at low ionic strength in what is mechanically a rapid equilibrium ("weak-binding") state (Brenner et al., 1982), diffraction patterns from bony fish fibres showed only a small change in relative peak intensities at low ionic strength (26 mM) compared with normal (170 mM) ionic strength. However, there was a slight ordering of the filament lattice at low ionic strength. The specimen temperature used (about 6 degrees C) was not far from the normal physiological temperature of the fish. Likewise, only a small change was seen by Xu et al. (1987) in patterns from frog fibres at low ionic strength at 2 to 6 degrees C. (Rabbit fibres previously studied, where large changes were seen at temperatures of 5 to 20 degrees C, were about 17 to 32 degrees C below physiological.) The I11/I10 ratio for fish fibres at 26 mM ionic strength was actually lower than that for rabbit even at normal ionic strength. This may be associated with an intrinsic structural difference between these muscles or alternatively with the disordering of the crossbridge helix in rabbit muscle found at low temperature by Wray (1987), and could support the view that rabbit fibres at 5 degrees C and normal ionic strength may already have a significant population of weak-binding crossbridges.     

The thermal denaturation of nonpolymerizable alpha alpha-tropomyosin and its segments as a function of ionic strength

Nonpolymerizable tropomyosin (NPTm) is found to unfold thermally at high ionic strength almost exactly as the parent protein, but it does not aggregate at low ionic strength. Thus, NPTm can be used as a tropomyosin surrogate whose coiled-coil structural stability can be probed by varying the ionic strength. Studies of NPTm by CD show that increasing ionic strength stabilizes the coiled-coil structure. CD spectra over a wide range of helix content, obtained by varying either temperature or ionic strength, show an isodichroic point at 203 nm, suggesting a local, residue-level, two-state model. At given temperature, such a local helix in equilibrium random equilibrium suggests ln [phi h/(1-phi h)] = A1 + A2In, wherein phi h is the fraction helix, and A1, A2, and n are constants. In the low ionic strength region, theoretical limiting laws for ionic strength mediated charge-charge, dipole-dipole, and apolar-apolar (salting out) interactions give, respectively, n = 0.5, 1.0, and 1.0. Our experimental values for 40 degrees C, where the data span a wide range of helix content, show n = 1.0, suggesting that ionic strength stabilizes either by reducing dipole-dipole repulsions or by enhancing hydrophobic interactions, both probably interhelix in nature. Two segments of tropomyosin, 11Tm127 and 142Tm281, neither of which aggregate at low ionic strength, give results similar to those for NPTm, i.e., n = 0.96 and 0.84, respectively.     

Effect of ionic strength and oxidation on the P-loop conformation of the protein tyrosine phosphatase-like phytase, PhyAsr

The protein tyrosine phosphatase (PTP)-like phytase, PhyAsr, from Selenomonas ruminantium is a novel member of the PTP superfamily, and the only described member that hydrolyzes myo-inositol-1,2,3,4,5,6-hexakisphosphate. In addition to the unique substrate specificity of PhyAsr, the phosphate-binding loop (P-loop) has been reported to undergo a conformational change from an open (inactive) to a closed (active) conformation upon ligand binding at low ionic strength. At high ionic strengths, the P-loop was observed in the closed, active conformation in both the presence and absence of ligand. To test whether the P-loop movement can be induced by changes in ionic strength, we examined the effect that ionic strength has on the catalytic efficiency of PhyAsr, and determined the structure of the enzyme at several ionic strengths. The catalytic efficiency of PhyAsr is highly sensitive to ionic strength, with a seven-fold increase in k(cat)/K(m) and a ninefold decrease in K(m) when the ionic strength is increased from 100 to 500 mm. Surprisingly, the P-loop is observed in the catalytically competent conformation at all ionic strengths, despite the absence of a ligand. Here we provide structural evidence that the ionic strength dependence of PhyAsr and the conformational change in the P-loop are not linked. Furthermore, we demonstrate that the previously reported P-loop conformational change is a result of irreversible oxidation of the active site thiolate. Finally, we rationalize the observed P-loop conformational changes observed in all oxidized PTP structures.     

Viscosity of chromatin solutions increases with increasing ionic strength

Increasing the ionic strength of rat liver chromatin solutions above 0.4 M causes increasing viscosity. This indicates transformation of the compact chromatin molecules to more elongated forms. In the range of 0.4–0.5 M ionic strength histone H1 is dissociating continuously from the chromatin and the quaternary structure chromatin unravels. At ionic strength higher than 0.5 M the viscosities of chromatin solutions are furthermore increasing due to structural deformation. Near 0.7 M ionic strength the core histones H2A and H2B begin to dissociate from the chromatin, and the opening of the nucleosome cores leads to increasing elongation of the chromatin molecules.     

Effect of the medium on functional and structural properties of serum albumins. IV. The state of human serum albumin in the pH range from 5 to 10

In order to investigate the effects of temperature and ionic strength on the N-B-transition and the alkaline denaturation of the human serum albumin, the pH-dependences of fluorescence position and relative yield of Trp-24 and of protein bound dye ANS were measured. The measurements were carried out at temperatures from 10 to 45 degrees C and ionic strengths (NaCl) from 0.001 to 0.2. The pH-induced structural transitions have different realization in environments of tryptophanyl and tightly bound ANS. The alkaline denaturation does not change the Trp-214 fluorescence. The N-B-transition gives rise to the slight polarity and/or mobility lowering in the Trp-214 environment (the shorter-wave-length spectral shift). Increase in the temperature and ionic strength induces the shift of the transition midpoint from ca. 8 to 8.7 and reduces the spectral shift amplitude. At low ionic strengths, the new structural transition in the Trp-214 environment is observed at pH change from 6.7 to 5.7. This transition is not observable using ANS fluorescence. The N-B-transition is accompanied by an enhancement and longer-wavelength shift of the ANS fluorescence spectra. The transition midpoint is independent of temperature, but is shifted to lower pH values at a decrease of ionic strength value. At ionic strengths less than or equal to 0.01 the shorter-wavelength spectral shift is seen at pH from 7.5 to 9, which seems to reflect the disulfide B-A-isomerisation. The alkaline denaturation gives rise to the sharp quenching of ANS fluorescence, probably due to the ANS binding site decomposition.(ABSTRACT TRUNCATED AT 250 WORDS)     

A Mesoscale Model of DNA and Its Renaturation

A mesoscale model of DNA is presented (3SPN.1), extending the scheme previously developed by our group. Each nucleotide is mapped onto three interaction sites. Solvent is accounted for implicitly through a medium-effective dielectric constant and electrostatic interactions are treated at the level of Debye-Hückel theory. The force field includes a weak, solvent-induced attraction, which helps mediate the renaturation of DNA. Model parameterization is accomplished through replica exchange molecular dynamics simulations of short oligonucleotide sequences over a range of composition and chain length. The model describes the melting temperature of DNA as a function of composition as well as ionic strength, and is consistent with heat capacity profiles from experiments. The dependence of persistence length on ionic strength is also captured by the force field. The proposed model is used to examine the renaturation of DNA. It is found that a typical renaturation event occurs through a nucleation step, whereby an interplay between repulsive electrostatic interactions and colloidal-like attractions allows the system to undergo a series of rearrangements before complete molecular reassociation occurs.     

Einfluß von Ionenstärke und pH auf die differentielle Dekondensation der Nukleoproteide isolierter Speicheldrüsen-Zellkerne und -Chromosomen von Chironomus thummi

A new method of isolating nuclei and chromosomes of salivary gland cells is described. — The influence of ionic strength and pH of the medium on the state of decondensation of chromosomal bands is studied. In the isolation medium (a modified Ringer solution), all the bands are in a condensed state; as the ionic strength is increased the bands decondense. This reaction of the bands to increasing ionic strength is dependent on the pH which determines: 1) the range of ionic strengths which causes decondensation of the bands; i.e., the lower the pH, the higher the ionic strength is required for decondensation (at pH 7.3, 150–350 mM NaCl, at pH 4.3, 500–800 mM NaCl), and 2) the extent of structural changes caused by increasing ionic strength; that is, at neutral pH the bands become diffuse (“fading”) and at moderate acidic pH (optimum 4.3) the bands unravel to yield pufflike structures (“swelling”). — All ion species tested induce decondensation of bands, but each one is effective differently; specifically, Mg⁺ is more effective than Na⁺ and K⁺, and ClO₄ ^? is more effective than Cl^?. — “Swelling” as induced at pH 4.3 by high ionic strength cannot be reversed by a mere lowering of ionic strength (to 150 mM NaCl) and a subsequent raise of pH (to 7.5); it can be reversed only by an addition of histones. The various histone fractions act differently on the recondensation process. — “Swelling” is correlated with an increase in template activity as evidenced by an increased incorporation of ³H-UTP, measured in the presence of ATP, CTP, GTP and exogeneous RNA polymerase. — The individual bands differ in their sensitivity to an increasing ionic strength. This differential sensitivity expresses itself only if one of the following conditions is met: 1) a moderately acidic pH (optimum 4.3) or 2) the presence of divalent cations at neutral pH. — In a few bands the sensitivity to an increasing ionic strength is dependent on the ionic species (Na⁺, K⁺, Mg⁺⁺ and Ca⁺⁺). — It is attempted to explain the above reactions on the basis of the physico-chemical properties of chromosomes.     

Urea-induced sequential unfolding of fibronectin: a fluorescence spectroscopy and circular dichroism study

Fibronectin (FN) is an extracellular matrix (ECM) protein found soluble in corporal fluids or as an insoluble fibrillar component incorporated in the ECM. This phenomenon implicates structural changes that expose FN binding sites and activate the protein to promote intermolecular interactions with other FN. We have investigated, using fluorescence and circular dichroism spectroscopy, the unfolding process of human fibronectin induced by urea in different ionic strength conditions. At any ionic strength, the equilibrium unfolding data are well described by a four-state equilibrium model N <= => I(1) <= =>I(2) <= => U. Fitting this model to experimental values, we have determined the free energy change for the different steps. We found that the N <= => I(1) transition corresponds to a free energy of 10.5 +/- 0.4 kcal/mol. Comparable values of free energy change are generally associated with a partial unfolding of the type III domain. For the I(1) <= => I(2) transition, the free energy change is 7.6 +/- 0.4 kcal/mol at low ionic strength but is twice as low at high ionic strength. This result is consistent with observations indicating that the complete unfolding of the type III domain from partially unfolded forms necessitates about 5 kcal/mol. The third step, I(2) <= => U, which leads to the complete unfolding of fibronectin, corresponds to a free energy change of 14.4 +/- 0.9 kcal/mol at low ionic strength whereas this energy is again twice as low under high ionic strength conditions. This hierarchical unfolding of fibronectin, as well as the stability of the different intermediates controlled by ionic strength demonstrated here, could be important for the understanding of activation of the matrix assembly.