Charge Shielding of PIP2 by Cations Regulates Enzyme Activity of Phospholipase C

Hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP₂) of the plasma membrane by phospholipase C (PLC) generates two critical second messengers, inositol-1,4,5-trisphosphate and diacylglycerol. For the enzymatic reaction, PIP₂ binds to positively charged amino acids in the pleckstrin homology domain of PLC. Here we tested the hypothesis that positively charged divalent and multivalent cations accumulate around the negatively charged PIP₂, a process called electrostatic charge shielding, and therefore inhibit electrostatic PIP₂-PLC interaction. This charge shielding of PIP₂ was measured quantitatively with an in vitro enzyme assay using WH-15, a PIP₂ analog, and various recombinant PLC proteins (β1, γ1, and δ1). Reduction of PLC activity by divalent cations, polyamines, and neomycin was well described by a theoretical model considering accumulation of cations around PIP₂ via their electrostatic interaction and chemical binding. Finally, the charge shielding of PIP₂ was also observed in live cells. Perfusion of the cations into cells via patch clamp pipette reduced PIP₂ hydrolysis by PLC as triggered by M₁ muscarinic receptors with a potency order of Mg²⁺ < spermine⁴⁺ < neomycin⁶⁺. Accumulation of divalent cations into cells through divalent-permeable TRPM7 channel had the same effect. Altogether our results suggest that Mg²⁺ and polyamines modulate the activity of PLCs by controlling the amount of free PIP₂ available for the enzymes and that highly charged biomolecules can be inactivated by counterions electrostatically.     

Measuring electrostatic, van der Waals, and hydration forces in electrolyte solutions with an atomic force microscope

In atomic force microscopy, the tip experiences electrostatic, van der Waals, and hydration forces when imaging in electrolyte solution above a charged surface. To study the electrostatic interaction force vs distance, curves were recorded at different salt concentrations and pH values. This was done with tips bearing surface charges of different sign and magnitude (silicon nitride, Al₂O₃, glass, and diamond) on negatively charged surfaces (mica and glass). In addition to the van der Waals attraction, neutral and negatively charged tips experienced a repulsive force. This repulsive force depended on the salt concentration. It decayed exponentially with distance having a decay length similar to the Debye length. Typical forces were about 0.1 nN strong. With positively charged tips, purely attractive forces were observed. Comparing these results with calculations showed the electrostatic origin of this force.

In the presence of high concentrations (> 3 M) of divalent cations, where the electrostatic force can be completely ignored, another repulsive force was observed with silicon nitride tips on mica. This force decayed roughly exponentially with a decay length of 3 nm and was ~0.07-nN strong. This repulsion is attributed to the hydration force.

     

Interactions and Diffusion in Fine-Stranded β-lactoglobulin Gels Determined via FRAP and Binding

The effects of electrostatic interactions and obstruction by the microstructure on probe diffusion were determined in positively charged hydrogels. Probe diffusion in fine-stranded gels and solutions of β-lactoglobulin at pH 3.5 was determined using fluorescence recovery after photobleaching (FRAP) and binding, which is widely used in biophysics. The microstructures of the β-lactoglobulin gels were characterized using transmission electron microscopy. The effects of probe size and charge (negatively charged Na₂-fluorescein (376Da) and weakly anionic 70kDa FITC-dextran), probe concentration (50 to 200 ppm), and β-lactoglobulin concentration (9% to 12% w/w) on the diffusion properties and the electrostatic interaction between the negatively charged probes and the positively charged gels or solutions were evaluated. The results show that the diffusion of negatively charged Na₂-fluorescein is strongly influenced by electrostatic interactions in the positively charged β-lactoglobulin systems. A linear relationship between the pseudo-on binding rate constant and the β-lactoglobulin concentration for three different probe concentrations was found. This validates an important assumption of existing biophysical FRAP and binding models, namely that the pseudo-on binding rate constant equals the product of the molecular binding rate constant and the concentration of the free binding sites. Indicators were established to clarify whether FRAP data should be analyzed using a binding-diffusion model or an obstruction-diffusion model.     

Quantitation of the Calcium and Membrane Binding Properties of the C2 Domains of Dysferlin

Dysferlin is a large membrane protein involved in calcium-triggered resealing of the sarcolemma after injury. Although it is generally accepted that dysferlin is Ca²⁺ sensitive, the Ca²⁺ binding properties of dysferlin have not been characterized. In this study, we report an analysis of the Ca²⁺ and membrane binding properties of all seven C2 domains of dysferlin as well as a multi-C2 domain construct. Isothermal titration calorimetry measurements indicate that all seven dysferlin C2 domains interact with Ca²⁺ with a wide range of binding affinities. The C2A and C2C domains were determined to be the most sensitive, with K_d values in the tens of micromolar, whereas the C2D domain was least sensitive, with a near millimolar K_d value. Mutagenesis of C2A demonstrates the requirement for negatively charged residues in the loop regions for divalent ion binding. Furthermore, dysferlin displayed significantly lower binding affinity for the divalent cations magnesium and strontium. Measurement of a multidomain construct indicates that the solution binding affinity does not change when C2 domains are linked. Finally, sedimentation assays suggest all seven C2 domains bind lipid membranes, and that Ca²⁺ enhances but is not required for interaction. This report reveals for the first time, to our knowledge, that all dysferlin domains bind Ca²⁺ albeit with varying affinity and stoichiometry.     

Quantitation of the Calcium and Membrane Binding Properties of the C2 Domains of Dysferlin

Dysferlin is a large membrane protein involved in calcium-triggered resealing of the sarcolemma after injury. Although it is generally accepted that dysferlin is Ca²⁺ sensitive, the Ca²⁺ binding properties of dysferlin have not been characterized. In this study, we report an analysis of the Ca²⁺ and membrane binding properties of all seven C2 domains of dysferlin as well as a multi-C2 domain construct. Isothermal titration calorimetry measurements indicate that all seven dysferlin C2 domains interact with Ca²⁺ with a wide range of binding affinities. The C2A and C2C domains were determined to be the most sensitive, with K_d values in the tens of micromolar, whereas the C2D domain was least sensitive, with a near millimolar K_d value. Mutagenesis of C2A demonstrates the requirement for negatively charged residues in the loop regions for divalent ion binding. Furthermore, dysferlin displayed significantly lower binding affinity for the divalent cations magnesium and strontium. Measurement of a multidomain construct indicates that the solution binding affinity does not change when C2 domains are linked. Finally, sedimentation assays suggest all seven C2 domains bind lipid membranes, and that Ca²⁺ enhances but is not required for interaction. This report reveals for the first time, to our knowledge, that all dysferlin domains bind Ca²⁺ albeit with varying affinity and stoichiometry.     

Interactions and Diffusion in Fine-Stranded β-lactoglobulin Gels Determined via FRAP and Binding

The effects of electrostatic interactions and obstruction by the microstructure on probe diffusion were determined in positively charged hydrogels. Probe diffusion in fine-stranded gels and solutions of β-lactoglobulin at pH 3.5 was determined using fluorescence recovery after photobleaching (FRAP) and binding, which is widely used in biophysics. The microstructures of the β-lactoglobulin gels were characterized using transmission electron microscopy. The effects of probe size and charge (negatively charged Na₂-fluorescein (376Da) and weakly anionic 70kDa FITC-dextran), probe concentration (50 to 200 ppm), and β-lactoglobulin concentration (9% to 12% w/w) on the diffusion properties and the electrostatic interaction between the negatively charged probes and the positively charged gels or solutions were evaluated. The results show that the diffusion of negatively charged Na₂-fluorescein is strongly influenced by electrostatic interactions in the positively charged β-lactoglobulin systems. A linear relationship between the pseudo-on binding rate constant and the β-lactoglobulin concentration for three different probe concentrations was found. This validates an important assumption of existing biophysical FRAP and binding models, namely that the pseudo-on binding rate constant equals the product of the molecular binding rate constant and the concentration of the free binding sites. Indicators were established to clarify whether FRAP data should be analyzed using a binding-diffusion model or an obstruction-diffusion model.     

Revisiting the Association of Cationic Groove-Binding Drugs to DNA Using a Poisson-Boltzmann Approach

Proper modeling of nonspecific salt-mediated electrostatic interactions is essential to understanding the binding of charged ligands to nucleic acids. Because the linear Poisson-Boltzmann equation (PBE) and the more approximate generalized Born approach are applied routinely to nucleic acids and their interactions with charged ligands, the reliability of these methods is examined vis-à-vis an efficient nonlinear PBE method. For moderate salt concentrations, the negative derivative, SK_pred, of the electrostatic binding free energy, ΔG_el, with respect to the logarithm of the 1:1 salt concentration, [M⁺], for 33 cationic minor groove drugs binding to AT-rich DNA sequences is shown to be consistently negative and virtually constant over the salt range considered (0.1-0.4 M NaCl). The magnitude of SK_pred is approximately equal to the charge on the drug, as predicted by counterion condensation theory (CCT) and observed in thermodynamic binding studies. The linear PBE is shown to overestimate the magnitude of SK_pred, whereas the nonlinear PBE closely matches the experimental results. The PBE predictions of SK_pred were not correlated with ΔG_el in the presence of a dielectric discontinuity, as would be expected from the CCT. Because this correlation does not hold, parameterizing the PBE predictions of ΔG_el against the reported experimental data is not possible. Moreover, the common practice of extracting the electrostatic and nonelectrostatic contributions to the binding of charged ligands to biopolyelectrolytes based on the simple relation between experimental SK values and the electrostatic binding free energy that is based on CCT is called into question by the results presented here. Although the rigid-docking nonlinear PB calculations provide reliable predictions of SK_pred, at least for the charged ligand-nucleic acid complexes studied here, accurate estimates of ΔG_el will require further development in theoretical and experimental approaches.     

Examining the contributions of lipid shape and headgroup charge on bilayer behavior

To better understand bilayer property dependency on lipid electrostatics and headgroup size, we use atomistic molecular dynamics simulations to study negatively charged and neutral lipid membranes. We compare the negatively charged phosphatidic acid (PA), which at physiological pH and salt concentration has a negative spontaneous curvature, with the negatively charged phosphatidylglycerol (PG) and neutrally charged phosphatidylcholine (PC), both of which have zero spontaneous curvature. The PA lipids are simulated using two different sets of partial charges for the headgroup and the varied charge distribution between the two PA systems results in significantly different locations for the Na⁺ ions relative to the water/membrane interface. For one PA system, the Na⁺ ions are localized around the phosphate group. In the second PA system, the Na⁺ ions are located near the ester carbonyl atoms, which coincides with the preferred location site for the PG Na⁺ ions. We find that the Na⁺ ion location has a larger effect on bilayer fluidity properties than lipid headgroup size, where the A_lipid and acyl chain order parameter values are more similar between the PA and PG bilayers that have Na⁺ ions located near the ester groups than between the two PA bilayers.     

Amino acid and divalent ion permeability of the pores formed by the Bacillus thuringiensis toxins Cry1Aa and Cry1Ac in insect midgut brush border membrane vesicles

The pores formed by Bacillus thuringiensis insecticidal toxins have been shown to allow the diffusion of a variety of monovalent cations and anions and neutral solutes. To further characterize their ion selectivity, membrane permeability induced by Cry1Aa and Cry1Ac to amino acids (Asp, Glu, Ser, Leu, His, Lys and Arg) and to divalent cations (Mg²⁺, Ca²⁺ and Ba²⁺) and anions (SO₄²⁻ and phosphate) was analyzed at pH 7.5 and 10.5 with midgut brush border membrane vesicles isolated from Manduca sexta and an osmotic swelling assay. Shifting pH from 7.5 to 10.5 increases the proportion of the more negatively charged species of amino acids and phosphate ions. All amino acids diffused well across the toxin-induced pores, but, except for aspartate and glutamate, amino acid permeability was lower at the higher pH. In the presence of either toxin, membrane permeability was higher for the chloride salts of divalent cations than for the potassium salts of divalent anions. These results clearly indicate that the pores are cation-selective.     

The role of the invariant glutamate 95 in the catalytic site of Complex I from Escherichia coli

Replacement of glutamate 95 for glutamine in the NADH- and FMN-binding NuoF subunit of E. coli Complex I decreased NADH oxidation activity 2.5-4.8 times depending on the used electron acceptor. The apparent K_m for NADH was 5.2 and 10.4 μM for the mutant and wild type, respectively. Analysis of the inhibitory effect of NAD⁺ on activity showed that the E95Q mutation caused a 2.4-fold decrease of K_i^NAD+ in comparison to the wild type enzyme. ADP-ribose, which differs from NAD⁺ by the absence of the positively charged nicotinamide moiety, is also a competitive inhibitor of NADH binding. The mutation caused a 7.5-fold decrease of K_i^ADP-ribose relative to wild type enzyme. Based on these findings we propose that the negative charge of Glu95 accelerates turnover of Complex I by electrostatic interaction with the negatively charged phosphate groups of the substrate nucleotide during operation, which facilitates release of the product NAD⁺. The E95Q mutation was also found to cause a positive shift of the midpoint redox potential of the FMN, from − 350 mV to − 310 mV, which suggests that the negative charge of Glu95 is also involved in decreasing the midpoint potential of the primary electron acceptor of Complex I.     

Composites of peptide nucleic acids with ttitanium dioxide nanoparticles. I. Construction of nanocomposites containing DNA/PNA duplexes and their delivery into HeLa cells

In order to study the possibility of using titanium dioxide (TiO₂) nanoparticles to deliver peptide nucleic acids (PNA) in eukaryotic cells, a PNA oligomer was synthesized, and a method of PNA immobilization in the form of hybrid DNA/PNA duplexes on the surface of TiO₂ nanoparticles covered with polylysine (PL) was developed. The attachment of a DNA/PNA duplex to TiO₂ · PL nanoparticles occurs due to electrostatic interactions between the negatively charged DNA chain and the positively charged amino groups of PL. The binding of the PNA to the nanocomposite is achieved through noncovalent Watson-Crick interactions between PNA and complementary DNA. The capacity of the obtained TiO₂ · PL · DNA/PNA nano-composites depending on immobilization conditions was 10?C30 nmol PNA per 1 mg of TiO₂ particles, which corresponds to ??1?C3 PNA molecules per one TiO₂ particle with a size of 4?C6 nm. It was shown by confocal laser scanning microscopy that fluorescently-labeled PNA molecules in the TiO₂ · PL · DNA/^FluPNA nano-composites effectively penetrate into HeLa cells without transfection agents, electroporation, or other auxiliary procedures.     

Adsorption of Adenine, Cytosine, Thymine, and Uracil on Sulfide-Modified Montmorillonite: FT-IR, M?ssbauer and EPR Spectroscopy and X-Ray Diffractometry Studies

In the present work the interactions of nucleic acid bases with and adsorption on clays were studied at two pHs (2.00, 7.00) using different techniques. As shown by Mössbauer and EPR spectroscopies and X-ray diffractometry, the most important finding of this work is that nucleic acid bases penetrate into the interlayer of the clays and oxidize Fe²⁺ to Fe³⁺, thus, this interaction cannot be regarded as a simple physical adsorption. For the two pHs the order of the adsorption of nucleic acid bases on the clays was: adenine????cytosine?>?thymine?>?uracil. The adsorption of adenine and cytosine on clays increased with decreasing of the pH. For unaltered montmorillonite this result could be explained by electrostatic forces between adenine/cytosine positively charged and clay negatively charged. However for montmorillonite modified with Na₂S, probably van der Waals forces also play an important role since both adenine/cytosine and clay were positively charged. FT-IR spectra showed that the interaction between nucleic acid bases and clays was through NH⁺ or NH ₂ ⁺ groups. X-ray diffractograms showed that nucleic acid bases adsorbed on clays were distributed into the interlayer surface, edge sites and external surface functional groups (aluminol, silanol) EPR spectra showed that the intensity of the line g????2 increased probably because the oxidation of Fe²⁺ to Fe³⁺ by nucleic acid bases and intensity of the line g?=?4.1 increased due to the interaction of Fe³⁺ with nucleic acid bases. Mössbauer spectra showed a large decreased on the Fe²⁺ doublet area of the clays due to the reaction of nucleic acid bases with Fe²⁺.     

The role of membrane surface charge in the control of photosynthetic processes and the involvement of electrostatic screening

Calculations of changes of the integrated space charge density within the diffuse layer adjacent to a negatively charged membrane surface have been made using analytical expressions derived from the full non-linear Poisson-Boltzmann equation of the Gouy-Chapman theory. This electrostatic screening parameter has been examined for mixed electrolytes of valency type $\text{Z}{}^{\mathrm{1+}}\text{Z}{}^{\mathrm{1?}}$ and $\text{Z}{}^{\mathrm{2+}}\text{Z}{}^{\mathrm{1?}}$ and concentration ranges were chosen so as to compare with experimental data obtained with thylakoid membranes. The results of the analysis are consistent with previous arguments (Barber, J., Mills, J.D. and Love, A. (1977) FEBS Letts. 74, 174–181) that this screening parameter is involved in the control of salt induced chlorophyll fluorescence and thylakoid stacking changes. Phenomenological equations suggesting the origin of the variations in the integrated space charge density for various salt conditions are presented. Overall the integrated space charge density (σ^′_x) is shown to be a more satisfactory measure of both short and long range effects associated with electrostatic screening and double layer repulsion of charged surfaces than the planar space charge density (?_x.     

On the interaction of chromomycin A3 with calf thymus DNA in the presence of metal cations at different pH values

The interactions of the antitumor antibiotics, chromomycin A₃, with a variety of metal cations in the pH range of 3.0–8.5 were systematically studied by CD, absorption, and ¹H-nmr spectroscopies. Results were compared with those obtained in the presence of increasing amounts of calf thymus DNA. The negatively charged chromomycin A₃, pK_a 6.3, forms aggregates that become ordered and smaller in size, in the presence of variety of metal cations. Spectrophotometric titrations have shown that binding of the neutral drug to DNA at pH 4.5 does not require divalent cations, although the strength of the binding is greatly enhanced in their presence. At higher pH values (> 7.0) and low DNA/drug ratio ( > 20), the metal cations are necessary to induce the binding between chromomycin A₃ and DNA. At higher DNA/drug ratios (> 100: 1), an appreciable proportion of the drug is bound even in the absence of divalent cations. Its binding affinity to the DNA is enhanced in the presence of these cations and at low pH values. Therefore, we conclude that chromomycin A₃ binds in two related modes, in the presence and in the absence of divalent cations. The spectral data accumulated indicate the metal cation is involved in the binding of the drug to the DNA by forming a drug–metal–DNA ternary complex.     

Chemically induced gelation of polysaccharide produced by Methylobacterium organophilum

Both attractive and repulsive interactions between entangled Methylan chains were investigated with divalent cations that might form a salt bridge or generate an electrostatic attraction between the negatively charged groups in Methylan chains. The chemically induced gelation produces a thermally reversible gel. The gel strength was proportional to Methylan concentration in range from 1 to 5 g/l and was controlled by both Methylan and salt concentrations. © Rapid Science Ltd. 1998     

Protein binding by agarose carrying hydrophobic groups in conjunction with charges

The binding of a series of proteins to agarose (Sepharose 4B) substituted with n-alkylamines of varying C-chain length (C₁, C₄ or C₈) has been investigated. At pH 8 and 0.05 ionic strength the negatively charged proteins (chymotrypsinogen X, serum albumin, ovalbumin and β-lactoglobulin), in constrast to the positively charged species (chymotrypsinogen A, α-chymotrypsin, and lysozyme) had strong affinity for the adsorbents with the longer C-chains (C₄, C₈). The binding appears to depend on cooperation between hydrophobic and electrostatic forces, the latter involving positive charges on the adsorbent which are introduced by the substitution process.     

The Lipopeptide Antibiotic Paenibacterin Binds to the Bacterial Outer Membrane and Exerts Bactericidal Activity through Cytoplasmic Membrane Damage

Paenibacterin is a broad-spectrum lipopeptide antimicrobial agent produced by Paenibacillus thiaminolyticus OSY-SE. The compound consists of a cyclic 13-residue peptide and an N-terminal C₁₅ fatty acyl chain. The mechanism of action of paenibacterin against Escherichia coli and Staphylococcus aureus was investigated in this study. The cationic lipopeptide paenibacterin showed a strong affinity for the negatively charged lipopolysaccharides (LPS) from the outer membrane of Gram-negative bacteria. Addition of LPS (100 μg/ml) completely eliminated the antimicrobial activity of paenibacterin against E. coli. The electrostatic interaction between paenibacterin and LPS may have displaced the divalent cations on the LPS network and thus facilitated the uptake of antibiotic into Gram-negative cells. Paenibacterin also damaged the bacterial cytoplasmic membrane, as evidenced by the depolarization of membrane potential and leakage of intracellular potassium ions from cells of E. coli and S. aureus. Therefore, the bactericidal activity of paenibacterin is attributed to disruption of the outer membrane of Gram-negative bacteria and damage of the cytoplasmic membrane of both Gram-negative and Gram-positive bacteria. Despite the evidence of membrane damage, this study does not rule out additional bactericidal mechanisms potentially exerted by paenibacterin.     

Saccharinate-metal complexes with 1,10-phenanthroline (phen) or 2,2′-bipyridine (bipy) as co-ligands; the synthesis, crystal and molecular structures of five new compounds of divalent metals

Five new saccharinate complexes of divalent metals with either phen or bipy as co-ligands have been synthesised, and fully characterised by single crystal X-ray diffraction at low temperature. The complexes [M(phen)₂(H₂O)₂](sac)₂·H₂O (M = Co or Zn) are isostructural, while [Hg(bipy)₂(sac)₂] is isostructural with the analogous cadmium(II) compound, which has been described previously in the literature. Cadmium(II) complex [Cd(phen)₂(sac)(H₂O)](sac).H₂O has an octahedral cation with the unidentate ligands in cis-positions, while [Hg(phen)₂(sac)](sac)·2.5 H₂O provides a rare example of a distorted tbp structure for the cation, with five nitrogen donors. The structures are compared with those of related saccharinate complexes. In general, the more sterically demanding phen, when compared with bipy, forces more of the saccharinate anions to be uncoordinated, and for smaller ligands such as H₂O to be coordinated to the metal, despite the electrostatic attraction between the positively charged metal and the anion. Intramolecular hydrogen bonding involving saccharinate groups plays an important role in all the hydrated complexes.