The effect of cationic electrolytes on the adhesion of cells

The adhesion rate of cells under charge regulation onto a spherical collector with constant potential is investigated in this paper. Particularly, the effect of the presence of cationic electrolytes in the suspension medium on the adhesion rate is examined. The result reveals that the presence of cationic electrolytes in the suspension medium raises the electrostatic repulsion force between cell and collector surface, when the separation distance between them is small than a critical value. This has the effect of decreasing the adhesion rate of cells. The adhesion rate of cells is quite sensitive to the value of Hamaker constant, especially at a high ionic strength value.     

The effect of heme-linked ionizable groups on cyanide binding to methemoglobin

The pH dependence of the kinetics of the binding of cyanide ion to methemoglobins A and S and to guinea pig and pigeon methemoglobins appears to be not directly correlated with the net charges on the proteins. The kinetics can, however, be adequately explained in terms of three sets of heme-linked ionizable groups with pK1 ranging between 4.9 and 5.3, pK2 between 6.2 and 7.9, and pK3 between 8.0 and 8.5 at 20 degrees C. pK1 is assigned to carboxylic acid groups, pK2 to histidines and terminal amino groups, and pK3 to the acid-alkaline methemoglobin transition. Kinetic second order rate constants have also been determined for the binding of cyanide ion by the four sets of methemoglobin species present in solution. The pKi values and the rate constants of methemoglobin S are strikingly different from those of methemoglobin A. This result is explained in terms of different electrostatic contributions to the free energy of heme linkage arising from differences in the environments of ionizable groups at the surfaces of the two molecules.     

Electrostatic potential between surfaces bearing ionizable groups in ionic equilibrium with physiologic saline solution

In the past calculations of electrostatic properties of interacting cellular surfaces have been restricted by assumptions of fixed surface charge or surface potential. For the most part these calculations have been confined to a linear approximation and neglect the small but important complement of divalent cations in the cellular environment. In the present paper these limitations are removed. Solutions are obtained to the full non-linear Poisson-Boltzmann equation, treating the fraction of dissociated ionizable surface groups as a self-consistent functional of the electrostatic potential.     

pKa's of ionizable groups in proteins: atomic detail from a continuum electrostatic model

A macroscopic electrostatic model is used to calculate the pKa values of the titratable groups in lysozyme. The model makes use of detailed structural information and treats solvation self-energies and interactions arising from permanent partial charges and titratable charges. Both the tetragonal and triclinic crystal structures are analyzed. Half of the experimentally observed pKa shifts (11 out of 21) are well reproduced by calculations for both structures; this includes the unusually high pKa of Glu 35 in the active site. For more than half the pKa's (13 out of 21), there is a large difference (1-3.3 pK units) between the results from the two structures. Many of these correspond to the titrating groups for which the calculations are in error. Since for an ionic strength of 0.1 M the Debye screening between titratable groups leads to a very high effective dielectric constant (the average value for all pairs of titrating groups is approximately 900), near-neighbor interactions dominate the pKa perturbations. Thus, the pKa values are very sensitive to the details of the local protein conformation, and it is likely that side-chain mobility has an important role in determining the observed pKa shifts.     

Enzymatic activation of hydrophobic self-immolative dendrimers: The effect of reporters with ionizable functional groups

Self-immolative dendrimers are uniquely structured molecules that release multiple tail units through a chain fragmentation initiated by a single cleavage at the dendrimer’s core. Although bioactivation of self-immolative dendritic molecules with only two reporter groups was demonstrated, enzymatic activation failed for self-immolative dendrimers with more reporters. These large and hydrophobic dendrimers aggregated under aqueous conditions and enzyme did not efficiently trigger chain fragmentation. Here we demonstrate a simple solution to the problem of enzymatic activation of hydrophobic self-immolative dendrimers. The reporter units on the dendritic platform were equipped with ionizable functional group. Polar interactions with water significantly decreased hydrophobicity of the dendrimers and prevented aggregate formation. Consequently, hydrophobic self-immolative dendrons were effectively activated.     

The surface potential of and double-layer interaction force between surfaces characterized by multiple ionizable groups.

At the beginning of cleavage, a cell develops the form of a short central cylinder capped at the ends with ellipsoids. The strain pattern produced by this shape, with the application of constricting forces, guides the cell either to divide into two spherical cells or to take the shape of a long, thin cell which may remain a single cell or divide into two thin cells.     

The acceleration of methanesulfonylation of acetylcholinesterase with cationic accelerators as an electrostatic effect.

1. In order to check our hypothesis of the electrostatic nature of the acceleration of methanesulfonylation of acetylcholinesterase (acetylcholine hydrolase, EC 3.1.1.7) with cationic accelerators, equations were solved for methane-sulfonylation with two accelerators and the reaction was studied in the presence of some single accelerators, including the sodium cation, and in the presence of two acclerators simultaneously. 2. The second-order rate constants for methanesulfonylation of the complexes between the enzyme and accelerators decamethonium, tetraethylammonium and tetramethylammonium are 90, 88 and 17 1 - mol-1 - s-1, respectively, which corresponds to a maximal acceleration of 29, 28 and 5.5 times, respectively. The dissociation constants for the binding of these accelerators to the enzyme, obtained from our acceleration experiments, are 3.7 - 10(-6), 3.2 - 10(-4) and 1.4 - 10(-3) M, respectively. These values are in good agreement with the dissociation constants of these ligands as inhibitors of acetylcholinesterase. It is interesting to note that the sodium cation also accelerates the methane-sulfonylation up to around three times, the corresponding second-order rate constant and the dissociation constant being 10 1 - mol-1 - s-1 and 1.3 M, respectively. 3. All tested cations compete in the acceleration with each other; they seem to accelerate the reaction in the same way and from the same site, the catalytic anionic site. 4. These findings confirm the hypothesis of the electrostatic nature of acceleration.     

pK values of the ionizable groups of proteins

We have used potentiometric titrations to measure the pK values of the ionizable groups of proteins in alanine pentapeptides with appropriately blocked termini. These pentapeptides provide an improved model for the pK values of the ionizable groups in proteins. Our pK values determined in 0.1 M KCl at 25 degrees C are: 3.67+/-0.03 (alpha-carboxyl), 3.67+/-0.04 (Asp), 4.25+/-0.05 (Glu), 6.54+/-0.04 (His), 8.00+/-0.03 (alpha-amino), 8.55+/-0.03 (Cys), 9.84+/-0.11 (Tyr), and 10.40+/-0.08 (Lys). The pK values of some groups differ from the Nozaki and Tanford (N & T) pK values often used in the literature: Asp (3.67 this work vs. 4.0 N & T); His (6.54 this work vs. 6.3 N & T); alpha-amino (8.00 this work vs. 7.5 N & T); Cys (8.55 this work vs. 9.5 N & T); and Tyr (9.84 this work vs. 9.6 N & T). Our pK values will be useful to those who study pK perturbations in folded and unfolded proteins, and to those who use theory to gain a better understanding of the factors that determine the pK values of the ionizable groups of proteins.     

Anomalous settlement behavior of Ulva linza zoospores on cationic oligopeptide surfaces

Identification of settlement cues for marine fouling organisms opens up new strategies and methods for biofouling prevention, and enables the development of more effective antifouling materials. To this end, the settlement behaviour of zoospores of the green alga Ulva linza onto cationic oligopeptide self-assembled monolayers (SAMs) has been investigated. The spores interact strongly with lysine- and arginine-rich SAMs, and their settlement appears to be stimulated by these surfaces. Of particular interest is an arginine-rich oligopeptide, which is effective in attracting spores to the surface, but in a way which leaves a large fraction of the settled spores attached to the surface in an anomalous fashion. These 'pseudo-settled' spores are relatively easily detached from the surface and do not undergo the full range of cellular responses associated with normal commitment to settlement. This is a hitherto undocumented mode of settlement, and surface dilution of the arginine-rich peptide with a neutral triglycine peptide demonstrates that both normal and anomalous settlement is proportional to the surface density of the arginine-rich peptide. The settlement experiments are complemented with physical studies of the oligopeptide SAMs, before and after extended immersion in artificial seawater, using infrared spectroscopy, null ellipsometry and contact angle measurements.     

On the environment of ionizable groups in globular proteins

The environment of ionizable groups in 36 proteins is characterized in terms of solvent-accessibility, salt-bridge formation and hydrogen-bonding. Possible implications of our results as to the protonation state of buried ionizable groups are considered and patterns useful for model building studies on proteins are derived. The most interesting finding is that there are on average two completely buried ionizable groups per protein of which at least 20% do not form saltbridges. However, all buried ionizable groups form hydrogen bonds with neutral polar groups.     

Thermodynamic characterization of proton‐ionizable functional groups on the cell surfaces of ammonia‐oxidizing bacteria and archaea

The ammonia‐oxidizing archaeon Nitrosopumilus maritimus strain SCM1 (strain SCM1), a representative of the Thaumarchaeota archaeal phylum, can sustain high specific rates of ammonia oxidation at ammonia concentrations too low to sustain metabolism by ammonia‐oxidizing bacteria (AOB). One structural and biochemical difference between N. maritimus and AOB that might be related to the oligotrophic adaptation of strain SCM1 is the cell surface. A proteinaceous surface layer (S‐layer) comprises the outermost boundary of the strain SCM1 cell envelope, as opposed to the lipopolysaccharide coat of Gram‐negative AOB. In this work, we compared the surface reactivities of two archaea having an S‐layer (strain SCM1 and Sulfolobus acidocaldarius) with those of four representative AOB (Nitrosospira briensis, Nitrosomonas europaea, Nitrosolobus multiformis, and Nitrosococcus oceani) using potentiometric and calorimetric titrations to evaluate differences in proton‐ionizable surface sites. Strain SCM1 and S. acidocaldarius have a wider range of proton buffering (approximately pH 10–3.5) than the AOB (approximately pH 10–4), under the conditions investigated. Thermodynamic parameters describing proton‐ionizable sites (acidity constants, enthalpies, and entropies of protonation) are consistent with these archaea having proton‐ionizable amino acid side chains containing carboxyl, imidazole, thiol, hydroxyl, and amine functional groups. Phosphorous‐bearing acidic functional groups, which might also be present, could be masked by imidazole and thiol functional groups. Parameters for the AOB are consistent with surface structures containing anionic oxygen ligands (carboxyl‐ and phosphorous‐bearing acidic functional groups), thiols, and amines. In addition, our results showed that strain SCM1 has more reactive surface sites than the AOB and a high concentration of sites consistent with aspartic and/or glutamic acid. Because these alternative boundary layers mediate interaction with the local external environment, these data provide the basis for further comparisons of the thermodynamic behavior of surface reactivity toward essential nutrients.     

The uptake of protons by heme-linked ionizable groups on azide binding to methemoglobin

When azide ion reacts with methemoglobin in unbuffered solution the pH of the solution increases. This phenomenon is associated with increases in the pK values of heme-linked ionizable groups on the protein which give rise to an uptake of protons from solution. We have determined as a functional of pH the proton uptake, delta h+, on azide binding to methemoglobin at 20 degrees C. Data for methemoglobins A (human), guinea pig and pigeon are fitted to a theoretical expression based on the electrostatic effect of these sets of heme-linked ionizable groups on the binding of the ligand. From these fits the pK values of heme-linked ionizable groups are obtained for liganded and unliganded methemoglobins. In unliganded methemoglobin pK1, which is associated with carboxylic acid groups, ranges between 4.0 and 5.5 for the three methemoglobins; pK2, which is associated with histidines and terminal amino groups, ranges from 6.2 to 6.7. In liganded methemoglobin pK1 lies between 5.8 and 6.3 and pK2 varies from 8.1 to 8.5. The pH dependences of the apparent equilibrium constants for azide binding to the three methemoglobins at 20 degrees C are well accounted for with the pK values calculated from the variation of delta h+ with pH.     

Linkage of thioredoxin stability to titration of ionizable groups with perturbed pKa

The highly conserved, buried, Asp 26 in Escherichia coli thioredoxin has a pKa = 7.5, and its titration is associated with a sizable destabilization of the protein [Langsetmo, K., Fuchs, J., & Woodward, C. (1991) Biochemistry (preceding paper in this issue)]. A fit of the experimental pH dependence of thioredoxin stability to a theoretical expression for the pH/stability relation in proteins agrees closely with a pKa value of 7.5 for Asp 26. The agreement between the experimental and theoretical changes in protein stability due to substitution of Asp 26 by alanine is also good. The local structure in the vicinity of Asp 26 in the low-pH crystal structure (with uncharged Asp 26) is hydrophobic, indicating that the aspartate would be highly destabilized. In theoretical calculations, the desolvation penalty for deprotonating Asp 26 in this environment is similar to the total protein folding energy. As a consequence, the Asp 26 pKa would be much greater than 7.5, and/or the protein might not fold. This suggests that a compensating process partially stabilizes the Asp 26 carboxyl group when it is charged. A simple model for this proposed, whereby the Lys 57 side chain rotates to form a salt bridge with Asp 26 when it is deprotonated.     

The effect of multivalent cations on adhesion time for cellular adhesion to solid surfaces

The dynamic behavior of the adhesion of a charge-regulated cell to a solid surface of constant potential is investigated. In particular, the effect of the presence of multivalent cations in the suspension medium on adhesion time is discussed. By neglecting the effect of hydrodynamic retardation and assuming that the bulk liquid phase is stagnant, we show that the presence of multivalent cations has the effect of retarding cell adhesion. At a fixed level of ionic strength, the adhesion time increases with the increase of the concentration of multivalent cations in the suspension medium, and decreases with the increase in magnitude of the Hamaker constant. For a fixed concentration of cations, the adhesion time decreases with the increase of ionic strength. The effect of the magnitude of Hamaker constant on adhesion time is appreciable if both the ionic strength and the concentration of cations are high.     

Mapping the electrostatic profiles of cellular membranes

Anionic phospholipids can confer a net negative charge on biological membranes. This surface charge generates an electric field that serves to recruit extrinsic cationic proteins, can alter the disposition of transmembrane proteins and causes the local accumulation of soluble counterions, altering the local pH and the concentration of physiologically important ions such as calcium. Because the phospholipid compositions of the different organellar membranes vary, their surface charges are similarly expected to diverge. Yet, despite the important functional implications, remarkably little is known about the electrostatic properties of the individual organellar membranes. We therefore designed and implemented approaches to estimate the surface charges of the cytosolic membranes of various organelles in situ in intact cells. Our data indicate that the inner leaflet of the plasma membrane is most negative, with a surface potential of approximately –35 mV, followed by the Golgi complex > lysosomes > mitochondria ≈ peroxisomes > endoplasmic reticulum, in decreasing order.

Lipids and (glyco)proteins are the main constituents of biological membranes. Sugar moieties of glycoproteins, glycolipids, and adherent glycocalyx components such as hyaluronic acid can bear ionizable groups that confer a net negative charge on the outer surface of the plasma membrane. The aggregate surface charge of the outer membrane has been estimated indirectly by measuring the ζ potential—the potential at the slipping plane—by electrophoretic means (e.g., Tippe, 1981; Silva Filho et al., 1987) or by measuring streaming potentials (Vandrangi et al., 2012). The plasma membrane, however, is highly asymmetric; its inner (cytosolic) aspect is virtually devoid of carbohydrate moieties. Nevertheless, the cytosolic leaflet is also thought to be negatively charged, due primarily to the accumulation of anionic phospholipids, namely phosphoinositides and phosphatidylserine (PtdSer). Based on biochemical determinations of its lipid composition, the net negative charge of the plasmalemmal inner leaflet is estimated to generate an electrical field of 10⁵ V/cm (Olivotto et al., 1996). The membranes of intracellular organelles can also contain anionic lipids, but their precise lipid composition and topology have been difficult to assess and hence their surface charge has not been estimated.The surface potentials of biological membranes have important functional implications: they can alter the disposition of charged regions of transmembrane proteins, cause local accumulation of soluble counterions in the vicinity—altering the local pH as well as the concentration of physiologically important ions such as calcium—and serve to recruit extrinsic cationic proteins (McLaughlin, 1989). It is therefore important to determine the electrostatic properties of each of the organellar membranes. In principle, this could be accomplished by measuring the ζ potentials of isolated organelles. However, the purity of such preparations is imperfect, changes in lipid composition (particularly phosphoinositide degradation) and sidedness cannot be avoided, and loosely adherent components that may alter the surface charge can be removed during the isolation process. Alternative approaches to estimating the surface potential are therefore required.Here we used recombinant and synthetic polycationic peptides to obtain a quantitative estimate of the surface potential of the inner leaflet of the plasma membrane and to establish a hierarchical map of the potentials of the cytosolic surfaces of the major intracellular organelles in live cells.     

Electrostatic calculations of the pKa values of ionizable groups in bacteriorhodopsin.

The effects of solvation and charge-charge interactions on the pKa of ionizable groups in bacteriorhodopsin have been studied using a macroscopic dielectric model with atom-level detail. The calculations are based on the atomic model for bacteriorhodopsin recently proposed by Henderson et al. Even if the structural data are not resolved at the atomic level, such calculations can indicate the quality of the model, outline some general aspects of electrostatic interactions in membrane proteins, and predict some features. The effects of structural uncertainties on the calculations have been investigated by conformational sampling. The results are in reasonable agreement with experimental measurements of several unusually large pKa shifts (e.g. the experimental findings that Asp96 and Asp115 are protonated in the ground state over a wide pH range). In general, we find that the large unfavorable desolvation energies of forming charges in the protein interior must be compensated by strong favorable charge-charge interactions, with the result that the titrations of many ionizable groups are strongly coupled to each other. We find several instances of complex titration behavior due to strong electrostatic interactions between titrating sites, and suggest that such behavior may be common in proton transfer systems. We also propose that they can help to resolve structural ambiguities in the currently available density map. In particular, we find better agreement between theory and experiment when a structural ambiguity in the position of the Arg82 side-chain is resolved in favor of a position near the Schiff base.