Allosteric modification of factor XIa functional activity upon binding to polyanions

The effects of several polyanions on the hydrolysis of the chromogenic substrate L-pyroglutamyl-L-prolyl-L-arginyl-p-nitroaniline (S-2366) and on the activation of factor IX by factor XIa have been investigated. Two forms of dextran sulfate (M(r) approximately 500000 and M(r) approximately 10000, DX10) and two forms of heparin (64 disaccharide units, M(r) approximately 14000, and hypersulfated heparin, S-Hep, M(r) approximately 12000) inhibited both factor XIa amidolytic activity and factor IX activation in a concentration-dependent manner. The inhibitory effect was not due to binding of either substrate by the polyanions since only a decrease in V(max) without any effect on K(m) was observed in kinetic assays. Steric inhibition is unlikely since the concentrations of polyanions required for inhibition of small peptide hydrolysis were lower than those required for macromolecular substrate cleavage. In contrast, an allosteric inhibitory mechanism was supported by an enhancement of the dansyl fluorescence of 5-(dimethylamino)-1-(naphthalenesulfonyl)glutamylglycylarginyl- (DEGR-) factor XIa observed when the fluorophore was in complex with either DX10 or S-Hep. Moreover, in the presence of a polyanion the fluorophore was far more resistant to quenching by acrylamide. These results provide compelling evidence that factor XIa binding to the polyanions, dextran sulfate and heparin, results in inhibition of the enzyme by an allosteric mechanism.     

Structural and microtubule binding properties of tau mutants of frontotemporal dementias

Several mutations in the gene encoding the microtubule-associated protein tau are responsible for the formation of neurofibrillary inclusions in frontotemporal dementia with Parkinsonism linked to chromosome 17 (FTDP-17). Here we present the high-resolution characterization of the conformational properties of two FTDP-17 mutants of the four-repeat domain of tau, P301L and DeltaK280, and their properties for binding to polyanions and microtubules. Multidimensional NMR spectroscopy shows that the mutations do no lead to a significant increase in the level of beta-structure in their monomeric state, even though the mutations strongly promote beta-structure during aggregation. However, local structural changes are induced in the second repeat. These changes only weakly affect the binding to the polyanion heparin, which promotes paired helical filament formation. The extent of binding to microtubules, however, is strongly decreased. Our results demonstrate that the reversible binding of tau to microtubules involves specific interactions, which are not essential for binding to polyanions.     

DNA-polycation complexation and polyplex stability in the presence of competing polyanions

Polyelectrolyte complex (polyplex) formation was studied by employing tapping mode atomic force microscopy (AFM) and an ethidium bromide fluorescence assay. The polycations chitosan and poly-L-lysine were used to compact DNA and the stability of the polyplexes was evaluated upon exposure to competing polyanions (alginate and xanthan). Furthermore, the relative preference of these polycations for DNA and the competing polyanion was investigated. The results showed that neither poly-L-lysine nor chitosan displayed any selectivity in binding to DNA relative to the competing polyanions, demonstrating the importance of electrostatics in the binding of a polycation to a polyanion. However, the ability of the polyanions to destabilize the DNA-polycation complexes depended on both the polyanion and the polycation employed, indicating that polymer-specific properties are also important for the complexation behavior and polyplex stability. Destabilization experiments further showed that annealing yielded complexes that were less prone to disruption upon subsequent exposure to alginate. Annealing experiments of plasmid DNA-chitosan complexes showed an increased fraction of rods following temperature treatment, indicating that the rods most likely are the more stable morphology for this system.     

Selective interactions of polyanions with basic surfaces on human immunodeficiency virus type 1 gp120

It is well established that the gp120 V3 loop of T-cell-line-adapted human immunodeficiency virus type 1 (HIV-1) binds both cell-associated and soluble polyanions. Virus infectivity is increased by interactions between HIV-1 and heparan sulfate proteoglycans on some cell types, and soluble polyanions such as heparin and dextran sulfate neutralize HIV-1 in vitro. However, the analysis of gp120-polyanion interactions has been limited to T-cell-line-adapted, CXCR4-using virus and virus-derived gp120, and the polyanion binding ability of gp120 regions other than the V3 loop has not been addressed. Here we demonstrate by monoclonal-antibody inhibition, labeled heparin binding, and surface plasmon resonance studies that a second site, most probably corresponding to the newly defined, highly conserved coreceptor binding region on gp120, forms part of the polyanion binding surface. Consistent with the binding of polyanions to the coreceptor binding surface, dextran sulfate interfered with the gp120-CXCR4 association while having no detectable effect on the gp120-CD4 interaction. The interaction between polyanions and X4 or R5X4 gp120 was readily detectable, whereas weak or undetectable binding was observed with R5 gp120. Analysis of mutated forms of X4 gp120 demonstrated that the V3 loop is the major determinant for polyanion binding whereas other regions, including the V1/V2 loop structure and the NH(2) and COOH termini, exert a more subtle influence. A molecular model of the electrostatic potential of the conserved coreceptor binding region confirmed that it is basic but that the overall charge on this surface is dominated by the V3 loop. These results demonstrate a selective interaction of gp120 with polyanions and suggest that the conserved coreceptor binding surface may present a novel and conserved target for therapeutic intervention.     

Polyanion binding accelerates the formation of stable and low‐toxic aggregates of ALS‐linked SOD1 mutant A4V

The toxic property thus far shared by both ALS‐linked SOD1 variants and wild‐type SOD1 is an increased propensity to aggregation. However, whether SOD1 oligomers or aggregates are toxic to cells remains to be well defined. Moreover, how the toxic SOD1 species are removed from intra‐ and extracellular environments also needs to be further explored. The DNA binding has been shown to be capable of accelerating the aggregatio\n of wild‐type and oxidized SOD1 forms under acidic and neutral conditions. In this study, we explore the binding of DNA and heparin, two types of essential life polyanions, to A4V, an ALS‐linked SOD1 mutant, under acidic conditions, and its consequences. The polyanion binding alters the A4V conformation, neutralizes its local positive charges, and increases its local concentrations along the polyanion chain, which are sufficient to lead to acceleration of the pH‐dependent A4V aggregation. The accelerated aggregation, which is ascribed to the polyanion binding‐mediated removal or shortening of the lag phase in aggregation, contributes to the formation of amorphous A4V nanoparticles. The prolonged incubation with polyanions not only results in the complete conversion of likely soluble toxic A4V oligomers into non‐ and low‐toxic SDS‐resistant aggregates, but also increases their stability. Although this is only an initial step toward reducing the toxicity of SOD1 mutants, the accelerating role of polyanions in protein aggregation might become one of the rapid pathways that remove toxic forms of SOD1 mutants from intra‐ and extracellular environments. Proteins 2014; 82:3356–3372. © 2014 Wiley Periodicals, Inc.     

Effect of polyanion on the acidic conformational transition of native and denatured ferricytochrome c. Circular dichroism study

Interaction of polyanion poly(vinylsulfate) with oxidized cytochrome c (cyt c) significantly affects the protein main characteristics. One of them, pKa value of acidic transition, was shifted from an apparent pKa value 2.5 (typical for cyt c in low ionic strength solvent) to approximately 5.20 +/- 0.15 upon polyanion binding to the protein, pointing to a likely involvement of histidines 26 and/or 33 in the protein acidic transition in complex with the polyanion. The acidic transition followed at 6 different wavelengths all over circular dichroism spectrum, monitoring different parts of the protein structure, revealed basically two-state character process. Only ellipticity at 262 nm indicated a low-cooperative pH-induced conformational transition in heme region with an apparent pKa approximately 4.34 +/- 0.25 in accordance with absorbance change at 620 nm. Polyanion also interacts with chemically-denatured (in the presence of 9 mol/l urea) state of the protein as it follows from stabilization of protein residual structure at acidic pH and its effect on pKa value of acidic transition of chemically-denatured cyt c. Destabilization effect of polyanions on native and, on the other hand, stabilization influence on partially unfolded conformations of the protein are discussed with an implication for their chaperone-like properties in vivo and in vitro.     

Effect of polyanions on the spectroscopic properties of the nitric oxide derivative of ferrous dromedary (Camelus dromedarius) hemoglobin

The effect of inositol hexakisphosphate, 2,3-diphosphoglycerate, dextran sulphate, and heparin on the spectroscopic (absorbance, circular dichroism, EPR) properties of the nitric oxide derivative of ferrous dromedary (Camelus dromedarius) hemoglobin was investigated. The results obtained show that: (i) all polyanions bind to the protein at the same sites, but with different affinities; (ii) polyanions affect the protein conformation of the ferrous nitrosyl derivative in a different way with respect to aquo-ferric and ferrous oxy dromedary hemoglobin; and (iii) the data obtained provide further independent evidence for the existence in dromedary hemoglobin of two functionally distinct polyanion binding sites that affect the conformational equilibrium of the protein in opposite ways.     

Conformational flexibility, hydration and state parameter fluctuations of fibroblast growth factor-10: effects of ligand binding

Differential effects of ligand binding on local and global fibroblast growth factor-10 (FGF-10) flexibility and stability have been investigated utilizing a variety of experimental and computational techniques. Normal mode analysis was used to predict the low frequency motions and regional flexibility of FGF-10. Similarly, regional variations in local folding/unfolding equilibria were characterized with the COREX/BEST algorithm. Experimental adiabatic and isothermal compressibilities of FGF-10 alone and in the presence of polyanions are compared. Furthermore, the effect of polyanions on the coefficient of thermal expansion is compared. Measurements of density, heat capacity, compressibility, and expansibility were combined to calculate experimentally determined volume and enthalpy fluctuations. Global effects of polyanions on FGF-10 flexibility, thermodynamic fluctuations, and hydration vary depending on the size and charge density of the polyanion. Local effects of polyanions were investigated utilizing time-resolved fluorescence spectroscopy and red edge excitation spectroscopy (REES). Increased rigidity of the protein matrix or an increased solvent response surrounding the Trp residues is observed in the presence of polyanions. Similarly, time-resolved spectroscopy reveals increased ground state heterogeneity and increased dipole relaxation on the time scale of fluorescence for FGF-10 in the presence of polyanions. These polyanions increase heterogeneity, global flexibility, and fluctuations while increasing the melting temperature (Tm) of FGF-10.     

Aggregation of ampholine on heparin and other acidic polysaccharides in isoelectric focusing.

The mechanism of complexation of pI range 3.5--5 Ampholine to heparin in isoelectric focusing has been explored by the dye-binding technique at different pH values in solution. There is no significant interaction between heparin and Ampholine at pH 6.7. Weak, or selective, binding occurs at pH 5.1, and very strong interaction at pH 3.5. In the latter system, the Ampholine components appear to behave as polycations due to their ordered sequence of positive charges, each two methylene groups apart, which favors a strong binding to polyanions. In addition, there appear to be variable stoichiometries for the strong binding between heparin and Ampholine, depending on their relative amounts. It is proposed that at a low ratio of heparin to Ampholine (Ampholine excess), aggregation is perpendicular to the heparin chain, with the end ammonium charge of each Ampholine molecule neutralizing one negative charge along the heparin molecule; at higher ratios (heparin excess), the bound Ampholine segment is aligned parallel to the heparin molecule, so that on the average one Ampholine component neutralizes approx. three negative charges. The banding of heparin in isoelectric focusing in the pH range 3.0--4.5 can be explained by aggregation of the various components on heparin in amounts dependent upon the net charge on the Ampholine species at the given pH, and upon the changing stoichiometries as a function of the variation in ratio of heparin to Ampholine along the pH gradient. Binding of Ampholine to polygalacturonate was also demonstrated in excess Ampholine in a pH range dependent on the degree of protonation of the carboxyl groups of this acidic polysaccharide as well as on the net positive charge of the Ampholine. The aggregation seen at pH 4.2--4.5 led to the prediction and subsequent demonstration that polygalacturonate would also exhibit binding upon isoelectric focusing. This supports the hypothesis that aggregation of Ampholine on polyanions having sufficient charge density is a general phenomenon which can lead to spurious banding of certain polymers at appropriate pH ranges in isoelectric focusing. On the basis of their behavior in isoelectric focusing at pH 3.0--4.5, strength of aggregation of the polyanions studied appears to be heparin A = heparin B greather than polyglutamate greater than carboxyl-reduced heparin B greater than polygalacturonic acid.     

The HIV-1 envelope glycoprotein gp120 features four heparan sulfate binding domains, including the co-receptor binding site

It is well established that the human immunodeficiency virus-1 envelope glycoprotein surface unit, gp120, binds to cell-associated heparan sulfate (HS). Virus infectivity is increased by such interaction, and a variety of soluble polyanions efficiently neutralize immunodeficiency virus-1 in vitro. This interaction has been mainly attributed to the gp120 V3 loop. However, although evidence suggested that this particular domain does not fully recapitulate the binding activity of the protein, the ability of HS to bind to other regions of gp120 has not been completely addressed, and the exact localizations of the polysaccharide binding sites are not known. To investigate in more detail the structural basis of the HS-gp120 interaction, we used a mapping strategy and compared the heparin binding activity of wild type and mutant gp120 using surface plasmon resonance-based binding assays. Four heparin binding domains (1-4) were identified in the V2 and V3 loops, in the C-terminal domain, and within the CD4-induced bridging sheet. Interestingly, three of them were found in domains of the protein that undergo structural changes upon binding to CD4 and are involved in co-receptor recognition. In particular, Arg(419), Lys(421), and Lys(432), which directly interact with the co-receptor, are targeted by heparin. This study provides a complete account of the gp120 residues involved in heparin binding and identified several binding surfaces that constitute potential target for viral entry inhibition.     

The effect of macromolecular polyanions on the functional properties of human hemoglobin.

The binding of dextran sulphate and heparin to human hemoglobin and their effect on the properties of gas transport have been investigated. Both dextran sulphate and heparin are strongly bound by oxy-hemoglobin as well as deoxyhemoglobin and the stoichiometry of the binding (polyanion/tetrameric hemoglobin) is less than unity; sedimentation analysis gives indication for the existence of octomers. The oxygen affinity of hemoglobin is decreased, to the same extent, by both dextran sulphate and heparin. This effect is pH-dependent. In addition the polyanions affect the position and the magnitude of the Bohr effect. In the presence of dextran sulphate the recombination of hemoglobin with carbon monoxide after flash photolysis is biphasic and the fraction of quickly reacting material increases with dilution of the protein.     

Modification of the structural and redox properties of cytochrome c by heteropolytungstate binding

Complex formation between horse heart ferricytochrome c and large three-dimensional polyanions has been investigated, in order to study the influence of surface electrostatic interactions on the structural and redox properties of cytochrome c. Cytochrome c binds the large heteropolytungstates (NaSb9W21O86)18- and (KAs4W40O140)27- with a 1/1 polyanion/cytochrome c ratio, and the smaller ion (SiW11O39)8- with a 2/1 ratio. Upon complexation, cytochrome c undergoes structural changes that are dependent on the size and charge of the polyanion, and on the pH and ionic strength of the medium. Three different forms of complexed cytochrome c have been characterized by optical and EPR spectroscopies, in the pH range 6.5-8: an N form, close to the native structure, an A form, analogous to cytochrome c in acidic medium, and a novel B form in which the heme pocket is open but the iron remains low-spin. The redox potential of cytochrome c is lowered to 250-220 mV (vs. NHE) in the N form, and to 80 mV in the B form.     

Parathyroid hormone binding to cultured avian osteoclasts.

Parathyroid hormone (PTH) increases serum calcium concentration via a controversial cellular mechanism. We investigated whether PTH binds avian osteoclasts. Isolated hypocalcaemic hen osteoclasts were incubated with [125I]--bovine PTH (1-84). Specific binding of the hormone to the cells, which reached the equilibrium within 60 min, was observed. Half maximal binding was reached by 10 min. Binding was competitively inhibited by increasing doses of unlabeled PTH, and was about 55% displaced by adding, at the equilibrium, 10(-6) M unlabeled PTH. Autoradiography demonstrated specific label on the osteoclast. The cellular mechanism activated by the hormone remains to be elucidated.     

Structural appearance of linker histone H1/siRNA complexes

Efficient non-viral vectors for the in vivo siRNA transfer are still being searched for. Comparing the differences of the structural appearance of siRNA and pDNA one would assume differences in the assembling behaviour between these polyanions when using polycationic vectors such as nuclear proteins. The spontaneous assembly of nuclear proteins such as histone H1 (H1) with pDNA as polyanion which has intensively been investigated over the last decade, showed a particulate structure of the resulting complexes. For an efficient in vivo use small almost monomolecular structures are searched for. Using siRNA as the polyanion might enforce this structural prerequisite lacking unwanted aggregation processes, exploiting the molecular size of siRNA. We therefore investigated the structure of H1/siRNA complexes. Five commonly used methods characterizing the resulting assemblies such as retardation gels, static and dynamic light scattering, reduction of ethidium bromide fluorescence, analytical ultracentrifugation, and electron microscopy were used. From analytical ultracentrifugation we learned that under physiological salt conditions the siRNA-H1 binding was not cooperative, even though the gel analysis showed disproportionation which would be an indication for a cooperative binding mode. H1 formed very small and stable complexes with siRNA at a molar ratio of 1:1 and 1:2. In order to find out if the observed structural appearance of the H1/siRNA complexes is due to unspecific charge effects only or to special features of H1, polylysine was included in the study. Low molecular weight polylysine (K₁₆) showed also non-cooperative binding with siRNA.     

A network-based analysis of polyanion-binding proteins utilizing yeast protein arrays

The high affinity of certain cellular polyanions for many proteins (polyanion-binding proteins (PABPs)) has been demonstrated previously. It has been hypothesized that such polyanions may be involved in protein structure stabilization, stimulation of folding through chaperone-like activity, and intra- and extracellular protein transport as well as intracellular organization. The purpose of the proteomics studies reported here was to seek evidence for the idea that the nonspecific but high affinity interactions of PABPs with polyanions have a functional role in intracellular processes. Utilizing yeast protein arrays and five biotinylated cellular polyanion probes (actin, tubulin, heparin, heparan sulfate, and DNA), we identified proteins that interact with these probes and analyzed their structural and amino acid sequence requirements as well as their predicted functions in the yeast proteome. We also provide evidence for the existence of a network-like system for PABPs and their potential roles as critical hubs in intracellular behavior. This investigation takes a first step toward achieving a better understanding of the nature of polyanion-protein interactions within cells and introduces an alternative way of thinking about intracellular organization.     

A novel method to demonstrate parathyroid hormone binding on unfixed living target cells in culture

We present a rapid and specific procedure that enables one to identify living target cells of peptide hormones within heterogeneous cell populations by means of morphological demonstration of ligand-receptor binding. This is exemplified using a biotinylated parathyroid hormone (PTH) analogue (biotinyl-b-PTH 1-84) which reacts with avidin-fluorescein (avidin-FITC) as a histochemical marker. The experiments revealed a fine dot-like distribution pattern of binding after 1-5 min of incubation at room temperature, changing to a more clustered pattern after 10 min of incubation. Competition of labeled and unlabeled PTH exhibited lack of staining if unlabeled PTH was applied in excess. The results suggest that the demonstrated binding sites represent specific receptors for PTH on living target cells.     

Heparin binding to the urokinase kringle domain.

The binding of urokinase to immobilized heparin and dextran sulfate was studied using activity assays of the bound urokinase. The markedly higher binding observed with high M(r) urokinase compared to low M(r) urokinase indicated a role for the amino-terminal fragment (ATF). This was confirmed by the use of inactive truncated urokinase and monoclonal antibodies specific for the ATF in competition assays of urokinase binding. Antibody competition assays suggested a site in the kringle domain, and a synthetic decapeptide Arg-52-Trp-62 from the kringle sequence (kringle numbering convention) was competitive in assays of urokinase binding to dextran sulfate and heparin. Heparin binding to the urokinase kringle was unambiguously demonstrated via 1H NMR spectroscopy at 500 MHz. Effective equilibrium association constants (K(a)*) were determined for the interaction of isolated kringle fragment and low M(r) heparin at pH 7.2. The binding was strong in salt-free 2H2O (K(a)* approximately 57 mM-1) and remained significant in 0.15 M NaCl (K(a)* approximately 12 mM-1), supporting a potential physiological role for the interaction. This is the first demonstration of a function for the kringle domain of urokinase, and it suggests that while the classical kringle structure has specificity for lysine binding, there may also exist a class of kringles with affinity for polyanion binding.     

Synthetic and natural polyanions induce cytochrome c release from mitochondria in vitro and in situ

A synthetic polyanion composed of styrene, maleic anhydride, and methacrylic acid (molar ratio 56:37:7) significantly inhibited the respiration of isolated rat liver mitochondria in a time-dependent fashion that correlated with 1) collapse of the mitochondrial membrane potential and 2) high amplitude mitochondrial swelling. The process is apparently Ca(2+) dependent. Since it is blocked by cyclosporin A, the process is ascribed to induction of the mitochondrial permeability transition. In mitoplasts, i.e., mitochondria lacking their outer membranes, the polyanion rapidly blocked respiration. After incubation of rat liver mitochondria with the polyanion, cytochrome c was released into the incubation medium. In solution, the polyanion modified by conjugation with fluorescein formed a complex with cytochrome c. Addition of the polyanion to cytochrome c-loaded phosphatidylcholine/cardiolipin liposomes induced the release of the protein from liposomal membrane evidently due to coordinated interplay of Coulomb and hydrophobic interactions of the polymer with cytochrome c. We conclude that binding of the polyanion to cytochrome c renders it inactive in the respiratory chain due to exclusion from its native binding sites. Apparently, the polyanion interacts with cytochrome c in mitochondria and releases it to the medium through breakage of the outer membrane as a result of severe swelling. Similar properties were demonstrated for the natural polyanion, tobacco mosaic virus RNA. An electron microscopy study confirmed that both polyanions caused mitochondrial swelling. Exposure of cerebellar astroglial cells in culture to the synthetic polyanion resulted in cell death, which was associated with nuclear fragmentation.     

A new map of glycosaminoglycan and C3b binding sites on factor H

Human complement factor H, consisting of 20 complement control protein (CCP) modules, is an abundant plasma glycoprotein. It prevents C3b amplification on self surfaces bearing certain polyanionic carbohydrates, while complement activation progresses on most other, mainly foreign, surfaces. Herein, locations of binding sites for polyanions and C3b are reexamined rigorously by overexpressing factor H segments, structural validation, and binding assays. As anticipated, constructs corresponding to CCPs 7-8 and 19-20 bind well in heparin-affinity chromatography. However, CCPs 8-9, previously reported to bind glycosaminoglycans, bind neither to heparin resin nor to heparin fragments in gel-mobility shift assays. Introduction of nonnative residues N-terminal to a construct containing CCPs 8-9, identical to those in proteins used in the previous report, converted this module pair to an artificially heparin-binding one. The module pair CCPs 12-13 does not bind heparin appreciably, notwithstanding previous suggestions to the contrary. We further checked CCPs 10-12, 11-14, 13-15, 10-15, and 8-15 for ability to bind heparin but found very low affinity or none. As expected, constructs corresponding to CCPs 1-4 and 19-20 bind C3b amine coupled to a CM5 chip (K(d)s of 14 and 3.5 microM, respectively) or a C1 chip (K(d)s of 10 and 4.5 microM, respectively). Constructs CCPs 7-8 and 6-8 exhibit measurable affinities for C3b according to surface plasmon resonance, although they are weak compared with CCPs 19-20. Contrary to expectations, none of several constructs encompassing modules from CCP 9 to 15 exhibited significant C3b binding in this assay. Thus, we propose a new functional map of factor H.     

Crystal structures of aprotinin and its complex with sucrose octasulfate reveal multiple modes of interactions with implications for heparin binding

The crystal structures of aprotinin and its complex with sucrose octasulfate (SOS), a polysulfated heparin analog, were determined at 1.7-2.6 Å resolutions. Aprotinin is monomeric in solution, which associates into a decamer at high salt concentrations. Sulfate ions serve to neutralize the basic amino acid residues of aprotinin to stabilize the decameric aprotinin. Whereas SOS interacts with heparin binding proteins at 1:1 molar ratio, SOS was surprisingly found to induce strong agglutination of aprotinins. Five molecules of aprotinin interact with one molecule of the sulfated sugar, which is stabilized by electrostatic interactions between the positively charged residues of aprotinin and sulfate groups of SOS. The multiple binding modes of SOS with five individual aprotinin molecules may represent the diverse patterns of potential heparin binding to aprotinin, reflecting the interactions of densely packed protein molecules along the heparin polymer.