The interaction of myelin basic protein with tubulin and the inhibition of tubulin carboxypeptidase activity

Tubulin carboxypeptidase was found to be inhibited by myelin basic protein in a concentration dependent manner. The inhibition was produced by the interaction between myelin basic protein with the substrate. As a consequence of this interaction, turbid insoluble aggregates were formed at either 5 degrees or 37 degrees C. The turbidity increased by increasing the myelin basic protein concentration and it reached a plateau at a molar ratio of myelin basic protein to tubulin dimer of about 6. At plateau, the molar ration in the insoluble aggregates was about 6. When tubulin was in excess, the formation of the insoluble aggregates was diminished. However, if the excess of tubulin was added after the formation of the aggregates, the turbidity was not significantly affected. Turbidity was diminished by increasing the ionic strength.     

Physical-chemical interaction of heparin and human plasma low-density lipoproteins

This study characterizes the physical-chemical interactions of heparin with human plasma low-density lipoproteins (LDL). A high reactive heparin (HRH) specific for the surface determinants of LDL was isolated by chromatography of commercial bovine lung heparin on LDL immobilized to AffiGel-10. HRH was derivatized with fluoresceinamine and repurified by affinity chromatography, and its interaction with LDL in solution was monitored by steady-state fluorescence polarization. Binding of LDL to fluoresceinamine-labeled HRH (FL . HRH) was saturable, reversible, and specific; HRH stoichiometrically displaced FL . HRH from the soluble complex, and acetylation of lysine residues on LDL blocked heparin binding. Titration of FL.HRH with excess LDL yielded soluble complexes with two LDL molecules per heparin chain (Mr 13,000) characterized by an apparent Kd of 1 microM. Titration of LDL with excess HRH resulted in two classes of heparin binding with two and five heparin molecules bound per LDL and apparent Kd values of 1 and 10 microM, respectively. At physiological pH and ionic strength, the soluble HRH-LDL complexes were maximally precipitated with 20-50 mM Ca2+. Insoluble complexes contained 2-10 HRH molecules per LDL with the final product stoichiometry dependent on the ratio of the reactants. The affinity of HRH for LDL in the insoluble complexes was estimated between 1 and 10 microM. Insoluble LDL-heparin complexes were readily dissociated with 1.0 M NaCl, and their formation was prevented by acetylation of the lysine residues on LDL.     

The two dimensional structure of tetrazolium-mucopolysaccharide complexes deduced from reactivity studies.

The formation of complexes between mucopolysaccharides and tetrazolium salts has been studied both by turbidimetry and nephelometry. The technique of laser nephelometry allows the detection of colloidal aggregates in systems which may, by turbidimetric methods, be ambiguous. The results indicate that binding of tetrazolium salts to polyanions can result in soluble as well as insoluble complexes; the monotetrazolium salts form soluble complexes and the ditetrazolium compounds form insoluble complexes. The insoluble complexes are stable at relatively low pH, and are disrupted during reduction to the formazan. Complex formation is decreased at high ratios of heparin to tetrazolium, and divalent cations, even at high concentration, do not precipitate mucopolysaccharides. It is concluded that stable ionic interactions with spatial charge separation are responsible for the cross linking of the mucopolysaccharides and the formaiton of large insoluble aggregates.     

Modifications of low-density lipoprotein induced by arterial proteoglycans and chondroitin-6-sulfate

Association of low-density lipoproteins (LDL) with arterial chondroitin sulfate proteoglycans (CSPG) appears to contribute to their deposition in the extracellular intimal compartment and to its internalization by macrophages. CSPG and LDL interact by ionic bridges with formation of soluble and insoluble complexes. We studied the alterations on LDL structure induced by its association with arterial CSPG and other glycosaminoglycans (GAG). In soluble complexes, at low and physiological ionic strength, arterial CSPG and sulfated GAG modify the kinetics of apoB-100 proteolysis by trypsin. However, less marked alterations in the peptide patterns were observed with proteinase V8 and almost none with thermolysin. This is indirect evidence that the presence of CSPG and GAG modified the exposure of polar regions of apoB-100 in LDL. Competitive binding experiments with agarose-bound heparin and soluble GAG also suggest that after formation of insoluble complexes with arterial CSPG and resolubilization the exposure of Lys, Arg-rich segments of apoB-100 is increased. Results from differential scanning calorimetry and differential thermal spectrophotometry showed that the CSPG and GAG-induced modifications reduced the thermal stability of the surface and core in LDL. If present in vivo, the structural alterations of polar segments of the LDL protein moiety may influence the outcome of its alteration with the arterial mesenchyma.     

Polyelectrolyte Complexes: Interactions between Lignosulfonate and Chitosan

The interactions between high molecular weight chitosans (fraction of acetylated units (F(A)) = 0.10 or 0.50) and lignosulfonates of varying molecular weights (5000-400000 g/mol) and degrees of sulfonation (0.39-0.64) were studied. Lignosulfonates and chitosans form primarily insoluble polyelectrolyte complexes when mixed at pH 4.5, where the polymers are oppositely charged. In contrast, no complex formation occurred at pH 8, as shown by using a chitosan with F(A) = 0.50, which is soluble at this pH. Thus, a positively charged chitosan is a prerequisite for interactions leading to insoluble complexes with lignosulfonates. It is therefore unlikely that complex formation involves the formation of covalent sulfonylamide linkages as proposed in the literature. The composition of the complexes varied to some degree with the mixing ratio and molecular weight of lignosulfonate, but in most cases compact complexes with a sulfonate/amino ratio close to 1.0 were formed, suggesting that all sulfonate groups are accessible for interactions with chitosan. The influence of the ionic strength and temperature on the complex formation and the behavior of the precipitated complexes were in agreement with that expected for classical polyelectrolyte complexes where the associative phase separation is primarily governed by the increase in entropy due to the release of counterions.     

Insoluble complex formation between low density lipoprotein and heparin. A 31P-NMR study

31P-NMR has been used to probe the motions of the phosphate moiety of phospholipid head-groups in samples of human low density lipoprotein (LDL) in which particle tumbling has been greatly reduced by increasing the viscosity of the medium, by forming an LDL gel by ultracentrifugation, or by precipitation with heparin. The 31P-NMR spectra of LDL gel give broad "powder-like" lineshapes, with the sign and magnitude of the anisotropy characteristic of the bilayer mesophase, which narrow as the temperature is raised from 5 to 45 degrees C. This narrowing occurs over the same temperature range as the core cholesteryl ester liquid-crystalline to liquid phase transition, suggesting interactions between the surface and core. The 31P lineshapes of LDL-heparin insoluble complexes are also "powder-like", but are broader than native LDL at all temperatures studied. The spectra were simulated assuming an axially-symmetric shielding tensor motionally narrowed by Brownian isotropic diffusion [Burnell et al. (1980) Biochim. Biophys. Acta 603, 63-69], allowing determination of the lateral diffusion coefficients, DT, and the chemical shift anisotropy, delta sigma, of the monolayer phospholipids. Relative to LDL gel, the temperature-dependence of DT was reduced in the LDL-heparin insoluble complexes, and delta sigma was increased from 50 to 60 ppm. The results suggest that insoluble complex formation slows phospholipid lateral diffusion in the LDL monolayer and alters the orientation and/or order of the head-group.     

Soluble heparin proteoglycans released from stimulated mast cells induce uptake of low density lipoproteins by macrophages via scavenger receptor-mediated phagocytosis.

Stimulation of rat serosal mast cells in vitro triggers exocytosis of secretory granules from their cytoplasm. Thereupon, the granules lose their perigranular membranes, and about 40% of the heparin proteoglycans and all of the chondroitin sulfate proteoglycans that they initially contained are released into the incubation medium. At physiologic ionic strength and calcium ion concentration, the solubilized heparin proteoglycans, but not the chondroitin sulfate proteoglycans, form insoluble complexes with the low density lipoproteins (LDL) present. We calculated that the heparin proteoglycans could bind approximately seven times their own mass (Mr about 1 x 10(6)) of LDL cholesterol. Using gold-labeled LDL, we observed massive phagocytosis of the heparin proteoglycan-LDL complexes by cultured mouse macrophages in vitro, which was inhibited by cytochalasin B. Uptake of LDL by mouse macrophages was 45-fold higher in the presence of solubilized heparin proteoglycans than in their absence, and continued unabated over a 72-h period, indicating that the uptake process was not under negative feedback control. Excess amounts of acetyl-LDL or polyinosinic acid inhibited the uptake of these insoluble heparin proteoglycan-LDL complexes, indicating that their phagocytosis was mediated by scavenger receptors of the acetyl-LDL receptor type. The experiments reveal the following pathophysiologic mechanism relevant to atherogenesis: stimulated mast cells secrete soluble heparin proteoglycans capable of forming insoluble complexes with LDL and thereby trigger uptake of LDL by macrophages through scavenger receptor-mediated phagocytosis.     

Effect of trypsin treatment on the heparin- and receptor-binding properties of human plasma low-density lipoproteins

The effect of trypsin treatment on the heparin- and receptor-binding properties of human plasma low-density lipoproteins (LDL) was examined. LDL were treated with trypsin (2% by weight) for 16 h at 37 degrees C, and the trypsinized core particles (T-LDL) were isolated by gel permeation chromatography on Sepharose CL-4B. Trypsin degraded the apolipoprotein B moiety (Mr = 550,000) of LDL into numerous peptides of Mr less than 110,000, resulting in the release of 25% +/- 5% (n = 6) of its surface-associated protein. Relative to LDL, T-LDL had an increased phospholipid/protein ratio, decreased flotation density and alpha-helical structure, and increased fluidity of the surface and core constituents. Compared to LDL, T-LDL showed a 60% decreased capacity to suppress [1-14C]acetate incorporation into cellular sterols consistent with decreased binding to the LDL receptor. In contrast, T-LDL showed an enhanced capacity to form soluble complexes with heparin in the absence and presence of 2 mM Ca2+. Between 5 and 25 mM Ca2+, both LDL and T-LDL were maximally precipitated by heparin; the stoichiometry of the insoluble complexes (uronic acid/phospholipid, w/w) was 0.054 +/- 0.004 and 0.055 +/- 0.005 (n = 18) for LDL and T-LDL, respectively. Thus, trypsin treatment significantly diminished the lipoprotein's interaction with cells but not with heparin. This finding suggests that proteolysis may decrease receptor-mediated uptake of LDL without diminishing the lipoprotein's reactivity with acellular components of the arterial wall.     

人动脉壁蛋白聚糖与血清脂蛋白形成的不溶性复合物

本文报道了人主动脉壁中正常及异常(脂纹,FS)区的三种蛋白聚糖(PG)即:硫酸软骨素PG(CSPG)、硫酸皮肤素—硫酸软骨素PG(DSCSPG)及硫酸乙酰肝素PG(HSPG)与血清极低密度脂蛋白(VLDL)及低密度脂蛋白(LDL)所形成的不溶性复合物。在30mmol/L Ca~(2+)对,三种PG都能与这两种脂蛋白形成不溶性复合物,随放置时间的增加,形成的复合物都发生解离,但其复合物形成的曲线及解离程度明显不同。DSCSPG与CSPG比较,前者与两种脂蛋白更易形成不溶性复合物且不易解离。HSPG与两种脂蛋白形成不溶性复合物所需时间远大于CSPG及DSCSPG。FS区及正常区三种PG形成复合物曲线类型相似,异常区CSPG、DSCSPG与VLDL形成的复合物量低于正常区的相应PG,而与VLDL则高于正常区的相应PG。异常区的HSPG与两种脂蛋白形成不溶性复合物的量均高于正常区。     

Intermolecular complexation and phase separation in aqueous solutions of oppositely charged biopolymers

Turbidity measurements performed at 450nm were used to follow the process of complex formation, and phase separation in gelatin-agar aqueous solutions. Acid (Type-A) and alkali (Type-B) processed gelatin (polyampholyte) and agar (anionic polyelectrolyte) solutions, both having concentration of 0.1% (w/v) were mixed in various proportions, and the mixture was titrated (with 0.01 M HCl or NaOH) to initiate associative complexation that led to coacervation. The titration profiles clearly established observable transitions in terms of the solution pH corresponding to the first occurrence of turbidity (pH(C), formation of soluble complexes), and a point of turbidity maximum (pH(phi), formation of insoluble complexes). Decreasing the pH beyond pH(phi) drove the system towards precipitation. The values of pH(C) and pH(phi) characterized the initiation of the formation of intermolecular charge neutralized soluble aggregates, and the subsequent formation of microscopic coacervate droplets. These aggregates were characterized by dynamic light scattering. It was found that Type-A and -B gelatin samples formed soluble intermolecular complexes (and coacervates) with agar molecules through electrostatic and patch-binding interactions, respectively.     

人血清脂蛋白与糖胺聚糖及人主动脉蛋白聚糖的相互作用

本文报道了在[Ca~(2+)]=30mmol/L时,人血清或人血清脂蛋白与各种糖胺聚糖(GAG)及人主动脉两种蛋白聚糖(PG)的相互作用。GAG与血清的作用能力为6—硫酸软骨素(C6—S)>肝素(Hep)>4—硫酸软骨素(C4—S)>透明质酸(HA)>硫酸皮肤素(DS)。极低密度脂蛋白(VLDL)及低密度脂蛋白(LDL)可与肝素作用形成不溶性复合物,而高密度脂蛋白(HDL)则不能。人主动脉硫酸软骨素—PG(CS—PG)、硫酸皮肤素—硫酸软骨素—PG(DS—CS—PG)与血清形成不溶性复合物的曲线类型不同,后者的类型似有利于DS—CS—PG与血清脂蛋白结合从而使之在动脉壁沉积。     

The effect of heparin on structural and functional properties of low density lipoproteins

Heparin binding to human low density lipoproteins (LDL) and the effect of heparin on the ability of LDL to bind to the LDL receptor has been investigated. Emphasis has been made on the physiological conditions of temperature, pH and the ionic strength. Intrinsic fluorescence spectroscopy of LDL has been applied to follow heparin binding. Fluorescence anisotropy has been measured to describe the changes in apoB and dansyl-heparin dynamics upon binding. Eu3+-labeled LDL binding to the intact LDL receptor has been monitored by time-resolved fluorescence spectroscopy technique. We have found that heparin binds to LDL under the physiological conditions, probably by Van der Waals interactions and hydrogen bonding. Temperature seems to be the most important factor influencing the interaction. Furthermore, the presence of heparin inhibits LDL binding to the intact LDL receptor that might have consequences on the cholesterol metabolism in vivo.     

Dynamic light scattering studies on hydrodynamic properties of fibrinogen-fibronectin complex.

A high molecular weight 'cryogel' was obtained as insoluble complexes by cold incubation at near-freezing temperatures from heparinized plasma of patients with rheumatoid arthritis. After the cryogel was solubilized at 37 degrees C, 1:1 complex of fibrinogen and fibronectin was purified at room temperature by affinity chromatography on a gelatin-Sepharose 4B. Hydrodynamic properties of the complex were investigated as a function of temperature and NaCl concentration using a dynamic light scattering. The diffusion coefficients of the complex at 20 degrees C decreased with increasing of NaCl concentration as free fibronectin. The complex appears to be a more compact form at low ionic concentration, which is associated with conformational changes of fibronectin. The diffusion coefficient of the complex at 20 degrees C in 0.05 M TrisHCl(pII7.4) containing 0.5 M NaCl was estimated as 8.5 x 10(-8) cm2s-1. The complex did not dissociate over the temperature range from 20 to 37 degrees C. The diffusion coefficients of the complex decreased significantly at 12 degrees C and 40 degrees C. The thermal denaturation of fibrinogen molecule in the complex was observed at 40 degrees C. The CONTIN analysis of the light scattering data showed that the complex associated to form higher aggregates at 15 degrees C, but not at near-freezing temperature. The equilibrium between the complex and higher aggregates appeared reversible.     

Fibronectin (cold-insoluble globulin), VI. Influence of heparin and hyaluronic acid on the binding of native collagen.

Fibronectin of human plasma associated readily with denatured collagen but gave only a weak reaction with the native protein. In the presence of heparin, however, solutions of native collagen type III, and fibronectin produced precipitates at an ionic strength of 0.2. In the presence of fibronectin and optimal additions of heparin, up to 60% of soluble native 125I-collagen type III, but only about 10% of native 125I-collagen type I, were insolubilized. Heparin also enhanced the formation of insoluble complexes from fibronectin and denatured collagen type I and type III. In the absence of collagen 125I-fibronectin was partially precipitated by heparin. Electron micrographs showed filamentous structures. Collagen did not increase the amount of 125I-fibronectin precipitated by heparin unless a critical collagen concentration was exceeded. It is suggested that heparin induced the transition of fibronectin from a globular to an elongated form, capable of forming filamentous precipitates which adsorb native collagen. Hyaluronic acid and putrescine prevented the insolubilization of native collagen type III, by fibronectin and heparin.     

Aggregation and fibril formation of plasma fibronectin by heparin

The precipitation of plasma fibronectin by heparin in dependence on various parameters was investigated. Rising heparin concentration augmented the precipitates up to a maximum beyond which precipitation decreased. Yields close to 80% were obtained at low temperatures, but some precipitation was observed at 37 degrees C as well. Insolubilization was considerably dependent on the ionic strength, indicating that electrostatic forces play a major role in the aggregation of fibronectin. Calcium already prevented precipitation by heparin at low concentrations. If precipitation was performed on hydrophobized glass cover slides, the formation of fibrils visible by phase-contrast microscopy was observed. On hydrophilic surfaces amorphous precipitates were generally obtained, most likely due to trapping of aggregates by adsorption prior to their arrangement to fibrils. The results are discussed on the basis of a model assuming that heparin induces a conformational rearrangement of plasma fibronectin so that masked binding sites responsible for self-association become exposed.     

Preventive effect of egg yolk phosvitin on heat-insolubilization of egg white protein and its application to heat-induced egg white gel

The effects of phosvitin (PV) on insolubilization of egg white protein (EWP) and ovotransferrin (OT) were examined by measuring turbidity after heating at 80 degrees C in a pH range of 5 to 8. PV showed preventive ability against heat-insolubilization of EWP, especially heat-labile OT. The preventive ability of PV was reduced by adding NaCl to a PV-OT mixture on heating. Native PAGE and gel filtration analyses showed that PV prevented an insolubilization of heat-denatured OT through ionic interactions. The preventive effects of PV on insolubilization of EWP and OT resulted in the formation of a firm, transparent gel from EWP in coexistence with PV on heating. The addition of PV might make possible the preparation of liquid egg white without insoluble products even on heat-treatment at high temperatures.     

C-terminal cleavage of tubulin by subtilisin enhances ring formation

Following cleavage of alpha- and beta-tubulin C termini, under mild conditions we observed that microtubule-related polymers were formed, and also that ring aggregates were abundant. These ring aggregates were clearly detected by turbidity and electron microscope studies under standard assembly conditions. It was found that removal of the C-terminal fragments of tubulin (phosphocellulose-tubulin or Weisenberg tubulin) markedly favored Mg2(+)-induced ring formation. Binding of GDP to the exchangeable nucleotide site of cleaved tubulin further enhanced ring formation. The cleaved tubulin-GDP ring aggregates could be classified into three types: aggregates without apparent order, bidimensionally ordered ring aggregates, and stacks of rings. Temperature had little effect on the formation of these ring aggregates; however, they were very sensitive to ionic strength.     

Studies on the effect of various parameters on crotalarin-fetuin interaction.

With a view to optimise the interaction of crotalarin, a blood group A-specific lectin from the seeds of Crotalaria striata with fetuin the effect of various parameters on the reaction has been studied turbidimetrically. The formation of crotalarin-fetuin complex was dependent on time, temperature, pH and the ionic strength of the medium. The maximum turbidity appeared in 30 min at 20 degrees C and the pH optimum was 3.5. The binding constant (Ka) for crotalarin-fetuin interaction was 5.58 x 10(4) M-1 (pH 3.5) at 20 degrees C. Among the different inorganic salts tested, the cations with increasing concentrations had pronounced effect on binding. KCNS and KI, however, were noninhibitory. The turbidity slightly increased in presence of different sodium salts, whereas periodate and urea reduced the interaction. The different alcohols had no remarkable effect on the above reaction.     

Effect of limited tryptic treatment and sialic acid removal of low density lipoproteins on the glycosaminoglycan-lipoprotein interaction

This study was undertaken to determine whether limited tryptic digestion or sialic acid removal affects the internal structure of human serum low density lipoprotein (LDL) and to examine the role of the protein and carbohydrate moiety of LDL in the formation of LDL aortic glycosaminoglycan complexes. Results of investigations by differential scanning calorimetry (d.s.c.) showed that trypsin-treated and sialinidase-treated LDL exhibited the same thermotropic transitions as the control native LDL and thus indicated that partial proteolysis or desialylation did not produce an alteration in the organization of the lipid core of the LDL molecule. Formation of insoluble complexes with glycosaminoglycan (GAG) was significantly increased by prior treatment of LDL with trypsin, owing to an increase in the net negative charge; desialylation did not result in any alteration in reactivity of the LDL. It was also demonstrated that while in LDL cholesteryl esters of the LDL core exist in a liquid state at body temperature, in GAG-LDL complexes they occur in a mesomorphic liquid crystalline state. As there was no difference in this respect between the complexes prepared from native LDL, from trypsin treated LDL and from sialic acid-deficient LDL, it might be concluded that effect of GAG on the structure of the lipid core does not related to the protein or to the cabohydrate arrangement of the shell of the LDL particle.     

Lipoprotein-heparin-fibronectin-denatured collagen complexes enhance cholesteryl ester accumulation in macrophages

The sequestration of low-density lipoprotein (LDL) by components of the vascular extracellular matrix has long been recognized as a contributing factor to lipid accumulation during atherogenesis. The effects, however, that components of the extracellular matrix might have on LDL catabolism by scavenger cells have been little investigated. For these purposes we have prepared insoluble complexes of LDL, heparin, fibronectin, and denatured collagen (gelatin) and examined their effects on lipid accumulation, LDL uptake and degradation, and cholesteryl ester synthesis in mouse peritoneal macrophages. The results of these experiments have demonstrated that the cholesteryl ester content of macrophages incubated with a particular suspension of LDL, heparin, fibronectin, and collagen complexes is four- to fivefold that of cells incubated with LDL alone. The uptake of complexes containing 125I-LDL is rapid; however, in contrast to either endocytosed 125I-LDL or 125I-acetyl LDL, the degradation of complex-derived LDL is impaired. In addition, the uptake of complex-derived LDL stimulates the incorporation of [14C]oleic acid into cholesteryl oleate, however, the stimulation was a small fraction of that observed in cells incubated with acetyl LDL. Ultrastructurally, macrophages incubated with LDL, heparin, fibronectin, and collagen complexes did not contain many lipid droplets, but rather their cytoplasm is filled with phagosomes containing material similar in appearance to LDL-matrix complexes. These results indicate that components of the extracellular matrix can alter the catabolism of LDL by scavenger cells, suggesting that they may play a role in cellular lipid accumulation in the atherosclerotic lesion.