Interaction of gangliosides with proteins depending on oligosaccharide chain and protein surface modification.

By using neutron and synchrotron x-ray small-angle scattering techniques, we investigated the process of the complexation of gangliosides with proteins. We treated monosialoganglioside (G(M1)), disialoganglioside (G(D1a)), and a mixture of G(M1)/G(D1a). Proteins used were bovine serum albumins whose surfaces were modified with different sugars (deoxy-D-galactose, deoxy-L-fucose, deoxymaltitol, and deoxycellobiitol), which were used as model glycoproteins in a membrane. We found that the complexation of gangliosides with albumins greatly depends on the combination of ganglioside species and protein surface modification. With a varying protein/ganglioside ratio in a buffer solution at pH 7, the complexation of G(M1) or G(D1a) with albumins modified by monosaccharides appears to be less destructive for ganglioside aggregate structures in forming large complexes; the complexation of G(D1a) with the albumins modified by disaccharides induces the formation of complexes with a dimeric structure; and the complexation of G(M1) with albumins modified by disaccharides, to form small complexes, is very destructive. The present results show a strong dependence of the interaction between ganglioside and protein on the characteristics of the ganglioside and protein surface, which would relate to a physiological function of gangliosides, such as a function regulating the receptor activity of glycoproteins in a cell membrane.     

Understanding the role of internal lysine residues of serum albumins in conformational stability and bilirubin binding

The role of internal lysine residues of different serum albumins, viz. from human, rabbit, goat, sheep and buffalo (HSA, RbSA, GSA, SSA and BuSA), in conformational stability and bilirubin binding was investigated after blocking them using acetylation, succinylation and guanidination reactions. No significant change in the secondary structure was noticed whereas the tertiary structure of these proteins was slightly altered upon acetylation or succinylation as revealed by circular dichroism (CD), fluorescence and gel filtration results. Guanidination did not affect the native protein conformation to a measurable extent. Scatchard analysis, CD and absorption spectroscopic results showed marked reductions (5-21-fold decrease in K(a) and approximately 50% decrease in the CD Cotton effect intensity) in the affinity of albumins for bilirubin upon acetylation or succinylation whereas guanidination produced a small change. Interestingly, monosignate CD spectra of bilirubin complexed with GSA, SSA and BuSA were transformed to bisignate CD spectra upon acetylation or succinylation of internal lysine residues whereas spectra remained bisignate in the case of bilirubin bound to acetylated or succinylated derivatives of HSA and RbSA. When probed by CD spectroscopy, bilirubin bound to acetylated or succinylated derivatives of GSA and SSA rapidly switched over to native albumins and not vice versa. These results suggested that salt linkage(s) contributed by internal lysine residue(s) play an important role in the high-affinity binding of bilirubin to albumin and provide stability to the native three-dimensional conformation of the bound pigment. Chloroform severely decreased the intensity of both positive and negative CD Cotton effects of bilirubin complexed with acetylated or succinylated derivatives of all albumins which otherwise increased significantly in the case of bilirubin complexed with native and guanidinated albumin derivatives, except the bilirubin-RbSA complex which showed a small decrease in intensity. These results suggest that the presence of salt linkage(s) in bilirubin-albumin complexation is(are) crucial to bring about effective and efficient stereochemical changes in the bound pigment by co-binding of chloroform which seems to have at least one conserved binding site on these albumins that is shared with bilirubin.     

Quenching of the emission of tryptophan, tyrosine, and serum albumins by cupric ion

The effect of cupric ion on the emission of tryptophan, tyrosine, and serum albumins is studied by emission spectroscopy and lifetime measurements. It is found that whenever cupric ion is bound to tryptophan or tyrosine, their emissions are quenched completely. The quenching may be due to an electron transfer mechanism. The fluorescence of complexes of cupric ions with serum albumins is partially quenched; this is because energy is transferred from tryptophan to the complexed cupric ions by a dipolar energy transfer mechanism. It is deduced from the present study that the tryptophan in the human serum albumin molecule is between 11 and 16 Å from the nearest eupric ion binding sites (assumed to be at the surface of the protein) and that one of the tryptophan in the bovine serum albumin molecule is very close to the cupric ion binding sites and the other is near the center of the bovine serum albumin molecule. It is also found that the deuterium solvent effect on serum albumin fluorescence is very small, and that the quenching of bovine serum albumin fluorescence at the N-F transition is the result of quenching of the fluorescence of both tryptophans. The phosphorescence lifetime apparatus, capable of measuring decay times of signals with intensities changing over a few orders of magnitude, and the ratio spectrofluorometer, both of which were constructed in this laboratory, are also described.     

Electrophoretic investigation of interactions of sanguinarine and chelerythrine with molecules containing mercapto group

Using mercaptoethanol and (L)-cysteine as representatives of mercapto compounds and capillary zone electrophoresis as experimental technique, it was evidenced that sanguinarine and chelerythrine do not react with the mercapto group of organic compounds at pH 7.4. Their interaction is fast and reversible complexation based on non-bonding intermolecular interaction in which enter uncharged forms of sanguinarine or chelerythrine. A negatively charged group, either bound to the mercapto ligand or supplied from solution, participates in the complexation. Simple 1:1 interaction scheme reported in literature holds therefore only for mercapto compounds bearing anionic group. Stoichiometric binding constants corrected for the abundance of the uncharged alkaloid form at pH 7.4 are of the order of magnitude of 10(4) l/mol and depend on both cations and anions of the background electrolyte. Interaction of sanguinarine and chelerythrine with human or bovine serum albumins does not qualitatively differ from their interaction with simple mercapto compounds. Stoichiometric binding constants for the binding of sanguinarine with human and bovine serum albumins in sodium phosphate buffer pH 7.4, corrected for the abundance of the interacting uncharged form, are 332,000+/-38,400 and 141,000+/-14,400 l/mol, respectively. The former agrees well with the value K=385,000 (or log K=5.59) from static photometric experiments. Constants for the complexation of uncharged chelerythrine with human and bovine serum albumins are 2,970,000+/-360,000 and 1,380,000+/-22,600 l/mol, respectively.     

Difference in the effects of surfactants and albumin on the extent of deaggregation of purpurin 18, a model of hydrophobic photosensitizer

Absorption, fluorescence and light scattering techniques have been used to monitor the deaggregation of purpurin 18, a model of hydrophobic photosensitizers for photodynamic therapy, in aqueous micelles, microemulsions and human serum albumin. The aggregates present in the neat aqueous solvents are found to undergo deaggregation in these media to different extents. Aqueous micelles and microemulsions are found to induce a complete deaggregation whereas the process is only partial in albumins. This could be an indication of the fact that such hydrophobic photosensitizers are likely to be aggregated in the blood stream, but are probably in monomeric form, upon cellular uptake. The formation of surfactant-induced aggregates at intermediate concentrations of the positively charged CTAB is also observed and is explained in the light of electrostatic interactions between the fluorophore and the surfactant.     

Chloroform-induced conformational changes in the bound pigmentin bilirubin-albumin complexes

Chloroform-induced conformational changes of bilirubin (BR) bound to different serum albumins were studied by circular dichroism (CD) and fluorescence spectroscopy. Addition of a small amount of chloroform ( approximately 20 mM) to a solution containing 20 microM albumin and 15 microM BR changed the sign order and magnitude of the characteristic CD spectra of all BR-albumin complexes except BR-PSA complex which showed abnormal behavior. Monosignate negative CD Cotton effects (CDCEs) of BR complexed with SSA, GSA and BuSA were transformed into bisignate CDCEs in presence of chloroform akin to those exhibited by chloroform free solution of BR-HSA complex, indicating that the pigment acquired right handed plus (P) chirality when chloroform was added to these complexes. Bisignate CD spectra of BR complexed with HSA and BSA showed complete inversion upon addition of chloroform corroborating earlier findings. On the other hand, changes observed with BR-RSA complex were slightly different showing an additional CD band of weak intensity centered around 390 nm though inversion of CDCEs was similar to that of BR-HSA complex. Monosignate CD spectra of BR-PSA complex also showed three CD bands occurring at 409, 470 and 514 nm after chloroform addition. These results indicated significant but different effects of chloroform on the conformation of bound BR in BR-albumin complexes which can be ascribed to the changes in the exciton chirality of bilirubin probably due to altered hydrophobic microenvironment induced by the binding of chloroform at or near the ligand binding site. Chloroform severely quenched the intrinsic tryptophan fluorescence of the protein and shifted the emission maxima towards blue region in all the albumins except PSA. However, quantitative differences in both quenching and blue shift were noted in different serum albumins. This suggests that chloroform probably binds in the close vicinity of tryptophan residue(s) located in subdomain(s) IIA or IB and II both. The fluorescence of BR-albumin complexes was also found to be sensitive to the presence of a small amount of chloroform. But the changes observed in the fluorescence of the bound pigment in presence of chloroform were less marked as compared to the changes in the intrinsic fluorescence of protein per se. Taken together, these results suggest that there is at least one conserved site for chloroform binding in all these albumins which is at or near the BR binding site.     

Spectral and fluorescent study of the interaction of squarylium dyes,derivatives of 3<Emphasis Type="Italic">H</Emphasis>-indolium,with albumins

Noncovalent interaction of intraionic squarylium dyes, derivatives of 3H-indolium, as well as the structurally analogous ionic indodicarbocyanine dye with serum albumins (human, bovine, rat) and, for comparison, with ovalbumin has been studied by spectral and fluorescent methods. The hydrophilic squarylium dye with sulfonate groups was found to interact with albumins more efficiently, which is probably due to the double negative charge on the dye molecule at the expense of the sulfonate groups and the ability to form hydrogen bonds with albumin. The hydrophilic indodicarbocyanine dye without the squarylium group in its structure binds to albumins much weaker than the structurally analogous squarylium dye. The dyes bind to ovalbumin less efficiently than to serum albumins. Along with the binding of monomeric dye molecules, the aggregation of the dyes on albumins is also observed. The hydrophobic squarylium dye without sulfonate groups tends to form aggregates in aqueous solutions, which partially decompose upon the introduction of albumin into the solution. The hydrophilic squarylium dye with sulfonate groups can be recommended for tests as a spectral-fluorescent probe for serum albumins in extracellular media of living organisms.     

Protease-catalyzed synthetic reactions and immobilization-activation of the enzymes in hydrophilic organic solvents.

The catalytic feature of serine proteases for synthetic reactions in hydrophilic organic solvents and effects of immobilization by complexation with polysaccharides are described. Free alpha-chymotrypsin and subtilisin Carlsberg catalyze esterification, transesterification, and peptide synthesis in hydro-organic cosolvents with less than 10% water. Subtilisin BPN' is catalytically less active. The medium effects on the reaction kinetics and product yield were investigated in terms of the nature of solvent and water content in the reaction systems. The substrate- and stereo-specificities of the enzymes suggest that the enzymes maintain their native conformations in these low-water organic solvents. The catalytic activities of the proteases markedly increase by immobilization or complexation with polysaccharides, such as chitin or chitosan. The results of the rate measurements suggest that the primary role of the support materials is the activation of the enzymes and the increase in substrate concentration at reaction sites.     

Valinomycin and its interaction with ions in organic solvents, detergents, and lipids studied by Fourier transform IR spectroscopy.

The structure of valinomycin in a range of organic solvents of varying polarity and in detergent and lipid dispersions has been studied by Fourier transform ir spectroscopy. In solvents of low polarity such as chloroform, ir spectra of valinomycin are fully consistent with the bracelet structure proposed on the basis of nmr spectroscopy, showing a single narrow amide I component attributable to the presence of beta-turns and a single band arising from nonhydrogen-bonded ester C = O groups. K+ complexation results in a downward shift in the amide I band frequency, indicating an increase in the strength of the amide hydrogen bonds, along with a shift to lower frequencies of the ester C = O absorption due to a reduction in electron density in these bonds upon complexation. Identical results were obtained with NH4+, a finding not previously reported. In solvents of both medium (CHCl3/DMSO 3:1) and high (pure DMSO) polarity, we find evidence of significant disruption of the internal hydrogen-bonding network of the peptide and the appearance of a band suggesting the presence of free amide C = O groups. In such solvents, complexation with K+ and NH4+ was not observed. The structure of valinomycin in detergent micelles resembles that in nonpolar organic solvents. However, changes were found in the amide I and ester carbonyl maxima as 2H2O penetrated the micelle which suggest significant interaction between the solvent and peptide. Complexation with K+ was reduced in cationic detergent micelles as a result of a decrease in the effective K+ concentration due to charge repulsion at the micelle surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

Trinitrophenylation of the bilirubin binding site of human serum albumin.

Human serum albumin has been modified with 2,4,6-trinitrobenzenesulphonic acid and picryl chloride in low ratios of reagents/albumin. The derivatives have been investigated by spectrophotometry and by thin layer chromatography of the hydrolysates in order to assess the specificity of the reagents. The same reaction conditions were used to modify albumin previously complexed with bilirubin in the ratio of 1:1. The affinity of bilirubin to the modified albumins was estimated by an improved perozidase method. It is concluded that TNBS and picryl chloride react almost quantity with epsilon-amino groups of lysine on the albumin molecule. The results also suggest that at least on TNBS reactive amino group and at least one picryl chloride reactive amino group are located in or near the high-affinity bilirubin binding site.     

Circular dichroism of ketoprofen complexed to serum albumins: Conformational selection by the protein: A novel optical purity determination technique

Complexation of 2-(3′-benzoylphenyl)propionic acid (ketoprofen), 1 , to bovine serum albumin (BSA) results in an intense negative circular dichroism in the ketonic n → π* band of the benzoylphenyl moiety. This high CD contrasts with the weak CD of 1 -enantiomers dissolved in common solvents. Furthermore, a number of chiral and achiral molecules containing the benzophenone moiety are easily complexed to BSA: all these complexes show an intense CD at the same transition. To account for the observed CD intensities of the above molecules, it appears that BSA complexation markedly shifts the equilibrium between strongly asymmetric, antipodic conformers. Dissymmetry of these conformers is connected to the instability of a structure with phenyl rings coplanar to the carbonyl chromophore, as also indicated by molecular mechanics calculations. The magnification of the Cotton effects of the 1 -antipodes, due to the protein, can be used to measure the optical purity of 1 -samples with excellent precision. In contrast with BSA, human SA is unable to recognize the chirality of 1 -antipodes; oleic acid cocomplexation modifies this fact as well as other features of the binding. © 1995 Wiley-Liss, Inc.     

Molecular simulation of Tyr105 phosphorylated pyruvate kinase M2 to understand its structure and dynamics

Microstructure of dibenzo-18-crown-6 (DB18C6) and DB18C6/Li⁺ complex in different solvents (water, methanol, chloroform, and nitrobenzene) have been analyzed using radial distribution function (RDF), coordination number (CN), and orientation profiles, in order to identify the role of solvents on complexation of DB18C6 with Li⁺, using molecular dynamics (MD) simulations. In contrast to aqueous solution of LiCl, no clear solvation pattern is found around Li⁺ in the presence of DB18C6. The effect of DB18C6 has been visualized in terms of reduction in peak height and shift in peak positions of g_Li-Ow. The appearance of damped oscillations in velocity autocorrelation function (VACF) of complexed Li⁺ described the high frequency motion to a “rattling” of the ion in the cage of DB18C6. The solvent-complex interaction is found to be higher for water and methanol due to hydrogen bond (HB) interactions with DB18C6. However, the stability of DB18C6/Li⁺ complex is found to be almost similar for each solvent due to weak complex-solvent interactions. Further, Li⁺ complex of DB18C6 at the liquid/liquid interface of two immiscible solvents confirm the high interfacial activity of DB18C6 and DB18C6/Li⁺ complex. The complexed Li⁺ shows higher affinity for water than organic solvents; still they remain at the interface rather than migrating toward water due to higher surface tension of water as compared to organic solvents. These simulation results shed light on the role of counter-ions and spatial orientation of species in pure and hybrid solvents in the complexation of DB18C6 with Li⁺. Graphical Abstract

DB18C6/Li⁺ complex in pure solvents (water, methanol, chloroform, and nitrobenzene) and water/nitrobenzene interface     

Nanopore sensing of γ-cyclodextrin induced host-guest interaction to reverse the binding of perfluorooctanoic acid to human serum albumin

Perfluorooctanoic acid (PFOA) has been one of the most common perfluorochemicals, which are globally pervasive contaminants that are persistent, bioaccumulative, toxic, and have adverse impacts on human health. The highest concentration of PFOA occurs in the blood, where it strongly binds to human serum albumins (HSA). Thus, a method to reverse the HSA-PFOA binding is critical to help facilitate the faster elimination of PFOA from the body to minimize its toxicological effects. Inspired by the remediation effect of cyclodextrin (CD) to PFOA through host-guest interactions, herein, by elucidating inter-molecular interactions using a nanopore sensor, we demonstrated in vitro reversal of the binding of PFOA to HSA using γ-cyclodextrin (γ-CD). The competition behavior for the complexation of PFOA between HSA and γ-CD was discussed in combination with in situ nanopore current recording and nuclear magnetic resonance (NMR) characterization. The present work not only demonstrates the potential therapeutic application of γ-CD for PFOA removal from human blood, but also provides an emerging method for investigating interactions between organic compounds and proteins.     

Correlation between tryptophan, NEFA and albumins in the nephrotic syndrome

Many connections were considered between bound and free tryptophan and albumins, NEFA and other aminoacids in 18 proofs in ten subjects of paediatric age affected by nephrotic syndrome. A decrease of total tryptophan and a tendency to increase of free tryptophan were showed in our experience. NEFA, at normal concentrations, should not be responsible for this; and this could suggest that the binding sites on albumins for NEFA and tryptophan are different. Besides there is appearance of a positive correlation between albumins and bound tryptophan and a negative correlation between albumins and free tryptophan. These results can suggest that the reduction of the total tryptophan is due to the loss of the fractions bound to albumins, but urinary tryptophan is not increased in our studies. As the albumins get fewer, there is a lost in linked tryptophan and an increase of free tryptophan. A total reduction of other aromatic aminoacids can also explain, through a reduced intestinal absorption, the decrease of the tryptophan in the nephrotic syndrome.     

Species-dependent binding of serum albumins to the streptococcal receptor protein G

The interaction of the serum albumin binding domain from streptococcal protein G to serum albumins isolated from different species was investigated. The highest affinity to protein G was found for serum albumins from rat, man and mouse. A medium binding was found for serum albumin from rabbit, cow, hen and horse, while little or no binding was found for ovalbumin and serum albumin from sheep. The interaction between human serum albumin and protein G showed rapid binding kinetics at the temperatures 7, 22 and 37 degrees C. Furthermore, the ability of different serum albumins to function as affinity ligands when covalently coupled to a solid support was tested. The results show that protein G derivatives could be eluted at different pH depending on the origin of the serum albumin. It was also possible to elute the streptococcal receptor efficiently from the mouse serum albumin matrix with human serum albumin. Based on these results, a gene fusion system for recovery of sensitive proteins by affinity purification is described, where high yields are obtained under mild elution conditions.     

Organic solvent adaptation of Gram positive bacteria: applications and biotechnological potentials

Organic-solvent-tolerant bacteria are considered extremophiles with different tolerance levels that change among species and strains, but also depend on the inherent toxicity of the solvent. Extensive studies to understand the mechanisms of organic solvent tolerance have been done in Gram-negative bacteria. On the contrary, the information on the solvent tolerance mechanisms in Gram-positive bacteria remains scarce. Possible shared mechanisms among Gram-(−) and Gram-(+) microorganisms include: energy-dependent active efflux pumps that export toxic organic solvents to the external medium; cis-to-trans isomerization of unsaturated membrane fatty acids and modifications in the membrane phospholipid headgroups; formation of vesicles loaded with toxic compounds; and changes in the biosynthesis rate of phospholipids to accelerate repair processes. However, additional physiological responses of Gram-(+) bacteria to organic solvents seem to be specific. The aim of the present work is to review the state of the art of responsible mechanisms for organic solvent tolerance in Gram-positive bacteria, and their industrial and environmental biotechnology potential.     

Modeling hydration mechanisms of enzymes in nonpolar and polar organic solvents

A comprehensive study of the hydration mechanism of an enzyme in nonaqueous media was done using molecular dynamics simulations in five organic solvents with different polarities, namely, hexane, 3-pentanone, diisopropyl ether, ethanol, and acetonitrile. In these solvents, the serine protease cutinase from Fusarium solani pisi was increasingly hydrated with 12 different hydration levels ranging from 5% to 100% (w/w) (weight of water/weight of protein). The ability of organic solvents to 'strip off' water from the enzyme surface was clearly dependent on the nature of the organic solvent. The rmsd of the enzyme from the crystal structure was shown to be lower at specific hydration levels, depending on the organic solvent used. It was also shown that organic solvents determine the structure and dynamics of water at the enzyme surface. Nonpolar solvents enhance the formation of large clusters of water that are tightly bound to the enzyme, whereas water in polar organic solvents is fragmented in small clusters loosely bound to the enzyme surface. Ions seem to play an important role in the stabilization of exposed charged residues, mainly at low hydration levels. A common feature is found for the preferential localization of water molecules at particular regions of the enzyme surface in all organic solvents: water seems to be localized at equivalent regions of the enzyme surface independently of the organic solvent employed.     

Metals in biochemistry : P.M. Harrison and R.J. Hoare,Chapman & Hall,New York, 1980, 80 pp. $5.95 (paper)

An ultrafiltration technique was used to study stripping by glycine of the first copper and zinc ion equivalents bound by bovine, dog, and rat serum albumins at pH 7.5. Affinity of dog serum albumin for copper was poorer than for the other albumins, consistent with the absence in the former albumin of the copper binding site present at the amino terminus of the latter albumins. Affinities of all three proteins for zinc were similar, suggesting that the albumin amino terminus is not the primary zinc ion binding site.     

Kinetic analysis of the mechanism for subtilisin in essentially anhydrous organic solvents

Steady-state kinetic analysis has been used to confirm the catalytic mechanism of lyophilized subtilisin suspended in a variety of organic solvents. Specifically, this article demonstrates that partial reactions can occur between subtilisin and ester substrates in organic solvents. Partitioning of common intermediates between competing acceptors at a constant ratio of products has also been described. The decomposition of a common intermediate formed from different substrates at the same rate is also further evidence of an acyl-enzyme mechanism for subtilisin suspended in anhydrous solvents. Partitioning of a common intermediate to give two products at a constant total rate, and saturation kinetics at varying substrate concentrations, complete a kinetic investigation of the enzyme mechanism. All the data generated support the formation of a stable acyl enzyme during the transesterification reaction catalzyed by subtilisin in the solvents used.     

Isolation and Characterization of the cis-trans-Unsaturated Fatty Acid Isomerase of Pseudomonas oleovorans GPo12

Pseudomonas oleovorans contains an isomerase which catalyzes the cis-trans conversion of the abundant unsaturated membrane fatty acids 9-cis-hexadecenoic acid (palmitoleic acid) and 11-cis-octadecenoic acid (vaccenic acid). We purified the isomerase from the periplasmic fraction of Pseudomonas oleovorans. The molecular mass of the enzyme was estimated to be 80 kDa under denaturing conditions and 70 kDa under native conditions, suggesting a monomeric structure of the active enzyme. N-terminal sequencing showed that the isomerase derives from a precursor with a signal sequence which is cleaved from the primary translation product in accord with the periplasmic localization of the enzyme. The purified isomerase acted only on free unsaturated fatty acids and not on esterified fatty acids. In contrast to the in vivo cis-trans conversion of lipids, this in vitro isomerization of free fatty acids did not require the addition of organic solvents. Pure phospholipids, even in the presence of organic solvents, could not serve as substrate for the isomerase. However, when crude membranes from Pseudomonas or Escherichia coli cells were used as phospholipid sources, a cis-trans isomerization was detectable which occurred only in the presence of organic solvents. These results indicate that isolated membranes from Pseudomonas or E. coli cells must contain factors which, activated by the addition of organic solvents, enable and control the cis-trans conversion of unsaturated acyl chains of membrane phospholipids by the periplasmic isomerase.