Complex formation between protein and poly vinyl sulfonate as a strategy of proteins isolation

The complex formation between the basic protein trypsin and the strong anionic polyelectrolyte poly vinyl sulfonic acid was studied by using turbidimetric and isothermal calorimetric titrations. The trypsin-polymer complex was insoluble at pH lower than 5, with a stoichiometric ratio polymer mol per protein mol of 1:136. NaCl, 0.5M inhibited the complex precipitation in agreement with the proposed coulombic mechanism of complex formation. The protein structure and its thermodynamic stability were not significantly affected by the presence of the polyelectrolyte. The enzymatic activity of trypsin increases throughout time, even in the presence of the polymer.     

Activity and Stability of Native and Modified Subtilisins in Various Media

The activity and stability of native subtilisin 72, its complex with poly(acrylic acid), and subtilisin covalently attached to poly(vinyl alcohol) cryogel were studied in aqueous and organic media by hydrolysis of specific chromogenic peptide substrates. Kinetic parameters of the hydrolysis of Glp-Ala-Ala-Leu-pNA by native subtilisin and its complex with poly(acrylic acid) were determined. Based on the comparative study of stability of native and modified subtilisins in media of various compositions, it was established that covalent immobilization of subtilisin on poly(vinyl alcohol) cryogel is the most effective approach to improve enzyme stability in water as well as in mixtures with low water content.     

Precipitation with poly acrylic acid as a trypsin bioseparation strategy

Precipitation of enzymes with reversible soluble–insoluble polymers is a simple approach which can be easily scaled up. This work reports investigations aiming at verifying the existence of specific interactions and complex formation between porcine trypsin and poly acrylic acids using spectroscopy techniques. The trypsin–polymer complex was insoluble at pH lower than 5, with a stoichiometric ratio polymer mol per protein mol of 1:148. It took only a minute for the insoluble complex to form and it was redissolved modifying the pH of the medium. The enzymatic activity of trypsin was maintained even in the presence of the polymer and after precipitation poly acrylic acid presence protect the enzyme from itself degradation. The conditions of complex formation were studied using pure proteins that could be applied on porcine pancreas homogenates as an isolation strategy of trypsin.     

Chymotrypsin-poly vinyl sulfonate interaction studied by dynamic light scattering and turbidimetric approaches

The formation of non-soluble complexes between a positively charged protein and a strong anionic polyelectrolyte, chymotrypsin, and poly vinyl sulfonate, respectively, was studied under different experimental conditions such as pH (1-3.5), protein concentration, temperature, ionic strength, and the presence of anions that modifies the water structure. Turbidimetric titration and dynamic light scattering approaches were used as study methods. When low protein-polyelectrolyte ratio was used, the formation of a soluble complex was observed. The increase in poly vinyl sulfonate concentration produced the interaction between the soluble complex particules, thus inducing macro-aggregate formation and precipitation. Stoichiometry ratios of 500 to 780 protein molecules were found in the precipitate per polyelectrolyte molecule when the medium pH varied from 1.0 to 3.5. The kinetic of the aggregation process showed to be of first order with a low activation energy value of 4.2+/-0.2 kcal/mol. Electrostatic forces were found in the primary formation of the soluble complex, while the formation of the insoluble macro aggregate was a process driven by the disorder of the ordered water around the hydrophobic chain of the polymer.     

Novel insulin thiomer nanoparticles: in vivo evaluation of an oral drug delivery system

It was aim of the study to investigate the in vivo potential of a novel insulin-thiomer complex nanoparticulate delivery system. Insulin loaded nanoparticles were obtained by the formation of hydrogen bonds between poly(vinyl pyrrolidone) (PVP) and poly(acrylic acid)-cysteine (PAA-Cys) or poly(acrylic acid) (PAA), respectively, in the presence of insulin. Dissolution behavior of insulin from tablets as well as nanoparticulate suspensions was evaluated in vitro. Serum insulin concentrations and reduction of blood sugar values were determined after oral administration of nanoparticles formulated as enteric coated tablets and suspensions. Results displayed a low serum insulin concentration and pharmacological efficacy in terms of blood sugar reduction after oral administration of enteric coated tablets. On the contrary, nanoparticulate suspensions led to significant serum insulin concentrations. Furthermore a 2.3-fold improvement of the AUC of insulin could be achieved due to the use of thiolated PAA instead of unmodified PAA. In addition, a blood sugar reduction of 22% was observed. Results demonstrate that this novel complex nanoparticulate formulation is an encouraging new attempt toward the noninvasive delivery of peptide drugs.     

Chymotrypsin–poly vinyl sulfonate interaction studied by dynamic light scattering and turbidimetric approaches

The formation of non-soluble complexes between a positively charged protein and a strong anionic polyelectrolyte, chymotrypsin, and poly vinyl sulfonate, respectively, was studied under different experimental conditions such as pH (1–3.5), protein concentration, temperature, ionic strength, and the presence of anions that modifies the water structure. Turbidimetric titration and dynamic light scattering approaches were used as study methods. When low protein–polyelectrolyte ratio was used, the formation of a soluble complex was observed. The increase in poly vinyl sulfonate concentration produced the interaction between the soluble complex particules, thus inducing macro-aggregate formation and precipitation. Stoichiometry ratios of 500 to 780 protein molecules were found in the precipitate per polyelectrolyte molecule when the medium pH varied from 1.0 to 3.5. The kinetic of the aggregation process showed to be of first order with a low activation energy value of 4.2 ± 0.2 kcal/mol. Electrostatic forces were found in the primary formation of the soluble complex, while the formation of the insoluble macro aggregate was a process driven by the disorder of the ordered water around the hydrophobic chain of the polymer.     

Nature of Interaction between basic fibroblast growth factor and the antiangiogenic drug 7,7-(carbonyl-bis[imino-N-methyl-4,2-pyrrolecarbonylimino[N-methyl-4,2-pyrrole]-carbonylimino])-bis-(1,3-naphtalene disulfonate). II. Removal of polar interactions affects protein folding

Fibroblast growth factor-2 (basic FGF), a potent inducer of angiogenesis, and the naphthalene sulfonic distamycin A derivative, 7,7-(carbonyl-bis[imino-N-methyl-4,2-pyrrolecarbonylimino[N-methyl-4,2-pyrrole]-carbonylimino])-bis-(1,3-naphtalene disulfonate) (PNU145156E), which exhibits in vivo antiangiogenic activity, form a tight reversible (1:1) complex. PNU145156E binds to the heparin and the selenate-binding sites on bFGF. The cis bFGF-heparin (2:1) complex, essential for the activation of the angiogenic process, is thus prevented. The nature of the forces involved in bFGF:PNU145156E complex, using the wild-type and the K128Q, K138Q, K134Q, and K128Q-K138Q point mutated bFGFs was sought. Based on thermodynamic analysis of the complexation constants, protein temperature stability profiles by ultraviolet absorption, circular dichroism measurements, fluorescence F?rster energy-transfer, and anisotropy studies, in harmony with the published x-ray crystallographic structure, the following molecular interactions are proposed: reduced coulombic interactions, hence loosening of the complex by the removal of charged polar groups from the bFGF-heparin binding cleft resulted in decreased binding constants and in a change in the binding mode from polar to nonpolar. Concomitantly, upon mutation, the protein was rendered more compact, less flexible, and less aqueously exposed compared with the wild type. These were further pronounced with the double mutant: weaker dominantly nonpolar protein-drug interactions were accompanied by conspicuous folding. With heparin, however, wild-type bFGF forms a tighter complex with a more compact structure.     

Preparation and evaluation of polyvinyl alcohol-co-oleylvinyl ether derivatives as tumor-specific cytotoxic systems

A series of poly(vinyl alcohol) amphiphilic derivatives have been prepared to obtain polymeric aggregates in aqueous phase holding thermodynamic instability. The aim was to evaluate their ability to interact with tumor cells eliciting selective cytotoxicity. The poly(vinyl alcohol) derivatives were prepared by partial substitution of poly(vinyl alcohol) (MW 10 kDa) with both oleyl chains and poly(ethylene glycol) monoethyl ethers (PEGMEE) of different molecular weights. The substitution degree was 1.5% for the oleyl chains and 1% for the PEGMEE chains (moles of substituent per 100 mol of hydroxyvinyl monomer). The polyvinyl derivatives obtained easily dissolved in water. Dynamic and static light scattering measurements on the polymer aqueous solutions indicated the formation of polymeric aggregates characterized by low polydispersity (0.232-0.299) and mean size (218-382 nm) in the range suitable for intravenous administration. Moreover, they were characterized by different packing densities and thermodynamic instabilities driving the polymers to interact with hydrophobic membranes. Among the analyzed polymers, the poly(vinyl alcohol)-co-oleylvinyl ether substituted with triethylene glycol monoethyl ether (P10(4)) provided in solution the highest affinity for hydrophobic membranes. P10(4), moreover, was the most cytotoxic toward the tumor cell lines analyzed (neuroblastoma: SH-SY5Y, IMR-32, HTLA-230. melanoma: MZ2-MEL, RPMI7932.), while it did not appreciably alter the viability of the normal resting lymphocytes. The peculiar behavior of the P10(4) aggregates has been correlated to their high thermodynamic instability in solution due to the high packing density that triggers the polymeric aggregates to interact with hydrophobic membranes such as the tumor cell membranes, thus eliciting cytotoxicity.     

How Flexible Polymers Interact with Proteins and Its Relationship with the Protein Separation Method by Protein–Polymer Complex Formation

Bovine serum albumin was selected as a model protein to study the molecular mechanism of interaction between flexible polymer with net negative electrical charge (polyvinylsulphonate and polyacrylic acid) and a non-charged polymer such as poly(ethylene) poly(propylene) oxide (molecular mass 8,400) by using spectroscopies techniques combination: fluorescence emission and circular dichroism. Polyvinylsulphonate and polyacrylic acid interact with the protein due to the coulombic interaction between positive charged protein groups such as amine of lysine and histydine. The poly(ethylene)-poly(propylene) oxide increased the hydrophobic microenvironment around the tryptophan residues. This polymer preserved the secondary and tertiary structure of the protein and did not induce any significant modification in the protein surface area exposed to the solvent.     

Hydrolysis of sucrose using sulfonated poly(vinyl alcohol) as catalyst

The hydrolysis of sucrose was carried out over poly(vinyl alcohol) (PVA) with sulfonic acid groups, at 80 °C. The products of sucrose hydrolysis were glucose and fructose. A series of PVA with different crosslinking degree were prepared. It was observed that the catalytic activity of PVA matrix increases with the crosslinking degree, due to the increases of the amount of sulfonic acid groups on PVA.     

Interaction of spin-labelled serum albumin with synthetic polymers

Bovine and human serum albumin (BSA and HSA) were spin-labelled (SL-) with 2,2,6,6-tetramethyl-4-iodoacetamido-piperidine-1-oxyl, and e.s.r. measurements were performed in aqueous solutions. E.s.r. spectra of SL-BSA measured at various pH values were essentially different from those of HSA, indicating a difference of the environment around the free sulphydryl (residue 34) in BSA and HSA. The spectrum of SL-BSA did not change by the addition of neutral poly(vinyl alcohol) (PVA). On the other hand, it decomposed into a mobile component and a less mobile component,by the addition of poly(acrylic acid) (PAA) and poly(ethyleneimine) (PEI), suggesting the formation of a polyionic complex. The dependence of relative intensity of the mobile component, Rh, on pH was consistent with the complex formation as a function of pH. Rh value for SL-BSA/PAA and SL-BSA/PEI showed a minimum at pH 4.8 and 7.0, respectively, where the ionic interactions occurred rather efficiently. The minimum Rh value was, however, smaller for SL-BSA/PAA than for SL-BSA/PEI, indicating that the environment around the sulphydryl interacted more strongly with the polyanion than the polycation.     

Construction of a new artificial biomineralization system

Hydroxyapatite (HAP) was mineralized in poly(vinyl alcohol) (PVA)/poly(acrylic acid) (PAA) complex hydrogel immersed in a salt solution containing PAA. The transparent HAP/polymer composite swelled in water depending on the HAP content; high HAP content gave small swelling and vice versa. The HAP content reached about 80 wt % at most. Observation of the cross section of the composite by energy-dispersive analysis of X-ray (EDAX) revealed that the composite consisted of two phases, i.e., a hard HAP-rich phase and a soft polymer-rich phase. In the HAP-rich phase, the space inside the hydrogel was occupied by HAP, while HAP was not mineralized in the polymer-rich phase. The nucleation seemed to take place, at first, at the middle depth of the hydrogel where the HAP-rich phase was formed. The HAP-rich phase grew its size toward the surface of the hydrogel at the cost of the polymer-rich phase. The presence of phosphorus, P, in the polymer-rich phase indicated the adsorption of HPO(4)(2-) on the polymer chain of the hydrogel via hydrogen bonding, accompanied with Ca(2+) because of electrostatic constraints. This adsorption of ions in addition to Donnan distribution of ions leads to the formation of a hypercomplex that can be regarded as a precursor of the HAP-rich phase. The change of the hypercomplex into the HAP-rich phase is discontinuous and hence concluded as a phase transition. By comparison of our mineralization system with the biomineralization system of HAP and CaCO(3), the physicochemical mechanism of the mineralization process in the present system was found to be similar to that in biological systems. In this sense, we termed the present system an artificial biomineralization system.     

Non-mulberry silk sericin/poly (vinyl alcohol) hydrogel matrices for potential biotechnological applications

This study reports a novel biopolymeric matrix fabricated by chemically cross-linking poly (vinyl alcohol) with silk sericin protein obtained from cocoons of the tropical tasar silkworm Antheraea mylitta. Glutaraldehyde was used as a cross-linking agent with hydrochloric acid acting as an initiator. The matrices were biophysically characterized and the cytocompatibility of the matrices was evaluated for their suitability as biomaterials. The surface morphology was assessed using atomic force microscopy while the changes taking place after cross-linking were confirmed by Fourier transform infrared spectroscopy. The enhanced thermal stability of the constructs was assessed by thermogravimetric and differential scanning calorimetry. Fourier transform infrared spectroscopy analysis showed that sericin was chemically cross-linked with poly (vinyl alcohol) using glutaraldehyde. Silk sericin protein demonstrated a favorable effect on animal cell culture by successfully improving the adhering and spreading of cells on the poorly adhering surface of poly (vinyl alcohol). Confocal microscopy revealed cell spreading and actin filament development in sericin/poly (vinyl alcohol) hydrogel matrices. These findings prove the potential of non-mulberry silk sericin/poly (vinyl alcohol) hydrogel matrices to be used as biocompatible and biopolymeric material for tissue-engineering and biotechnological applications.     

Chitosan membranes modified by contact with poly(acrylic acid)

In this work chitosan membranes modified by contact with poly(acrylic acid) (PAA) aqueous solution at two different temperatures (25 °C and 60 °C) were obtained. The pure chitosan (CS) membranes, as well as those treated with PAA (CSPAA_25 and CSPAA_60) were characterized by FTIR-ATR, water sorption capacity, thermal analysis (TG/DTG), and scanning electron microscopy (SEM). In addition, in vitro permeation experiments were carried out using metronidazol and sodium sulfamerazine aqueous solutions at 0.1% and 0.2% as model drugs. FTIR-ATR results showed the presence of absorption bands of and COO⁻ indicating the formation of a polyelectrolyte complex between chitosan and poly(acrylic acid). The results also indicated that PAA penetrates deeper into the membrane at higher temperature (60 °C), forming a thicker complex layer. Polyelectrolyte complex formation as well as the influence of treatment temperature was confirmed by lower hydrophilicity, higher thermal stability, and lower permeability of the treated membranes. The results show that the methodology used is a simple and very efficient way to drastically change some membrane properties, especially their permeability.     

Effect of solution pH and ionic strength on the stability of poly(acrylic acid)-encapsulated multiwalled carbon nanotubes aqueous dispersion and its application for NADH sensor

The optimal conditions to prepare water-soluble, stable poly(acrylic acid)-wrapped multiwalled carbon nanotubes (PAA-MWNTs) complex is presented. PAA-MWNTs shows high stability within weak acid to weak basic pH condition. The complex also shows good endurance to moderate ionic strengths in the buffer solution. The PAA-MWNTs complex film-covered electrode demonstrates stable, excellent electrocatalytic activity to oxidize NADH, which makes it possible to prepare NADH sensor at a low potential of approximately 0.13 V (versus Ag/AgCl) with the linear range of 4-100 microM by differential pulse voltammetry.     

Complex formation between spin-labeled polyuridylic acid and pyrimidine nucleosides.

Complex formation between poly (U) and pyrimidine nucleosides, uridine and cytidine, was observed using spin labeling technique. The binding of these nucleosides with poly (U) takes place within a narrow range of their concentration and is characterized by a relatively strong cooperativity. It is shown, that both hydrogen bonding and stacking interaction contribute to the complex stability. Some thermodynamic parameters of the process were obtained from the binding isotherms. At 21 degrees C the equilibrium constants for nucleation were found to be 0.23 M-1 and 0.42 M-1, and those for chain growth 2.63 M-1 and 2.19 M-1 for uridine and cytidine respectively. Complex formation of poly (U) with adenosine was also studied by spin labeling method.     

Interaction of trivaline with single-stranded polyribonucleotides]

Binding of tripeptide H-Val3-(NH)2-Dns (TVP) to polyribonucleotides was studied by fluorescence methods, circular and flow linear dichroism, equilibrium dialysis and electron microscopy. It was found that TVP binds to poly(U) in monomer, dimer and tetramer forms with binding constants of about 10(3), 40, 18.10(4) M, respectively. The cooperativity parameter for peptide dimer binding is 2000. The peptide forms tetramer complexes with poly(A), poly(C), poly(G) also. The formation of a complex between the peptide tetramer and nucleic acid is accompanied by a significant increase in the fluorescence intensity. The cooperative binding of TVP dimers to poly(U), poly(A), poly(C) is accompanied by a dramatic decrease in the flexibility of polynucleotide chains. However, it has a small effect (if any) on the flexibility of the poly(G) chain. The observed similarity of thermodynamic, optical and hydrodynamic++ properties of TVP complexes with single-stranded and double-stranded nucleic acids may reflect a similarity in the geometries of peptide complexes with nucleic acids. Electron microscopy studies show that peptide binding to poly(U) and dsDNA leads to compactization of the nucleic acids caused by interaction between the peptide tetramers bound to a nucleic acid. At the first stage of the compactization process the well-organized rod-like particles are formed, each consisting of one or more single-stranded polynucleotide fibers. Increasing the peptide concentration stimulates a side-by-side association and folding of the rods with the formation of macromolecular "leech-like" structures with the thickness of 20-50 nm.     

The effect of structural-chemical characteristics of water-soluble polyelectrolyte complexes of ovalbumin on their immunological properties

Immunogenicity of soluble protein antigens in the complexes with synthetic polyions may be regarded as depending both on the nature of polymer carrier and the structure of the protein-polyelectrolyte complex. The immunogenicity of stable soluble complexes of ovalbumin (OA) with polycation - quaternized poly-4-vinylpyridine (C-1) and copolymer of acrylic acid and 2-methyl-5-vinylpyridine (C-2) have been evaluated. Immunization of mice by C-1 have induced a vigorous formation of the anti-OA IgG antibodies and IgE homocytotropic antibodies, while immunogenicity of OA in C-2 was comparable with that of OA alone. The analysis of the structural-chemical features of the complexes investigated has shown that enhanced immunogenicity of C-1 may be due to (1) the non-homogeneous distribution of protein globulae among polycation macromolecules and to (2) the formation of complex with an asymmetrical structure, to (3) the high ability of C-1 to adsorb on a surface of the lymphoid cells and to induce a formation of intercellular aggregates. An enhancing of a stability and a size of C-2 in the presence of Cu2+ shows no influence on a immunogenicity of OA. An immunogenicity of both types of complexes does not depend upon the access of determinants of OA to antibodies so far as it has been shown that complex formation in both cases are not accompanied by an alteration of antigenicity and allergenicity of OA.     

Accessibility for water molecules and relative stability of the A- and B-forms of DNA

Accessible surface areas of DNA molecules (A- and B-forms) for different probe particle radii were calculated for poly(dA).poly(dT) and poly[d(A-T)].poly[d(A-T)] sequences. The problem of different forms stability is discussed in connection with accessible surface area characteristics as well as coulombic interaction between base pairs. The coulombic interaction was shown to play an important role in sequence dependent stability of the DNA molecule.     

1H-NMR Study of the effect of synthetic polymers on the fluidity,transition temperature and fusion of dipalmitoyl phosphatidylcholine small vesicles

The interaction of water-soluble polymers with dipalmitoyl phosphatidylcholine small vesicles and the effect on vesicle fusion were studied by means of ¹H-NMR spectrometry. The motion of dipalmitoyl phosphatidylcholine molecules decreased on interaction with the polymers and was detected as a change in the signal intensity. The interaction behavior of polymers is very sensitive to the chemical structure of the applied polymers. Poly(styrene sulfonic acid) and poly(ethylene glycol) decreased the motion of the choline methyl group, predominantly through coulombic and hydrophobic interaction forces, respectively. For example, in the case of the poly(styrene sulfonic acid)-containing system, the signal intensity of the choline methyl group was decreased about 15% while those of the hydrophobic methylene and terminal methyl groups were scarcely decreased by the addition of polymer to a final concentration of 4.0 · 10^t-2 unit mol/1. These polymers are considered to interact with the surface of the vesicle membrane. On the other hand, poly(l-glutamic acid) and poly($\text{N-}\text{vinyl}\text{-2-}\text{pyrrolidone}$) decreased the signal intensities of not only the choline methyl group, but also those of the hydrophobic methylene and terminal methyl groups. This result suggest that part of these polymers might be incorporated into the hydrophobic region of the vesicle membrane.Addition of the non-ionic polymers inhibited vesicle fusion considerably. This effect was explained by the stabilization of dipalmitoyl phosphatidylcholine vesicles by complexation with these polymers.