Polyethyleneimine phosphate and citrate systems act like pseudo polyampholytes as a starting method to isolate pepsin

The aqueous solution behaviour of polyethyleneimine (a cationic synthetic polymer) in the presence of anions (such as citrate and phosphate) was studied by means of turbidimetry. The variation of the absorbance at 420 nm of dilute mixture with pH, the polymer concentration and the ionic strength were examined. The mixture of polyethyleneinine citrate or polyethyleneinine phosphate behaves as a pseudo polyampholyte with an isoelectric point of 5.5 and 6.2 for phosphate and citrate respectively and a precipitation pH range between 3.5 and 8.0. Pepsin was completely precipitated with the polymer anion complex within this pH interval. Citrate showed a better precipitation effect than phosphate did. The precipitate was reversibly dissolved in NaCl (for concentrations higher than 0.2 M) and pepsin kept its biological activity. Studies of pepsin thermal stability (by differential scanning calorimetry) revealed that the polyethyleneimine presence increased the enzyme denaturation temperature. The circular dichroism spectrum of pepsin showed a non-significant loss of secondary and tertiary enzyme structure by the polyethyleneimine. However, the polymer presence increased the biological activity of pepsin.     

Influence of hetero-association on the precipitation of proteins by poly(ethylene glycol)

The influence of hetero-association on the precipitation of proteins by poly(ethylene glycol) was investigated by comparing the precipitation of binary mixtures to that of the individual proteins. Pronounced enhancement of precipitation was observed for several mixtures, with maximum effect at low ionic strength at a pH between the pI's. Measurements of sedimentation velocity and/or fluorescence polarization of dansyl-labeled components revealed that conditions fostering precipitation of a given mixture also enhanced the formation of soluble hetero-complexes in the absence of poly(ethylene glycol). Conversely, enhanced precipitation was not observed under conditions where complexes were shown to be absent. Poly(ethylene glycol) does not appear to influence such interactions and thus can be used to detect the presence of hetero-complexes in a binary mixture whose precipitation curve is shifted relative to those of its components.     

Isoelectric focusing of complex protein mixtures in the nanogram range in microgels (author's transl)]

A method is described for isolectric focusing of complex protein mixtures in 2, 5 or 10 mul capillaries. For one separation only 15- 50 ng of a protein mixture is needed. Isoelectric focusing is finished after 10 min, staining takes 20 min and destaining approximately 30 min. Using defined mixtures of Servalyt from different pH ranges, isoelectric focusing can be adapted to the protein sample to be fractionated. Protein peaks separated by isoelectric focusing can be electrophoretically eluted and for further analysis refractionated directly in a microgradient gel. The resolution power of microisoelectric focusing is as good as that of the wellknown macroprocedure, as is demonstrated by isoelectric focusing of the water soluble proteins from cerebellum and heart, of rat and human serum and of a human oncocytoma of the thyroid gland.     

Potential for ultrafast protein separations with capillary-channeled polymer (C-CP) fiber columns

Capillary-channeled polymer (C-CP) fibers are demonstrated as a potential stationary phase for liquid chromatography separation of protein mixtures. Separation of a synthetic mixture of four proteins is accomplished within a 45-second window using a conventional revered-phase (RP) gradient, at a mobile phase flow rate of 7 mL/min (10,200 mm/min).     

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.     

Kinetics of biodegradation of binary and ternary mixtures of PAHs

The kinetics of biodegradation of mixtures of polycyclic aromatic hydrocarbons (PAHs) by Sphingomonas paucimobilis strain EPA505 were investigated. The investigation focused on three- and four-ring PAHs, specifically 2-methylphenanthrene, fluoranthene, and pyrene. Uptake rates in aerobic batch suspended cultivations were measured for the individual PAHs and their binary and ternary mixtures. It was observed that kinetics were influenced by the mixture composition and the kinetic properties of the components. A material balance equation containing the Monod model was numerically fitted to uptake data to determine extant kinetic parameters for the individual PAHs. Similarly, equations containing kinetic interaction models derived from enzyme kinetics were fitted to the uptake data obtained from experiments with binary and ternary mixtures. The investigation considered the following interaction types: no-interaction (Monod), pure competitive interaction, noncompetitive or mixed-type interaction, uncompetitive inhibition, and nonspecific interaction based on pure competition (SKIP). Model fit was evaluated based on probabilistic and statistical criteria and inferences were reached about underlying interaction mechanisms based on model fit. Mixture kinetics were most adequately simulated by the pure competitive interaction model with mutual substrate exclusivity. This model is fully predictive, relying only on parameters determined in the sole-PAH experiments. It was shown that for low percent inhibition values and with limited data, pure competitive interaction kinetics may not be evident, resembling no-interaction kinetics. This study is a reasonable starting point for understanding and modeling biodegradation of complex PAH mixtures in engineered and natural systems.     

Apolar interaction of alpha-chymotrypsin with dimyristoyl phosphatidylcholine vesicles

The interaction of bovine pancreatic alpha-chymotrypsin with dimyristoyl phosphatidylcholine (PC) vesicles was measured turbimetrically. The protein interacted with the vesicles at NaCl concentrations of above 0.8 M. The turbidity reached a plateau on increase in the amount of either the protein or the vesicles in the presence of a fixed amount of the other component. The precipitates formed contained both PC and protein in ratios varying with the initial amount of each component. On mixing chymotrypsin and PC vesicles, time-dependent turbidity increase was high at below pH 2.5, but relatively small at neutral and alkaline pH values. Apolar interaction between the two components was confirmed by demonstrating an increase in fluorescence intensity of chymotrypsin in the presence of the PC in 1 M NaCl. The turbidity of a mixture of PC vesicles and bovine serum albumin (BSA) increased even in the absence of 1 M NaCl, whereas the turbidities of mixtures of the vesicles and lysozyme or alpha-lactalbumin did not change with time in the presence of 1 M NaCl at pH 8.0.     

Isoelectric focusing in continuous-flow electrophoresis. I. Separation of mixed red blood cells of different species.

A noncommercial continuous-flow isoelectric focusing (CIF) apparatus which was formerly applied to separate mixtures of proteins was used to study the separation of red blood cells (RBC's) of different species. A mixture of human, mouse and rabbit erythrocytes, a good model for demonstration of cell separation by CIF, was completely separated into the three components. The separation was performed by isoelectric focusing in pH gradients, 3–10 and 5–7, using Ampholine carrier ampholytes at a field strength of 110 V/cm and a flow-through time of RBC's of 7 min. The isoionic points of human RBC's both determined by CIF and calculated from electrophoretic mobility measurements by extrapolation to zero electrophoretic mobility and zero ionic strength were found at pH 5.6–5.7. The method of CIF which is presently used to isolate a pure lysosomal fraction seems to be a valuable method for the separation of mixtures of cells or cell organelles.     

Synthesis, characterization, and evaluation as transfection reagents of ampholytic star copolymers: effect of star architecture

Five star polymers based on the positively ionizable hydrophilic 2-(dimethylamino)ethyl methacrylate (DMAEMA) and the hydrophobic but hydrolyzable tetrahydropyranyl methacrylate (THPMA) were prepared by group-transfer polymerization (GTP) using ethylene glycol dimethacrylate (EGDMA) as the coupling agent. In particular, four isomeric star copolymers (one heteroarm, two star block, and the statistical star), all with a 3:1 DMAEMA:THPMA molar ratio, plus one star homopolymer of DMAEMA, with degrees of polymerization of the arms equal to 15, were synthesized. After star polymer preparation and preliminary characterization, the THPMA units were hydrolyzed to negatively ionizable hydrophilic methacrylic acid (MAA) untis, thus yielding star polyampholytes. All the star polyampholytes as well as the commercially available transfection reagent SuperFect were evaluated for their ability to transfect human cervical HeLa cancer cells with the modified plasmid pRLSV40 bearing the enhanced green fluorescent protein (EGFP) as the reporter gene. The transfection efficiency was affected by star architecture. The DMAEMA15-star-MAA5 polyampholyte presented the highest transfection efficiency of all the star polymers tested but lower than that of SuperFect at its optimum conditions. All four star copolymers showed decreased toxicity compared to the DMAEMA star homopolymer for the same amounts of star polymer tested and also compared to the SuperFect at its optimum conditions.     

pH dependence and protein selectivity of poly(ethyleneimine)/poly(acrylic acid) multilayers studied by in situ ATR-FTIR spectroscopy

The selective interaction between polyelectrolyte multilayers (PEM) consecutively adsorbed from poly(ethyleneimine) (PEI) and poly(acrylic acid) (PAC) and a binary mixture containing concanavalin A (COA) and lysozyme (LYZ) based on electrostatic interaction is reported. The composition and structure of the PEM and the uptake of proteins were analyzed by in situ attenuated total reflection (ATR) Fourier transform infrared (FTIR) spectroscopy, and the morphology and thickness were characterized by atomic force microscopy (AFM) and ellipsometry. The PEM dissociation degree and charge state and the protein adsorption were shown to be highly dependent on the outermost layer type and the pH in solution. High protein uptake was obtained under electrostatically attractive conditions. This was used to bind selectively one protein from a binary mixture of LYZ/COA. In detail it could be demonstrated that six-layered PEM-6 at pH = 7.3 showed a preferential sorption of positively charged LYZ, while at PEM-5 and pH = 7.3 negatively charged COA could be selectively bound. No protein sorption from the binary mixture was observed at pH = 4.0 for both PEM, when COA, LYZ, and the outermost PEI layer of PEM-5 were positively charged or the outermost PAC layer of PEM-6 was neutral. Furthermore, from factor analysis of the spectral data the higher selectivity was found for PEM-5 compared to PEM-6. Increasing the ionic strength revealed a drastic decrease in the selectivity of both PEM. Evidence was found that the proteins were predominantly bound at the surface and to a minor extent in the bulk phase of PEM. These results suggest possible working regimes and application fields of PEI/PAC multilayer assemblies related to the preparative separation of binary and multicomponent protein mixtures (biofluids, food) as well as to the design of selective protein-resistant surfaces.     

A comparison of the dodecyl sulfate-induced precipitation of the myelin basic protein with other water-soluble proteins

The interactions of sodium dodecyl sulfate with a number of proteins were examined at a variety of pH values ranging from 4.8 to 11.6 The dodecyl sulfate-induced precipitation of some of these proteins was observed within a relatively limited range of total dodecyl sulfate concentration. Most of the basic proteins precipitated at low pH but as the isoelectric point of the protein was approached the amount of protein that precipitated decreased. Bovine myelin basic protein was unique in that it precipitated at all pH values examined both above and below its isoelectric point. Thus, the dodecyl sulfate-induced precipitation of myelin basic protein appears to be different from the dodecyl sulfate-induced precipitation of most proteins. A comparison of protein precipitation at equivalent dodecyl sulfate: protein molar or weight ratios revealed very little difference in the precipitation behavior of the proteins studied. When the bovine myelin basic protein was cleaved at its single tryptophan residue, the N-terminal fragment (1–115) formed insoluble dodecyl sulfate complexes at pH values ranging from 4.8 to 9.2. The C-terminal fragment (116–169) precipitated almost completely at pH 4.8 but to a lesser extent at pH 7.4 and 9.2 Equimolar mixtures of the N- and C-terminal fragments precipitated in the presence of dodecyl sulfate at pH 7.4 and 9.2 to an extent greater than the C-terminal fragment alone but comparable to the N-terminal fragment alone or the whole basic protein. These results suggest: (a) that the mechanism by which dodecyl sulfate induces the precipitation of myelin basic protein may be unique compared to other proteins and (b) that the intact myelin basic protein is not necessary for its precipitation by dodecyl sulfate.     

Interactions of surfactants with a water treatment protein from Moringa oleifera seeds in solution studied by zeta-potential and light scattering measurements

Protein extracted from Moringa oleifera (MO) seeds has been advocated as a cheap and environmental friendly alternative to ionic flocculants for water purification. However, the nature and mechanism of its interaction with particles in water, as well as with dissolved surface-active molecules, are not well understood. In this article, we report studies of the protein and its interaction with four surfactants using dynamic light scattering (DLS), zeta-potential and turbidity measurements. Zeta-potential measurements identified points of charge reversal and the turbidity and DLS measurements were used to characterize the microstructure and size of protein-surfactant complexes. From the points of charge reversal, it was estimated that 7 anions are required to neutralize the positive charges of each protein molecule at pH 7. For protein mixtures with sodium dodecyl sulfate and dodecyl di-acid sodium salt, the peak in turbidity corresponds to concentrations with a large change in zeta-potential. No turbidity was observed for protein mixtures with either the nonionic surfactant Triton X-100 or the zwitterionic surfactant N-dodecyl-N,N-dimethyl-3-ammonio-1-propanesulfonate. Changes of pH in the range 4-10 have little effect on the zeta-potential, turbidity, and the hydrodynamic radius reflecting the high isoelectric point of the protein. Addition of small amounts of salt has little effect on the size of protein in solution. These results are discussed in the context of the use of the MO protein in water treatment.     

Effects of protein-protein interaction in ultrafiltration based fractionation processes

This paper discusses the use of pulsed sample injection ultrafiltration (UF) for investigating protein-protein interaction, particularly its effect on protein transmission through UF membranes. Several binary protein mixtures were investigated; the proteins in each mixture being selected such that one of the proteins in the pair would be preferentially transmitted while the other would be either totally or substantially retained. The "retained" protein either decreased or increased or did not affect the sieving coefficient of the "transmitted" protein, this depending the type of protein-protein interaction, that is, associative, repulsive, or neutral. The type of protein-protein interaction depended on the particular protein pair under investigation as well as on the operating conditions used (pH and salt concentration). The magnitude of either decrease or increase in transmission of a preferentially transmitted protein due to the presence of a retained protein was found to be independent of the manner in which the proteins were injected into the system, that is, simultaneous or sequential. These magnitudes however correlated well with the ratio of the two proteins present in the feed.     

Tuning supramolecular structuring at the nanoscale level: nonstoichiometric soluble complexes in dilute mixed solutions of alginate and lactose-modified chitosan (chitlac)

Two oppositely charged polysaccharides, alginate and a lactose-modified chitosan (chitlac), have been used to prepare dilute binary polymer mixtures at physiological pH (7.4). Because of the negative charge on the former polysaccharide and the positive charge on the latter, polyanion-polycation complex formation occurred. A complete miscibility between the two polysaccharides was attained in the presence of both high (0.15 M) and low (0.015 M) concentrations of simple 1:1 supporting salt (NaCl), as confirmed by turbidity measurements; phase separation occurred for intermediate values of the ionic strength (I). The binary solutions were further characterized by means of light scattering, specific viscosity, and fluorescence quenching measurements. All of these techniques pointed out the fundamental role of the electrostatic interactions between the two oppositely charged polysaccharides in the formation of nonstoichiometric polyelectrolyte soluble complexes in dilute solution. Fluorescence depolarization (P) experiments showed that the alginate chain rotational mobility was impaired by the presence of the cationic polysaccharide when 0.015 M NaCl was used. Moreover, upon addition of calcium, the P values of the binary polymer mixture in 0.015 M NaCl increased more rapidly than that of an alginate solution without chitlac, suggesting an efficient crowding of the negatively charged alginate chains caused by the polycation.     

Affinity precipitation of an antibody by ligand-modified phospholipids

A new method for the selective precipitation of proteins is applied to the isolation and purification of an antibody. Ligand-modified phospholipids (LMPs) are solubilized by the nonionic ethoxylated alcohol detergent, resulting in small (50 to 100 A) micellar aggregates of LMPs and surfactant. When introduced into protein solutions containing an antibody for which the LMP has specific affinity, the ligand binds to the protein. Hydrophobic interactions between phospholipid tail groups bound to the protein molecules result in an insoluble precipitate. Polyclonal and monoclonal antibiotin antibody (pABA and mABA) are shown to be selectively precipitated using ratios of dimyristoylphosphatidylethanolamidobiotin (DMPE-B) to ABA ranging from 1:1 to 19:1. The kinetics and yield of the precipitation achieve a maximum at a ratio of DMPE-B to ABA of approximately 7:1. The kinetics and magnitude of the turbidity change are modeled using the Mie theory of light scattering coupled with the smoluchowski theory of aggregation. The kinetics are shown to be enhanced significantly by the addition of salt. In particular, the addition of 0.5 M ammonium sulfate salt increases the rate of precipitation by more than an order of magnitude. It is demonstrated that pABA can be recovered with total activity yields of 60% to 70% from mixtures containing nonspecific lgG antibodies in very high purity (>99%). (c) 1994 John Wiley & Sons, Inc.     

Isoelectric focusing of plant cell protoplasts: separation of different protoplast types

The surface charge of plant protoplasts has been measured by a new technique, isoelectric focusing. The protoplasts were loaded in a dextran density gradient over which a pH gradient was superimposed. When voltage was applied, protoplasts moved to a point in the gradient corresponding to their isoelectric point (pI). The pI of the protoplasts varied with the compounds used for pH gradient generation. Using commercial ampholytes for pH gradient formation, the pI of all protoplasts tested was 4.4 ± 0.2, and viability following electrophoresis was low. Using an acetate/acetic acid mixture to generate the pH gradient, the pI of protoplasts varied from 3.7 to 5.3 depending on the species and tissue type of the parental cells. Postelectrophoresis viability was high. Using isoelectric focusing techniques, it was possible to separate mixtures of protoplasts derived from different species of plants.     

Effect of divalent ions on protein precipitation with polyethylene glycol: mechanism of action and applications.

Polyethylene glycol (PEG) is extensively employed for protein purification by fractional precipitation. Efficiency of precipitation is highest when the solution pH is near the isoelectric point of the target protein. At pH values far from the isoelectric point of the target protein, proteins develop a net positive or negative charge and are not more resistant to precipitation. We have found that divalent cations (Ba2+, Sr2+, and Ca2+) or divalent anions (SO4(2-)) significantly change the pattern of PEG precipitation when the ion is chosen so as to counteract the expected net charge on the target protein. At moderate (5-50 mM) concentrations of Ba2+, negatively charged proteins can be precipitated from solution at pH values as high as 10 with efficiency unchanged from precipitation at pH values near their isoelectric point values. The mechanism of PEG precipitation of protein at these high pH values appears to be unchanged from the mechanism operative at the protein isoelectric point. Precipitation is rapid and the capacity for protein precipitation is high. There is no detectable coprecipitation of small molecules (AMP, ATP, and NADH) or soluble proteins (carbonic anhydrase) induced when large quantities of protein are precipitated by this method. The purification of bovine carbonic anhydrase from erythrocyte lysate is more efficient at pH 10 in the presence of Ba2+ than is conventional PEG precipitation carried out at the isoelectric point of carbonic anhydrase. Application of these observations should broaden the utility of protein purification by fractional precipitation with PEG.     

Susceptibility of food-borne bacteria to binary combinations of antimicrobials at selected a(w) and pH

AIM: To evaluate the antibacterial susceptibilities of food-borne bacteria to individual and binary mixtures of a synthetic antimicrobial agent with a natural phenolic compound. METHODS AND RESULTS: Antibacterial susceptibilities of Escherichia coli, Listeria innocua, Salmonella Typhimurium and Staphylococcus aureus to individual and binary mixtures of potassium sorbate with a phenolic compound (thymol, carvacrol, or eugenol) were evaluated, at selected water activity (a(w); 0.99 or 0.97) and pH (5.5 or 4.5). The bacteria studied were susceptible to the action of the antimicrobials individually with minimal inhibitory concentrations that varied from 800-ppm potassium sorbate for Staph. aureus at a(w) 0.99, and pH 5.5 to 100-ppm thymol or carvacrol for the four studied bacteria at a(w) 0.97 and pH 4.5. Several binary mixtures of potassium sorbate with thymol, carvacrol or eugenol inhibited bacterial growth. Antimicrobial agent inhibitory concentrations in the mixture varied among bacteria, additionally depending on the a(w) and the pH tested. CONCLUSIONS: Synergistic binary mixtures with fractional inhibitory concentration index <0.6 include 100- or 200-ppm potassium sorbate with 50- or 100-ppm thymol, carvacrol or eugenol. SIGNIFICANCE AND IMPACT OF THE STUDY: The synergistic combinations could be useful in reducing the amounts of antimicrobials needed to inhibit growth, thus diminishing consumer concerns regarding chemical preservatives.     

Precipitation of egg white proteins below their isoelectric points by sodium dodecyl sulphate and temperature.

The precipitating of effect of sodium dodecyl sulphate (SDS) on the egg white proteins ovalbumin, conalbumin and lysozyme was studied at 25 degrees C and at different pH values. The proteins precipitated below their respective isolectric points, provided the detergent to protein ratio was appropriate. The pH profile of precipitation was different for the three proteins reflecting net charge differences. The binding of SDS to the proteins was studied with [35S]-labelled SDS and for ovalbumin a ratio of 21--28 SDS molecules/protein molecule, dependent on the concentration of SDS initially used, seem to be required for precipitation at pH 4.5. This number, however, is dependent on pH and increases with an increased positive net charge of the protein. The precipitating effect of SDS was identical for ovalbumin, conalbumin and lysozyme when compared on a gram to gram basis (0.1--0.15 g SDS/g precipitated protein). The precipitated protein was denatured as measured by differential scanning calorimetry, but was also completely redissolved if pH was increased to above the isoelectric point. The precipitating effecto f SDS was also examined at elevated temperatures. The two-phase systems of the proteins induced by SDS at 25 degrees C were heated from 25 degrees C to 90 degrees C at a rate of 1.25 degrees C/min. The precipitation behaviour was similar for the three proteins upon heating. When the SDS concentration was increased the precipitation curves were transferred towards lower temperatures and the courses of precipitation became less sharp. The synergistic effect of SDS and heat on protein precipitation was differentiated by denaturation measurements and radioactive labelling. The ratio SDS to precipitated protein gradually diminished towards higher temperatures but no purely thermal precipitation was found.     

Characterization of synthetic carrier ampholytes by repetitive scanning of the electric field during focusing

This paper reports the utilization of a potential gradient array detector for monitoring the dynamics of the electric field during isoelectric focusing. Transient and steady state electric field profiles are presented for synthetic carrier ampholyte mixtures with a wide (approximately 3-10) pH range. Two available commercial products (Ampholine and Pharmalyte) and a laboratory synthesized mixture (PEHA ampholytes) are compared. The formation of conductivity gaps and their migration toward the cathode in extended experiments (cathodic drift) can be visualized with this system.