Conjugation of polyethylene glycol via a disulfide bond confers water solubility upon a peptide model of a protein transmembrane segment.

The aqueous insolubility of hydrophobic peptides has presented a barrier to the structural characterization of membrane protein transmembrane domains. Since the conjugation of polyethylene glycol is known to modulate the solubility of certain proteins and peptides, we have prepared PEG-a-Cys reagent, a polyethylene glycol derivative which reacts spontaneously with Cys residues to attach polyethylene glycol to polypeptides via a mixed disulfide bond. When desired, the PEG moiety can be readily removed by reduction with tricarboxyethylphosphine. The aqueous solubilizing power of PEG-a-Cys reagent is confirmed with a synthetic hydrophobic peptide model of a generic transmembrane segment-soluble carrier fusion protein.     

Solubility of plasma proteins in the presence of polyethylene glycol

The solubility of plasma proteins was studied at various pH as a function of polyethylene glycol concentration. Computer analysis of precipitation curves permitted equations to be derived. The equations describe the relationship between protein solubility and polyethylene glycol concentration. The analysis of the equations furnished further data for the validity of the displacement theory.     

Solubility behavior of enzymes after addition of polyethylene glycol to erythrocyte hemolysates

The addition of polyethylene glycol to a hemolysate of rat erythrocytes reduces the solubility of phosphofructokinase and glucose-6-phosphate and 6-phosphogluconate dehydrogenases in an exponential manner with respect to polymer concentration. Analyses of the solubility curves (log solubility versus polymer concentration) obtained at different pH values suggest that the solubility can be related to both the aggregation state and the intrinsic solubility of the proteins promoted by solution conditions. These findings suggest the possibility of using polyethylene glycol in a rational way for the fractional precipitation of a mixture.     

Effects of polyethylene glycol and dextrans on immunoprecipitations: a two-cross immunodiffusion study

Precipitating titers and immunochemical titers obtained in a wide range of antigen-to-antibody concentration ratios by the two-cross immunodiffusion technique are compared with the corresponding laser light scatter precipitin curves. The two-cross immunodiffusion technique has also been applied to investigate whether polyethylene glycol of molecular mass 6000 and dextrans of molecular masses from 10,000 to 2,000,000 enhance the immunoprecipitation processes of the system human serum IgG-rabbit immune serum at pH 5.5 and 8.1 at 20 degrees C. It was found that the significant increase of precipitating titers of both precipitating components in the presence of polyethylene glycol is a consequence of a strong decrease of solubility of the primary antigen-antibody complex. The decrease of solubility does not affect the immunochemical titer of the immune serum, indicating stoichiometrical invariance of the precipitate at the equivalence. The apparent strong decrease of diffusion coefficients of both antigen and antibody in 20- and 40-g/liter polyethylene glycol solution is attributed to increase of viscosity of the solutions and to a partial self-association of protein molecules due to steric exclusion. In 40-g/liter polyethylene glycol solutions at pH 5.5 every fourth molecular entity of antigen and every third molecular entity of antibody are present in the form of a two-molecular self-associate, whereas in 20-g/liter polyethylene glycol solutions only 1% of antigen molecules and 8% of antibody molecules are associated. With the increase of pH to 8.1 the self-association of protein molecules is strongly further enhanced. Dextrans in 20-g/liter solutions, without regard to their relative molecular masses, do not influence precipitating titers and solubility of the antigen-antibody system at equivalence and do not enhance self-association of protein molecules. The strong decrease of diffusion coefficients of immunoglobulin G antigen and antibodies in dextran solutions is solely attributed to the increase of viscosity of the dextran solutions; hence there was no evidence of interaction of dextrans with serum IgG proteins.     

Oxygen availability in polyethylene glycol solutions and its implications in plant-water relations

The solubility of O₂ in polyethylene glycol 4000 and 6000 solutions of varying concentrations was determined iodimetrically (titrimetrically) and electrochemically using a rotating glassy carbon electrode and a PAR Model 174 Polarograph. The titrimetric determination resulted in the formation of an unexpected precipitate at 2% (w/v) polyethylene glycol corresponding to the approximate critical micelle concentration of the two polyethylene glycol homologs. Beyond 5% polyethylene glycol, O₂ concentration was inversely proportional to polyethylene glycol concentration, and was higher in polyethylene glycol 4000 solutions than in polyethylene glycol 6000. The electrochemical data are a direct measure of O₂ transport to the electrode surface, rather than O₂ activity or concentration. Results indicate that even at relatively high H₂O potentials, the transport of O₂ to the root surface might be insufficient to meet the plant's respiratory requirements.     

Porcine pancreatic lipase partition in potassium phosphate-polyethylene glycol aqueous two-phase systems

This research study examined porcine pancreatic lipase partition in aqueous two-phase systems formed by polyethylene glycol-potassium phosphate at pH 6.0, 7.0 and 8.0, the effect of polymer molecular mass, and NaCl concentration. The enzyme was preferentially partitioned into the polyethylene glycol rich phase in systems with molecular mass 4000-8000, while with polyethylene glycol of 10,000 molecular mass it was concentrated in the phosphate rich phase. The enthalpic and entropic changes found due to the protein partition were negative for all the polyethylene glycol molecular mass systems assessed. Both thermodynamic functions were shown to be associated by an entropic-enthalpic compensation effect suggesting that the water structure ordered in the ethylene chain of polyethylene glycol plays a role in the protein partition. The addition of NaCl increased the lipase affinity to the top phase and this effect was most significant in the system polyethylene glycol 2000-NaCl 3%. This system yielded an enzyme recovery more than 90% with a purification factor of approximately 3.4.     

Polyethylene glycol behaves like weak organic solvent

Effect of polyethylene glycol (PEG) on protein solubility has been primarily ascribed to its large hydrodynamic size and thereby molecular crowding effect. However, PEG also shows characteristics of organic solvents. Here, we have examined the solubility of glycine and aliphatic and aromatic amino acids in PEG solutions. PEG400, PEG4000, and PEG20000 decreased the solubility of glycine, though to a much smaller magnitude than the level achieved by typical organic solvents, including ethanol and dimethyl sulfoxide. PEG4000 showed varying degree of interactions with amino acid side chains. The free energy of aliphatic side chains marginally increased by the addition of PEG4000, indicating their weak unfavorable interactions. However, it significantly decreased the free energy of the aromatic side chains and hence stabilized them. Thus, it was concluded that PEG behaves like weak organic solvents; namely PEG destabilized (interacted unfavorably with) polar and charged groups and stabilized (interacted favorably with) aromatic groups. Interestingly, the interaction of PEG20000, but neither PEG400 nor PEG4000, with glycine resulted in phase separation under the saturated concentration of glycine.     

Anatomical repair of nerve membranes in crushed mammalian spinal cord with polyethylene glycol

Acute damage to axons is manifested as a breach in their membranes, ion exchange across the compromised region, local depolarization, and sometimes conduction block. This condition can worsen leading to axotomy. Using a novel recording chamber, we demonstrate immediate arrest of this process by application of polyethylene glycol (PEG) to a severe compression of guinea pig spinal cord. Variable magnitudes of compound actions potentials (CAPs) were rapidly restored in 100% of the PEG-treated spinal cords. Using a dye exclusion test, in which horseradish peroxidase is imbibed by damaged axons, we have shown that the physiological recovery produced by polyethylene glycol was associated with sealing of compromised axolemmas. Injured axons readily imbibe horseradish peroxidase—but not following sealing of their membranes. The density of nerve fibers taking up the marker is significantly reduced following polyethylene glycol treatment compared to a control group. We further show that all axons—independent of their caliber—are equally susceptible to the compression injury and equally susceptible to polyethylene glycol mediated repair. Thus, polyethylene glycol—induced reversal of permeabilization by rapid membrane sealing is likely the basis for physiological recovery in crushed spinal cords. We discuss the clinical importance of these findings.     

Cryoprotection of purified rat kidney transamidinase by polyethylene glycol.

Polyethylene glycol is a water-soluble polymer which is widely used in the pharmaceutical, cosmetic, and chemical industries. In this study, it is shown that polyethylene glycol is an effective cryoprotectant of rat kidney transamidinase purified from both the mitochondria and cytosol. Much of the activity is lost when the purified enzyme is frozen and thawed in sodium-potassium phosphate buffer in the absence of cryoprotectants. Polyethylene glycols with molecular weights of 4000 to 10,000 were effective cryoprotectants. However, polyethylene glycols with a molecular weight of 1000 or lower inhibited the purified enzyme. A concentration of only 0.01% polyethylene glycol 4000, 8000, or 10,000 was required for complete cryoprotection. In addition to polyethylene glycol, 0.5 mM ethylenediaminetetraacetic acid was required in the phosphate buffer for complete cryoprotection. The stabilization of purified transamidinase by polyethylene glycol will facilitate characterization experiments designed to compare the properties of the mitochondrial and cytosolic isozymes.     

Studies of the fiber to crystal transition of sickle cell hemoglobin in acidic polyethylene glycol

The crystallization of deoxygenated sickle cell hemoglobin in acidic (pH 5.2) polyethylene glycol (10%) has been studied in order to determine if the mechanism of crystal formation under such conditions has features in common with the mechanism of crystal formation at higher pH values in the absence of polyethylene glycol. The existence of a common mechanism of crystallization under different conditions is relevant in validating the use of the known high resolution crystal structure to interpret the fiber structure. Our findings indicate that deoxygenated sickle cell hemoglobin crystallization in acidic polyethylene glycol is initiated by fiber formation. Fibers, in turn, convert to larger structures called macrofibers within several hours (Wellems et al., 1981). Fibers and macrofibers (and their respective optical transforms) formed in acidic polyethylene glycol appear to have the same structure as their counterparts formed at higher pH values in the absence of polyethylene glycol. Early in the transition one can observe macrofibers in the process of alignment and fusion. The structural characterization of the intermediates leaves little doubt that crystallization in acidic polyethylene glycol is mediated by the same mechanism as that occurring under more physiological conditions, and that fibers are a metastable intermediate whose ultimate fate is to crystallize.     

Review: model peptides and the physicochemical approach to beta-amyloids

beta-Amyloid peptides are the main protein components of neuritic plaques and may be important in the pathogenesis of Alzheimer's Disease. The determination of the structure of beta-amyloid fibrils poses a challenge because of the limited solubility of beta-amyloid peptides and the noncrystalline nature of fibrils formed from these peptides. In this paper, we describe several physicochemical approaches which have been used to examine fibrils and the fibrillogenesis of peptide models of beta-amyloid. Recent advances in solid state NMR, such as the DRAWS pulse sequence, have made this approach a particularly attractive one for peptides such as beta-amyloid, which are not yet amenable to high-resolution solution phase NMR and crystallography. The application of solid state NMR techniques has yielded information on a model peptide comprising residues 10-35 of human beta-amyloid and indicates that in fibrils, this peptide assumes a parallel beta-strand conformation, with all residues in exact register. In addition, we discuss the use of block copolymers of Abeta peptides and polyethylene glycol as probes for the pathways of fibrillogenesis. These methods can be combined with other new methods, such as high-resolution synchrotron X-ray diffraction and small angle neutron and X-ray scattering, to yield structural data of relevance not only to disease, but to the broader question of protein folding and self-assembly.     

Immobilization of nitrifying bacteria by polyethylene glycol prepolymer

The effects of immobilizing materials on the activity of nitrifying bacteria were investigated by using 11 kinds of prepolymers of polyethylene glycol. Relative respiratory activity of immobilized nitrifying bacteria with polyethylene glycol metacrylate prepolymer was higher than that of polyethylene glycol acrylate prepolymer, and there was a tendency for relative respiratory activity to be higher with a prepolymer of greater molecular weight. With the polyethylene glycol prepolymer, there was a drastic improvement over the conventional method of immobilization by acrylamide in the relative respiratory activity of the pellet. Inorganic synthetic wastewater was treated under a high loading rate of 1.14 kg-N/m³·d. Influent NH₄-N could be removed to 2 mg/l or less and the nitrogen removal was 90%.     

Simplified procedure for transient transformation of plant protoplasts using polyethylene glycol treatment

A modification of the polyethylene glycol-mediated transformation procedure which eliminates the manual polyethylene glycol dilution step is presented. A transformation mixture of protoplasts, DNA and polyethylene glycol was plated directly onto agarose blocks after incubation. The procedure was simple and fast, thereby suitable for screening the gene activity of large numbers of plasmid constructions. It has been tested for both maize and rice protoplasts.     

Bilateral peripheral facial nerve palsy in acute poisoning with ethylene glycol

Acute poisonings with polyethylene glycol become more and more frequent. The acute poisoning with polyethylene glycol leads to a considerable metabolic acidosis and acute renal failure. Usually there is no peripheral nervous system involvement. Two cases of the bilateral facial nerve palsy in patients with renal failure due polyethylene glycol poisoning are presented. It seems that it is the first report on the lesions to facial nerve involvement in the course of the acute polyethylene glycol poisoning.     

Acceleration of nucleic acid hybridization rate by polyethylene glycol

The addition of polyethylene glycol to filter-bound nucleic acid hybridization greatly increases the hybridization rate. With single-stranded probes, the increase obtained with polyethylene glycol is significantly greater than that obtained with dextran sulfate. Additionally, polyethylene glycol is easier to manipulate and less expensive than dextran sulfate.     

Degradation of ethylene glycol and polyethylene glycols by methanogenic consortia.

Methanogenic enrichments capable of degrading polyethylene glycol and ethylene glycol were obtained from sewage sludge. Ethanol, acetate, methane, and (in the case of polyethylene glycols) ethylene glycol were detected as products. The sequence of product formation suggested that the ethylene oxide unit [HO-(CH2-CH2-O-)xH] was dismutated to acetate and ethanol; ethanol was subsequently oxidized to acetate by a syntrophic association that produced methane. The rates of degradation for ethylene, diethylene, and polyethylene glycol with molecular weights of 400, 1,000, and 20,000, respectively, were inversely related to the number of ethylene oxide monomers per molecule and ranged from 0.84 to 0.13 mM ethylene oxide units degraded per h. The enrichments were shown to best metabolize glycols close to the molecular weight of the substrate on which they were enriched. The anaerobic degradation of polyethylene glycol (molecular weight, 20,000) may be important in the light of the general resistance of polyethylene glycols to aerobic degradation.     

Polyethylene glycol interferes with protein molecular weight determinations by gel filtration

Gel filtration studies on Sephadex G-75 demonstrate markedly increased elution volumes for proteins chromatographed with polyethylene glycol. As little as 5% (w/v) polyethylene glycol in the applied protein sample can reduce apparent molecular weight estimates by gel filtration as much as 55%. Furthermore, gel filtration columns equilibrated with polyethylene glycol are not size-separating columns. Consequently, caution must be exercised when performing and interpreting gel filtration studies of proteins previously treated or precipitated with polyethylene glycol.     

Enhancement of ribonucleotide reductase activity at low enzyme concentrations by polyethylene glycol

The estimation of ribonucleotide reductase in cell extracts has been problematical on account of abnormally low activities at low enzyme concentrations, presumably due to subunit dissociation. This problem can be alleviated by assaying the enzyme in the presence of polyethylene glycol. The presence of 15% polyethylene glycol during the assay greatly stimulated ribonucleotide reductase activity at low enzyme concentrations and allowed measurement of enzyme activity in as little as 10(5) mouse L929 cells, a 30-fold enhancement of assay sensitivity. Enzyme activity measured in the presence of 15% polyethylene glycol was proportional to enzyme concentration, thus making possible the accurate measurement of very low levels of ribonucleotide reductase.     

Functional properties of normal and sickle cell hemoglobins in polyethylene glycol 6000.

The functional properties of human hemoglobin A and S were studied in concentrated solutions of polyethylene glycol. Polyethylene glycol solutions are frequently used as media for protein crystallization. In particular, sickle cell hemoglobin, which does not make X-ray quality crystals in high salt solutions, will form high-quality crystals in polyethylene glycol. Comparison of the functional properties of normal and sickle cell hemoglobin in polyethylene glycol show that pH, anion effects and cooperativity of ligand binding are largely unaffected by polyethylene glycol. This suggests that the crystals grown in this medium are representative of the native structure.