Coarse-grained modeling study of nonpeptide RGD ligand density and PEG molecular weight on the conformation of poly(γ-glutamyl-glutamate) paclitaxel conjugates

Molecular shape, flexibility, and surface hydrophilicity are thought to influence the ability of nanoparticles to cross biological barriers during drug delivery. In this study, coarse-grained (CG) molecular dynamics (MD) simulations were used to study these properties of a polymer-drug construct in potential clinical development: poly(γ-glutamyl-glutamate)-paclitaxel-poly(ethylene glycol) nonpeptide RGD (PGG-PTX-PEG-npRGD), a linear glutamyl-glutamate polymer with paclitaxel and poly(ethylene glycol)-nonpeptide RGD side groups. It was hypothesized that the PEG molecular weight (MW) (500 Da; 1,000 Da; and 2,000 Da) and nonpeptide RGD ligand density (4, 8, 12, and 16 per molecule), respectively, may have advantageous effects on the shape, flexibility, and surface hydrophilicity of PGG-PTX-PEG-npRGD. Circular dichroism spectroscopy was used to suggest initial structures for the all-atom (AA) models of PGG-PTX-PEG-npRGD, which were further converted to CG models using a commercially available mapping algorithm. Due to its semi-flexibility, PGG-PTX-PEG-npRGD is not limited to one specific conformation. Thus, CG MD simulations were run until statistical equilibrium, at which PGG-PTX-PEG-npRGD is represented as an ensemble of statistically similar conformations. The size of a PGG-PTX-PEG-npRGD molecule is not affected by the PEG MW or the nonpeptide RGD density, but higher PEG MW results in increased surface density of a PGG-PTX-PEG-npRGD molecule. Most PGG-PTX-PEG-npRGD shapes are globular, although filamentous shapes were also observed in the PEG500 and PEG1000 molecules. PEG500 and PEG1000 molecules are more flexible than PEG2000 systems. A higher presence of npRGD ligands results in decrease surface hydrophilicity of PGG-PTX-PEG-npRGD. These results indicate that the PGG-PTX-PEG1000-npRGD₄ and PGG-PTX-PEG1000-npRGD₈ molecules are the most efficacious candidates and are further recommended for experimental preclinical studies.     

Thermodynamic study of forces involved in bovine serum albumin and ovalbumin partitioning in aqueous two-phase systems

The partitioning of bovine serum albumin and ovalbumin in different two-phase aqueous polymer systems is investigated using a thermodynamic approach. Systems used were polyethylene glycols (PEGs) of molecular weights 1000 to 10,000 Da and Dextran T500 (500,000 Da). Ovalbumin transfer to the top phase is exothermic, which suggests an electrostatic interaction between the hydroxyl groups of PEG and the hydrophilic side chain of the protein, whereas the bovine serum albumin partition is an endothermic process that is entropically driven, which coincides with its high surface hydrophobicity. The effect of PEG molecular weight on enthalpy and heat capacity changes, associated with the partition of both proteins, is examined on the basis of a preferential interaction of low-molecular-weight PEG with the protein surface.     

Yeast RNA partition accompanying adsorption in salt/PEG two-phase system

Summary Partitioning of yeast total RNA in a salt/PEG two-phase system, i.e., a potassium phosphate/PEG system and a ammonium sulfate/PEG system, was characterized with regard to the dependence on the molecular weights of PEG and RNA. The shift in RNA partitioning was investigated for a PEG molecular weight range from 300 to 20000. RNA was partitioned mainly to the top phase in the system with PEG of a molecular weight up to 1000, mainly at the interface or almost equally to both phases in the system with PEG of a molecular weight 1000–2000, and mainly to the bottom phase in the system with PEG of more than 2000 in a molecular weight . The effect of PEG molecular weight on partitioning of low molecular weight RNA, less than 5.8S molecule, was qualitatively similar to that of high molecular weight RNA, more than 17S molecule. However, partitioning of high molecular weight RNA was more one-sided than that of low molecular weight RNA. In the system with PEG1000–2000, remarkable adsorption of high molecular weight RNA at the interface was investigated; more than 90% of the high molecular weight RNA added was concentrated. Adsorption of RNA at the interface was quantitatively demonstrated as a novel example of adsorption of a soluble macromolecule in an aqueous two-phase system.     

Long functionalized poly(ethylene glycol)s of defined molecular weight: synthesis and application in solid-phase synthesis of conjugates

A concise synthesis of long-chain poly(ethylene glycol) (PEG) of defined molecular weight up to 29 ethyleneoxy units is described. These PEG diols were converted in a two-step synthesis into Fmoc-protected PEG amino acids, suitable as long linkers and compatible with solid-phase peptide synthesis. Long PEG chains (MW > 1000) can be readily synthesized with this method, which has the advantage of defined single molecular weight products over the comparable commercial polymers. The application of these PEG linkers to the synthesis of peptide-PEG-folate conjugates on a solid support was investigated. A method for the solid support synthesis of the targeting component of the conjugate, folic acid-cysteine, was developed, resulting in improved yields with respect to literature methods. The assembly of the peptide, PEG linker, and targeting group on solid support resulted in the synthesis of a conjugate of defined molecular weight and structure.     

Polyethylene glycol-induced mammalian cell hybridization: effect of polyethylene glycol molecular weight and concentration.

The effects of polyethylene glycol (PEG) molecular weight and concentration on mammalian cell hybridization were studied. The peak hybridization-inducing activity with all grades of PEG from 400-6000 was found to occur in the concentration range of 50-55%. However, changes in concentration were seen to have different quantitative effects with different grades of PEG. For monolayer fusions, PEG 1000 at 50% seems to be the optimal combination of PEG molecular weight and concentration, in terms of both efficiency of hybridization and relative insensitivity to dilution effects.     

Interaction of poly(ethylene-glycols) with air-water interfaces and lipid monolayers: investigations on surface pressure and surface potential.

We have characterized the surface activity of different-sized poly(ethylene-glycols) (PEG; M(r) 200-100,000 Da) in the presence or absence of lipid monolayers and over a wide range of bulk PEG concentrations (10(-8)-10% w/v). Measurements of the surface potential and surface pressure demonstrate that PEGs interact with the air-water and lipid-water interfaces. Without lipid, PEG added either to the subphase or to the air-water interface forms relatively stable monolayers. Except for very low molecular weight polymers (PEGs < 1000 Da), low concentrations of PEG in the subphase (between 10(-5) and 10(-4)% w/v) increase the surface potential from zero (with respect to the potential of a pure air-water interface) to a plateau value of approximately 440 mV. At much higher polymer concentrations, > 10(-1)% (w/v), depending on the molecular weight of the PEG and corresponding to the concentration at which the polymers in solution are likely to overlap, the surface potential decreases. High concentrations of PEG in the subphase cause a similar decrease in the surface potential of densely packed lipid monolayers spread from either diphytanoyl phosphatidylcholine (DPhPC), dipalmitoyl phosphatidylcholine (DPPC), or dioleoyl phosphatidylserine (DOPS). Adding PEG as a monolayer at the air-water interface also affects the surface activity of DPhPC or DPPC monolayers. At low lipid concentration, the surface pressure and potential are determined by the polymer. For intermediate lipid concentrations, the surface pressure-area and surface potential-area isotherms show that the effects due to lipid and PEG are not always additive and that the polymer's effect is distinct for the two lipids. When PEG-lipid-mixed monolayers are compressed to surface pressures greater than the collapse pressure for a PEG monolayer, the surface pressure-area and surface potential-area isotherms approach that of the lipid alone, suggesting that for this experimental condition PEG is expelled from the interface.     

Enzymatic activity and thermal stability of PEG-α-chymotrypsin conjugates

α-Chymotrypsin was chemically modified with methoxypoly(ethylene glycol) (PEG) of different molecular weights (700, 2,000, and 5,000 Da) and the amount of polymer attached to the enzyme was varied systematically from 1 to 9 PEG molecules per enzyme molecule. Upon PEG conjugation, enzyme catalytic turnover (k _cat) decreased by 50% and substrate affinity was lowered as evidenced by an increase in the K _M from 0.05 to 0.19 mM. These effects were dependent on the amount of PEG bound to the enzyme but were independent of the PEG size. In contrast, stabilization toward thermal inactivation depended on the PEG molecular weight with conjugates with the larger PEGs being more stable.     

Polyethylenimine-graft-poly(ethylene glycol) copolymers: influence of copolymer block structure on DNA complexation and biological activities as gene delivery system

For two series of polyethylenimine-graft-poly(ethylene glycol) (PEI-g-PEG) block copolymers, the influence of copolymer structure on DNA complexation was investigated and physicochemical properties of these complexes were compared with the results of blood compatibility, cytotoxicity, and transfection activity assays. In the first series, PEI (25 kDa) was grafted to different degrees of substitution with PEG (5 kDa) and in the second series the molecular weight (MW) of PEG was varied (550 Da to 20 kDa). Using atomic force microscopy, we found that the copolymer block structure strongly influenced the DNA complex size and morphology: PEG 5 kDa significantly reduced the diameter of the spherical complexes from 142 +/- 59 to 61 +/- 28 nm. With increasing degree of PEG grafting, complexation of DNA was impeded and complexes lost their spherical shape. Copolymers with PEG 20 kDa yielded small, compact complexes with DNA (51 +/- 23 nm) whereas copolymers with PEG 550 Da resulted in large and diffuse structures (130 +/- 60 nm). The zeta-potential of complexes was reduced with increasing degree of PEG grafting if MW >or= 5 kDa. PEG 550 Da did not shield positive charges of PEI sufficiently leading to hemolysis and erythrocyte aggregation. Cytotoxicity (lactate dehydrogenase assay) was independent of MW of PEG but affected by the degree of PEG substitution: all copolymers with more than six PEG blocks formed DNA complexes of low toxicity. Finally, transfection efficiency of the complexes was studied. The combination of large particles, low toxicity, and high positive surface charge as in the case of copolymers with many PEG 550 Da blocks proved to be most efficient for in vitro gene transfer. To conclude, the degree of PEGylation and the MW of PEG were found to strongly influence DNA condensation of PEI and therefore also affect the biological activity of the PEI-g-PEG/DNA complexes. These results provide a basis for the rational design of block copolymer gene delivery systems.     

Branched polyethylene glycol for protein precipitation

The use of linear PEGs for protein precipitation raises the issues of high viscosity and limited selectivity. This paper explores PEG branching as a way to alleviate the first problem, by using 3-arm star as the model branched structure. 3-arm star PEGs of 4,000 to 9,000 Da were synthesized and characterized. The effects of PEG branching were then elucidated by comparing the branched PEG precipitants to linear versions of equivalent molecular weights, in terms of IgG recovery from CHO cell culture supernatant, precipitation selectivity, solubility of different purified proteins, and precipitation kinetics. Two distinct effects were observed: PEG branching reduced dynamic viscosity; secondly, the branched PEGs precipitated less proteins and did so more slowly. Precipitation selectivity was largely unaffected. When the branched PEGs were used at concentrations higher than their linear counterparts to give similar precipitation yields, the dynamic viscosity of the branched PEGs were noticeably lower. Interestingly, the precipitation outcome was found to be a strong function of PEG hydrodynamic radius, regardless of PEG shape and molecular weight. These observations are consistent with steric mechanisms such as volume exclusion and attractive depletion.     

Photocurable biodegradable liquid copolymers: synthesis of acrylate-end-capped trimethylene carbonate-based prepolymers, photocuring, and hydrolysis

Various photocurable liquid biodegradable trimethylene carbonate (TMC)-based (co)oligomers were prepared by ring-opening (co)polymerization of TMC with or without L-lactide (LL) using low molecular weight poly(ethylene glycol) (PEG) (mol wt 200, 600, or 1000) or trimethylolpropane (TMP) as an initiator. Resultant (co)oligomers were pastes, viscous liquids, or liquids at room temperature, depending on the monomer composition and monomer/initiator ratio. Liquid (co)oligomers were subsequently end-capped with acrylate groups. Upon visible-light irradiation in the presence of camphorquinone as a radical generator, rapid liquid-to-solid transformation occurred to produce photocured solid. The photocuring yield increased with photoirradiation time, photointensity, and camphorquinone concentration. The photocured polymers derived from low molecular weight PEG (PEG200) and TMP exhibited much reduced hydrolysis potential compared with PEG1000-derived polymers in terms of weight loss, water uptake, and swelling depth. Force-distance curve measurements by nanoindentation using atomic force microscopy clearly showed that Young's moduli of the photocured polymer films decreased with increasing hydrolysis time. Their potential biomedical applications are discussed.     

Use of polyethylene glycol in isolation and assay of stable, enzymically active starch granules from developing wheat endosperms

A procedure using polyethylene glycol (PEG), molecular weight 1000, was developed for the isolation of starch granules from wheat endosperm. Immature endosperm tissue was cut repeatedly in 300 millimolar PEG 1000 and filtered through Miracloth. Centrifugation separated a pellet from a supernatant with inhibitory activity. The pellet contained several enzyme activities, including soluble and bound components of starch synthase, starch phosphorylase, and sucrose synthase activities. The starch phosphorylase activity was unaffected by several washings with 300 millimolar PEG 1000 but was lost when the granules were washed once without PEG or washed with sucrose, glycerol, or sorbitol (up to 30%, w/v). The fraction of starch synthase, remaining on the granules after a wash without PEG (the `bound' activity) was not affected by the addition of 30% sorbitol to the wash buffer. This fraction became larger with grain development (0.2-0.7).

To obtain high activity, PEG was required not only during isolation of granules but also in the assay of both starch phosphorylase and starch synthase giving optimum activity at 225 to 255 millimolar. PEG reduced the requirement for glycogen as primer with soluble starch synthase. However, the `bound' starch synthase activity was unaffected by PEG. PEG of different size were compared by their effects in the assay of starch granules: with increase in molecular size, the same effect was obtained at ever lower polymer concentration (w/v) down to a limit.

Treatment of granules with Triton X-100 did not affect their starch synthase activity, but it removed the capacity to incorporate label from UDP [¹⁴C]G into non-starch polymers.

It is concluded that PEG, like some other active compounds (ethanol Na₃-citrate, and Ficoll) could mediate enzyme-primer interaction by exclusion.

     

PEG blocking of single pores arising on phase transitions in unmodified lipid bilayers

Changes in ionic permeability of bilayer lipid membranes (BLM) from dipalmitoyl phosphatidylcholine at temperature of phase transition in 1 M LiCl solution in the presence of polyethyleneglycols (PEG) of various molecular masses are studied. The transition of ionic membrane channels from conducting to blocked nonconducting state using polymers makes it possible to calibrate lipid pores. It is shown that low-molecular weight glycerol and PEG with molecular weights of 300 and 600 decrease the amplitude of current fluctuations through the membrane, the decrease being proportional to the size of the polymer molecule incorporated. The addition of PEG with molecular masses of 1450, 2000, and 3350 decrease the current fluctuations to the basal noise level. The result is considered as a complete blockade of ion channel conductivity. In the presence of rather large polymers, such as PEG with molecular masses of 6000 and 20000, which are hardly incorporated in the pore, single current fluctuations occur again; however, their amplitudes are somewhat smaller than in the absence of PEG. It is assumed that a complete blockade of the conductivity of lipid ionic channels by PEG with molecular masses of 1450, 2000, and 3350 is due to dehydration of the pore gap and the conversion of the hydrophilic pore to a hydrophobic one.     

Incorporation of polyethylene glycol in polyhydroxyalkanoic acids accumulated by Azotobacter chroococcum MAL-201

Azotobacter chroococcum MAL-201 (MTCC 3853), a free-living nitrogen-fixing bacterium accumulates poly(3-hydroxybutyric acid) [PHB, 69% of cell dry weight (CDW)] when grown on glucose and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) [PHBV with 19.2 mol% 3HV] when grown on glucose and valerate. Use of ethylene glycol (EG) and/or polyethylene glycols (PEGs) of low molecular weight as sole carbon source were detrimental to A. chroococcum growth and polymer yields. PEG-200, however, in the presence of glucose was incorporated into the polyhydroxyalkanoate (PHA) polymer. Addition of PEG-200 (150 mM) to culture medium during mid-log phase growth favored increased incorporation of EG units (12.48 mol%) into the PHB polymer. In two-step culture experiments, where valerate and PEG simultaneously were used in fresh medium, EG was incorporated most effectively in the absence of glucose, leading to the formation of a copolymer containing 18.05 mol% 3HV and 14.78 mol% EG. The physico-mechanical properties of PEG-containing copolymer (PHBV–PEG) were compared with those of the PHB homopolymer and the PHBV copolymer. The PHBV–PEG copolymer appeared to have less crystallinity and greater flexibility than the short-chain-length (SCL) PHA polymers.     

Prolonged circulation time in vivo of large unilamellar liposomes composed of distearoyl phosphatidylcholine and cholesterol containing amphipathic poly(ethylene glycol).

The effect of poly(ethylene glycol) (PEG) on the circulation time of liposomes in mice was examined by employing amphipathic PEGs (phosphatidylethanolamine (PE) derivatives of PEG) with average molecular weights of 1000, 2000, 5000 and 12,000. The activity of dioleoyl phosphatidylethanolamine-PEG (DOPE-PEG) in prolonging the circulation time of egg phosphatidylcholine/cholesterol large unilamellar liposomes (ePC/CH LUVs) (200 nm) was proportional to the molecular weight of PEG, i.e., 12000 = 5000 greater than 2000 greater than 1000. On the other hand, inclusion of distearoylphosphatidylethanolamine-PEG (DSPE-PEG) or dipalmitoyl-phosphatidylethanolamine-PEG (DPPE-PEG) of low molecular weight such as 1000 and 2000 in distearoylphosphatidylcholine (DSPC)/CH LUVs or dipalmitoyl phosphatidylcholine (DPPC)/CH LUVs effectively increased their blood circulation time. At least 3 mol% of amphipathic PEG in liposomes was required for activity. Addition of CH, which has a bilayer-tightening effect, to DSPC/CH/DSPE-PEG2000 LUVs further increased the blood residence time. A size of less than 300 nm was essential for prolonging the residence time of amphipathic PEG-containing liposomes in blood. DSPC/CH/DSPE-PEG2000 LUVs (1:1:0.13, m/m) containing 6 mol% of PEG and 200 nm in diameter remained in the circulation for over 24 h after injection and may be clinically useful for sustained release of an entrapped drug in the bloodstream and for drug accumulation in solid tumors.     

Acid-sensitive polyethylene glycol conjugates of doxorubicin: preparation, in vitro efficacy and intracellular distribution

Coupling anticancer drugs to synthetic polymers is a promising approach of enhancing the antitumor efficacy and reducing the side-effects of these agents. Doxorubicin maleimide derivatives containing an amide or acid-sensitive hydrazone linker were therefore coupled to alpha-methoxy-poly(ethylene glycol)-thiopropionic acid amide (MW 20000 Da), alpha,omega-bis-thiopropionic acid amide poly(ethylene glycol) (MW 20000 Da) or alpha-tert-butoxy-poly(ethylene glycol)-thiopropionic acid amide (MW 70000 Da) and the resulting polyethylene glycol (PEG) conjugates isolated through size-exclusion chromatography. The polymer drug derivatives were designed as to release doxorubicin inside the tumor cell by acid-cleavage of the hydrazone bond after uptake of the conjugate by endocytosis. The acid-sensitive PEG conjugates containing the carboxylic hydrazone bonds exhibited in vitro activity against human BXF T24 bladder carcinoma and LXFL 529L lung cancer cells with IC70 values in the range 0.02-1.5 microm (cell culture assay: propidium iodide fluorescence or colony forming assay). In contrast, PEG doxorubicin conjugates containing an amide bond between the drug and the polymer showed no in vitro activity. Fluorescence microscopy studies in LXFL 529 lung cancer cells revealed that free doxorubicin accumulates in the cell nucleus whereas doxorubicin of the acid-sensitive PEG doxorubicin conjugates is primarily localized in the cytoplasm. Nevertheless, the acid-sensitive PEG doxorubicin conjugates retain their ability to bind to calf thymus DNA as shown by fluorescence and visible spectroscopy studies. Results regarding the effect of an acid-sensitive PEG conjugate of molecular weight 20000 in the chorioallantoic membrane (CAM) assay indicate that this conjugate is significantly less embryotoxic than free doxorubicin although antiangiogenic effects were not observed.     

Peptide-polymer biotherapeutic synthesis on novel cross-linked beads with "spatially tunable" and "isolated" functional sites

Solid phase synthesis of polymer biotherapeutics using conventional polymers suffers from many limitations such as low synthetic yield and purity. The conventional polymers prepared by either pre- or post-functionalization strategies have no control over the point of functionalization. Hence we report a novel cross-linked polymer in which the functional groups are spatially tuned to predefined distance with optimal site isolation. This has been achieved by the design and synthesis of a tetra functional PEG, 3,3'-(PEG)bis(1-(4-vinylphenoxy)propan-2-ol) (bis(VPP)PEG). It has been incorporated at cross-linking of 1-12%, into a polystyrene network by free radical suspension polymerization. In this polymer, the distance between hydroxyl functional groups has been spatially tuned in a predefined manner by varying the length of the cross-linker backbone from ethylene glycol to PEG1000 Da and the loading capacity could be varied from 0.1 to 0.9 mmol/g. The polymer has been characterized by SEM, FTIR, and 13C NMR. The polymer exhibits excellent swelling behavior and high chemical stability. The synthetic efficiency of the polymer was demonstrated by the successful synthesis of three structural classes of PEGylated antimicrobial peptide biotherapeutics and the difficult ACP (65-74) fragment. Thus the "spatially defined" and "site isolated" synthesis within the new polymer offers a novel strategy for synthesis of difficult peptide-polymer bioconjugates. The bioassay studies shows that PEGylation of AMPs significantly reduces their hemolytic potential but the retainment of antibacterial property was dependent both on the peptide sequence and the size of PEG used.     

Influence of PEG endgroup and molecular weight on its reactivity for lipase-catalyzed polyester synthesis

Polycondensations were performed at 70 degrees C in bulk using physically immobilized lipase B from Candida antarctica (CAL-B) as catalyst. Study of copolymerizations between sebacic acid and PEG diols of differing Mn values (200, 400, 600, 1000, 2000, and 10 000) showed that PEG 400 and 600 were most reactive (DP(avg) up to about 6). Increasing the PEG diol chain length from 600 to 1000, 2000, and 10 000 resulted in large decreases in copolymer DP(avg) values. PEG200 diacids (i.e., HOOC-(CH2)x-O-(CH2CH2O)n-(CH2)x-COOH) were successfully synthesized where x was 1, 4, 5, 7, 9, and 11. Study of copolymerizations of these diacids with 1,8-octanediol showed that, by introduction of a five-carbon methylene spacer (x = 5), remarkable increases in the reactivity of PEG200 diacids were achieved. In addition, introduction of this spacer was also effective for increasing the reactivity of PEG diacids of higher molecular weight (i.e., PEG400, 600, and 1000). This work verified the hypothesis that, by conversion of PEG chain ends to structures more closely resembling fatty acids, modified PEG building blocks are obtained that are better recognized as substrates by CAL-B during condensation reactions.     

Isolation of plasmid DNA from cell lysates by aqueous two-phase systems

This work presents a study of the partitioning of a plasmid vector containing the cystic fibrosis gene in polyethylene glycol (PEG)/salt (K2HPO4) aqueous two-phase systems (ATPS). The plasmid was extracted from neutralized alkaline lysates using PEG with molecular weights varying from 200 to 8000. The effects of the lysate mass loaded to the ATPS (20, 40, and 60% w/w) and of the plasmid concentration in the lysate were evaluated. The performance of the process was determined by qualitative and quantitative assays, carefully established to overcome the strong interference of impurities (protein, genomic DNA, RNA), salt, and PEG. Plasmid DNA partitioned to the top phase when PEG molecular weight was lower than 400. The bottom phase was preferred when higher PEG molecular weights were used. Aqueous two-phase systems with PEG 300, 600, and 1000 were chosen for further studies on the basis of plasmid and RNA agarose gel analysis and protein quantitation. The recovery yields were found to be proportional to the plasmid concentration in the lysate. The best yields (>67%) were obtained with PEG 1000. These systems (with 40 and 60% w/w of lysate load) were able to separate the plasmid from proteins and genomic DNA, but copartitioning of RNA with the plasmid was observed. Aqueous two-phase systems with PEG 300 concentrated both plasmid and proteins in the top phase. The best system for plasmid purification used PEG 600 with a 40% (w/w) lysate load. In this system, RNA was found mostly in the interphase, proteins were not detected in the plasmid bottom phase and genomic DNA was reduced 7.5-fold.     

PEG molecular weight and lateral diffusion of PEG-ylated lipids in magnetically aligned bicelles

Lateral diffusion coefficients of PEG-ylated lipids with three different molecular weight PEG groups (1000, 2000 and 5000) were measured in magnetically-aligned bicelles using the stimulated echo (STE) pulsed field gradient (PEG) (1)H nuclear magnetic resonance (NMR) method. At concentrations below the PEG "mushroom-to-brush" transition, all three PEG-ylated lipids exhibited unrestricted lateral diffusion, with lateral diffusion coefficients comparable to those of corresponding non-PEG-ylated lipids and independent of PEG molecular weight. At concentrations above this transition, lateral diffusion slowed progressively with increasing concentration of PEG-ylated lipid as a result of surface crowding. As well, the lateral diffusion coefficients exhibited a pronounced decrease with increasing PEG group molecular weight and a diffusion-time dependence indicative of obstructed diffusion. We conclude that, while lateral diffusion of PEG-ylated lipids within lipid bilayers is determined primarily by the hydrophobic anchoring group, when crowding at the lipid bilayer surface becomes significant, the size of the extra-membranous domain, in this case the PEG group, can influence lateral diffusion, leading to decreased diffusivity with increasing size and producing obstructed diffusion at high crowding. These findings imply that similar considerations will pertain to lateral diffusion of membrane proteins with large extra-membranous domains.     

Polyethylene glycol enhanced refolding of bovine carbonic anhydrase B. Reaction stoichiometry and refolding model.

Polyethylene glycol (PEG) inhibited aggregation during refolding of bovine carbonic anhydrase B (CAB) through the formation of a nonassociating PEG-intermediate complex. Stoichiometric concentrations of PEG were required for complete recovery of active protein during refolding at aggregating conditions. For example, a PEG (Mr = 3350) to CAB molar ratio ([PEG]/[CAB]) of 2 was sufficient to inhibit aggregation during refolding at 1.0 mg/ml (33.3 microM) protein and 0.5 M guanidine hydrochloride. In addition, the PEG concentration required for enhancement was dependent upon the molecular weight and only molecular weights between 1000 and 8000 were effective in inhibiting aggregation. In the presence of PEG, the rate of refolding was the same as that observed for refolding without the formation of associated species. Refolding in the presence of PEG resulted in the rapid formation of a PEG complex with the molten globule first intermediate, and this PEG-intermediate complex did not aggregate. The CAB refolding kinetics in the presence of PEG were determined and used to develop a model of the PEG enhanced refolding pathway. The mathematical model was validated by independent activity measurements of CAB refolding. This model predicted that PEG enhanced refolding of CAB occurred by a specific interaction of PEG with the molten globule first intermediate to form a nonassociating complex which continued to fold at the same rate as the first intermediate. The predicted pathway and binding properties of PEG indicate that PEG enhanced refolding may be analogous to chaperonin mediated protein folding.