Todd M. Przybycien

Protein unfolding at interfaces: Slow dynamics of α-helix to β-sheet transition

A two‐phase sequential dynamic change in the secondary structure of hen egg lysozyme (Lys) adsorbed on solid substrates was observed. The first phase involved fast conversion of α‐helix to random/turns (within the first minute or at very low coverage or high substrate wettability) with no perceptible change in β‐sheet content. The second phase (1–1200 min), however, involved a relatively slow conversion from α‐helix to β‐sheet without a noticeable change in random/turns. An important finding of this work is that the concentration of lysozyme in the adsorbed state has a substantial effect on the fractional content of secondary structures. Attenuated total reflection Fourier transform infrared (ATR/FTIR) spectroscopy, along with a newly‐developed optimization algorithm for predicting the content of secondary structure motifs, was used to correlate the secondary structure and the amount of adsorbed lysozyme with the surface wettability of six different flat nanoporous substrates. Although three independent variables, surface wettability, solution concentration and time for adsorption, were used to follow the fractional structural changes of lysozyme, the results were all normalized onto a single plot with the amount adsorbed as the universal independent variable. Consequently, lateral interactions among proteins likely drive the transition process. Direct intermolecular force adhesion measurements between lysozyme and different functionalized self‐assembled alkanethiol monolayers confirm that hydrophobic surfaces interact strongly with proteins. The lysozyme‐unfolding pathway during early adsorption appears to be similar to that predicted by published molecular modeling results. Proteins 2004.

Critical factors for high-performance physically adsorbed (dynamic) polymeric wall coatings for capillary electrophoresis of DNA

Physically adsorbed (dynamic) polymeric wall coatings for microchannel electrophoresis have distinct advantages over covalently linked coatings. In order to determine the critical factors that control the formation of dynamic wall coatings, we have created a set of model polymers and copolymers based on N,N‐dimethylacrylamide (DMA) and N,N‐diethylacrylamide (DEA), and studied their adsorption behavior from aqueous solution as well as their performance for microchannel electrophoresis of DNA. This study is revealing in terms of the polymer properties that help create an “ideal” wall coating. Our measurements indicate that the chemical nature of the coating polymer strongly impacts its electroosmotic flow (EOF) suppression capabilities. Additionally, we find that a critical polymer chain length is required for polymers of this type to perform effectively as microchannel wall coatings. The effective mobilities of double‐stranded (dsDNA) fragments within dynamically coated capillaries were determined in order to correlate polymer hydrophobicity with separation performance. Even for dsDNA, which is not expected to be a strongly adsorbing analyte, wall coating hydrophobicity has a deleterious influence on separation performance.

Development of a novel gene delivery scaffold utilizing colloidal gold–polyethylenimine conjugates for DNA condensation

We have developed a novel gene delivery scaffold based on DNA plasmid condensation with colloidal gold/polyethylenimine conjugates. This scaffold system was designed to enable systematic study of the relationships between DNA complex physical properties and transfection efficiency. Using an enhanced green fluorescent protein-coding reporter plasmid and a Chinese hamster ovary cell line, we have measured the transfection efficiencies of our complexes using flow cytometry and their cytotoxicities using the trypan blue assay. We have also assayed complex particle morphologies using atomic force microscopy, photon correlation spectroscopy, and a novel plasmon absorbance peak position analysis. We achieved comparable rates of transfection relative to the commonly used polycationic condensation agents calcium phosphate and LipofectAMINE™, with comparably low cytotoxicities. In addition, by manipulating colloidal gold concentration, we could partially decouple complex physical properties including charge ratio, size, DNA loading, and polyethylenimine concentration. Our morphological analyses showed that complexes with a diameter of a few hundred nanometers and a charge ratio of ∼8 perform best in our transfection efficiency assays. The use of colloidal gold as a component in our delivery system provides a versatile system for manipulating complex properties and morphology as well as a convenient scaffold for planned ligand conjugation studies.

Self-interaction chromatography: a tool for the study of protein-protein interactions in bioprocessing environments.

We describe a new protein characterization technique called self-interaction chromatography (SIC), which exploits the specificity of protein-protein interactions that is common to protein aggregates and enables the rapid screening of protein formulation additives as physical stabilizers against aggregation. This technique also enables the identification of specific interaction sites and the determination of their relative importance for self-association. Mannitol, glycine, and dextran 40 were tested for their stabilizing effect toward the model protein lysozyme. Dextran 40 exhibited a poor stabilizing effect. While mannitol stabilized both the native and acid-denatured forms of lysozyme, glycine stabilized the native form with respect to the denatured species. These results are in good agreement with findings in the formulation literature. The SIC shows tremendous potential as a rapid formulation development tool. We also screened two putative interaction sites for involvement in the self-association of lysozyme and estimated the associated binding energies using a binding isotherm model that we developed. The sites screened consisted of residues 41-48 and 125-128 and were selected based on their apparent importance in forming crystal contacts in several different crystal forms of lysozyme. Of the two sites, only residues 125-128 were found to influence self-association under the conditions we employed. Because the success of this technique depends on the exploitation of self-interactions between native species, several important applications are also suggested such as separating native from misfolded or variant species and probing site utilization in aggregation versus crystallization phenomena.

Simulations of reversible protein aggregate and crystal structure

We simulated the structure of reversible protein aggregates as a function of protein surface characteristics, protein-protein interaction energies, and the entropic penalty accompanying the immobilization of protein in a solid phase. These simulations represent an extension of our previous work on kinetically irreversible protein aggregate structure and are based on an explicit accounting of the specific protein-protein interactions that occur within reversible aggregates and crystals. We considered protein monomers with a mixture of hydrophobic and hydrophilic surface regions suspended in a polar solvent; the energetic driving force for aggregation is provided by the burial of solvent-exposed hydrophobic surface area. We analyzed the physical properties of the generated aggregates, including density, protein-protein contact distributions, solvent accessible surface area, porosity, and order, and compared our results with the protein crystallization literature as well as with the kinetically irreversible case. The physical properties of reversible aggregates were consonant with those observed for the irreversible aggregates, although in general, reversible aggregates were more stable energetically and were more crystal-like in their order content than their irreversible counterparts. The reversible aggregates were less dense than the irreversible aggregates, indicating that the increased energetic stability is derived primarily from the optimality rather than the density of the packing in the solid phase. The extent of hydrophobic protein-protein contacts and solvent-exposed surface area within the aggregate phase depended on the aggregation pathway: reversible aggregates tended to have a greater proportion of hydrophobic-hydrophobic contacts and a smaller fraction of hydrophobic solvent-exposed surface area. Furthermore, the arrangement of hydrophobic patches on the protein surface played a major role in the distribution of protein contacts and solvent content. This was readily reflected in the order of the aggregates: the greater the contiguity of the hydrophobic patches on the monomer surface, the less ordered the aggregates became, despite the opportunities for rearrangement offered by a reversible pathway. These simulations have enhanced our understanding of the impact of protein structural motifs on aggregate properties and on the demarcation between aggregation and crystallization.

Poly(ethylene glycol)-Modified Proteins: Implications for Poly(lactide-co-glycolide)-Based Microsphere Delivery

The reduced injection frequency and more nearly constant serum concentrations afforded by sustained release devices have been exploited for the chronic delivery of several therapeutic peptides via poly(lactide-co-glycolide) (PLG) microspheres. The clinical success of these formulations has motivated the exploration of similar depot systems for chronic protein delivery; however, this application has not been fully realized in practice. Problems with the delivery of unmodified proteins in PLG depot systems include high initial “burst” release and irreversible adsorption of protein to the biodegradable polymer. Further, protein activity may be lost due to the damaging effects of protein-interface and protein-surface interactions that occur during both microsphere formation and release. Several techniques are discussed in this review that may improve the performance of PLG depot delivery systems for proteins. One promising approach is the covalent attachment of poly(ethylene glycol) (PEG) to the protein prior to encapsulation in the PLG microspheres. The combination of the extended circulation time of PEGylated proteins and the shielding and potential stabilizing effects of the attached PEG may lead to improved release kinetics from PLG microsphere system and more complete release of the active conjugate.

Protein purification with vapor-phase carbon dioxide.

Gaseous CO2 was used as an antisolvent to induce the fractional precipitation of alkaline phosphatase, insulin, lysozyme, ribonuclease, trypsin, and their mixtures from dimethylsulfoxide (DMSO). Compressed CO2 was added continuously and isothermally to stationary DMSO solutions (gaseous antisolvent, GAS). Dissolution of CO2 was accompanied by a pronounced, pressure-dependent volumetric expansion of DMSO and a consequent reduction in solvent strength of DMSO towards dissolved proteins. View cell experiments were conducted to determine the pressures at which various proteins precipitate from DMSO. The solubility of each protein in CO2-expanded DMSO was different, illustrating the potential to separate and purify proteins using gaseous antisolvents. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate (SDS-PAGE) was used to quantify the separation of lysozyme from ribonuclease, alkaline phosphatase from insulin, and trypsin from catalase. Lysozyme biological activity assays were also performed to determine the composition of precipitates from DMSO initially containing lysozyme and ribonuclease. SDS-PAGE characterizations suggest that the composition and purity of solid-phase precipitated from a solution containing multiple proteins may be accurately controlled through the antisolvents pressure. Insulin, lysozyme, ribonuclease, and trypsin precipitates recovered substantial amounts of biological activity upon redissolution in aqueous media. Alkaline phosphatase, however, was irreversibly denaturated. Vapor-phase antisolvents, which are easily separated and recovered from proteins and liquid solvents upon depressurization, appear to be a reliable and effective means of selectively precipitating proteins.

Protein structure perturbations on chromatographic surfaces

Amide I band Raman spectroscopy was used to quantify the secondary structure contents of proteins adsorbed on ion-exchange and reversed-phase materials. Neither ribonuclease A, a rigid protein, nor α-lactalbumin, a flexible protein, exhibited any significant secondary structural change on adsorption to an agarose-based cation-exchange support. On reversed-phase supports, however, lysozyme demonstrated a significant perturbation in secondary structure in the adsorbed state as compared to its structure in solution. For a constant concentration of adsorbed protein, the perturbed structure of adsorbed lysozyme was relatively insensitive to mobile phase conditions. However, the extent of structural change decreased as the concentration of adsorbed protein decreased. In agreement with the Raman spectroscopic characterization, reversed-phase linear gradient elution of lysozyme produced two peaks: a weakly binding peak corresponding to the native state and a strongly binding peak corresponding to the denatured state. The results presented in this paper demonstrate the utility of the Raman spectroscopic technique for in-situ characterization of protein secondary structures and their use in the molecular-level interpretation of protein retention behavior.

Structure-function relationships in the inorganic salt-induced precipitation of α-chymotrypsin

Abstract α-Chymotrypsin (αCT) was used as a model protein to study the effects of salt-induced precipitation on protein conformation. Process parameters investigated included the type and amount of salt used to induce precipitation. The salts studied included Na 2 SO 4 , NaCl, NaBr, KBr and KSCN. Precipitate secondary structure content was examined via laser Raman spectroscopy. Conventional and saturation transfer electron paramagnetic resonance spectroscopy were employed to probe the tertiary structure of the active site in spin-labelled αCT precipitates. As the molal surface tension increment of the inducing salt increased, the β-sheet content increased and the α-helix content decreased. There was no significant variation in secondary structure with the amount of salt used. The fraction of precipitate that recovered activity on redissolution was correlated with the change in secondary structure content. Spin-labelled precipitate spectra indicated that the active site remains unaltered during precipitation. Molecular modelling was employed to investigate how physical property of αCT were affected by these types of conformational change. Estimated physical property changes could not account entirely for observed deviations from current equilibrium theory for salt-induced precipitation. The spectroscopic observations were also combined with activity/solubility results to propose a mechanism for the salt-induced precipitation of globular proteins.

Secondary structure perturbations in salt-induced protein precipitates

The secondary structure implications of precipitation induced by a chaotropic salt, KSCN, and a structure stabilizing salt, Na2SO4, were studied for twelve different proteins. alpha-helix and beta-sheet content of precipitate and native structures were estimated from the analysis of amide I band Raman spectra. A statistical analysis of the estimated perturbations in the secondary structure contents indicated that the most significant event is the formation of beta-sheet structures with a concomitant loss of alpha-helix on precipitation with KSCN. The conformational changes for each protein were also analyzed with respect to elements of primary, secondary and tertiary structure existing in the native protein; primary structure was quantified by the fractions of hydrophobic and charged amino acids, secondary structure by x-ray estimates of alpha-helix and beta-sheet contents of native proteins and tertiary structure by the dipole moment and solvent-accessible surface area. For the KSCN precipitates, factors affecting beta-sheet content included the fraction of charged amino acids in the primary sequence and the surface area. Changes in alpha-helix content were influenced by the initial helical content and the dipole moment. The enhanced beta-sheet contents of precipitates observed in this work parallel protein structural changes occurring in other aggregative phenomena.