Polyethyleneglycol methacrylate 200 as an electrophoresis matrix in hydroorganic solvents

Power and limitations of electrophoretic separations in proteomics strategies

Proteomics can be defined as the large-scale analysis of proteins. Due to the complexity of biological systems, it is required to concatenate various separation techniques prior to mass spectrometry. These techniques, dealing with proteins or peptides, can rely on chromatography or electrophoresis. In this review, the electrophoretic techniques are under scrutiny. Their principles are recalled, and their applications for peptide and protein separations are presented and critically discussed. In addition, the features that are specific to gel electrophoresis and that interplay with mass spectrometry (i.e., protein detection after electrophoresis, and the process leading from a gel piece to a solution of peptides) are also discussed.

Polymer Monoliths with Low Hydrophobicity for Strong Cation-Exchange Capillary Liquid Chromatography of Peptides and Proteins

Two polymer monoliths were designed and synthesized from commercially available monomers with an attempt to decrease hydrophobicity for strong cation-exchange chromatography. One was prepared from the copolymerization of sulfoethyl methacrylate and poly(ethylene glycol) diacrylate, and the other was synthesized from vinylsulfonic acid and poly(ethylene glycol) diacrylate. Both of the monoliths were synthesized inside 75-microm i.d., UV-transparent fused-silica capillaries by photopolymerization. The hydrophobicities of the two monoliths were systematically evaluated using standard synthetic undecapeptides under ion-exchange conditions and propyl paraben under reversed-phase conditions. The poly(sulfoethyl methacrylate) monolith demonstrated similar hydrophobicity as a monolith prepared from copolymerization of 2-acrylamido-2-methyl-1-propanesulfonic acid and poly(ethylene glycol) diacrylate, and 40% acetonitrile was required to suppress any hydrophobic interactions with peptides under ion-exchange conditions. However, with the use of vinylsulfonic acid as the functional monomer, a monolith with very low hydrophobicity was obtained, making it suitable for strong cation-exchange liquid chromatography of both peptides and proteins. It was found that monolith hydrophobicity could be adjusted by selection of monomers that differ in hydrocarbon content and type of vinyl group. Finally, excellent separations of model protein standards and high-density lipoproteins were achieved using the poly(vinylsulfonic acid) monolith. Five subclasses of high-density lipoproteins were resolved using a simple linear NaCl gradient.

Preparation and evaluation of poly(polyethylene glycol methyl ether acrylate-co-polyethylene glycol diacrylate) monolith for protein analysis

A poly(polyethylene glycol methyl ether acrylate-co-polyethylene glycol diacrylate) monolith was prepared by UV-initiated polymerization. Methanol and ethyl ether were selected as porogens from a variety of organic solvents to achieve the desirable characteristics of the monolith. The preparation of the monolith could be achieved within 10 min. The monolith was macroscopically homogeneous, had low flow resistance, and did not swell or shrink significantly in tetrahydrofuran. Inverse size-exclusion data indicate that the monolith had a total porosity of 75.4% and an internal porosity of 9.1%. The monolith could be used for size-exclusion separation of peptides, although it could not separate proteins with molecular masses between 10 and 100 K due to its unique pore size distribution. It was found to resist adsorption of proteins in capillary liquid chromatography when using 100 mM phosphate buffer (pH 7.0) containing 0.5 M NaCl. Complete recovery of both acidic and basic proteins was achieved. The monolith can be used for applications in which inert materials are required for protein analysis.

Hydrogels as potential probes for investigating the mechanism of lenticular presbyopia

PURPOSE

To synthesize and characterize hydrogels with viscoelastic properties comparable to those of the natural lens.

METHODS

Hydrogels were synthesized in water by free-radical polymerization of the monomer poly(ethyleneglycol)-monomethacrylate. Three different molecular weights of poly(ethyleneglycol)-dimethacrylates were used as crosslinkers. For each crosslinker used, five different monomer-to-crosslinker weight ratios were utilized while the total mass of the reactants was kept constant. In another series, the concentration of the reactants was varied while the weight ratio of monomer to crosslinker was kept constant at 95 : 5. The percent optical transmission, equilibrium water content, moduli (elastic, shear, storage, and loss), and retardation time constant of the hydrogels were determined. In addition, endocapsular polymerization was performed in the capsular bag of porcine eyes.

RESULTS

The hydrogels examined exhibited the following ranges for viscoelastic properties: elastic modulus, 1.33-2.37 x 10(4) Pa; shear modulus, 3.35-6.72 x 10(3) Pa; storage modulus, 1.65-6.24 x 10(4) Pa. For any given hydrogel, raising its crosslinker's weight ratio increased its moduli and decreased its equilibrium water content and optical transmission. For any given monomer-to-crosslinker weight ratio, increasing the molecular weight of the crosslinker reversed these trends. Reactant concentrations increased the elastic modulus and decreased the equilibrium water content. The hydrogels formed ex vivo (in the evacuated capsular bag of porcine eyes) allowed for the clear and undistorted viewing of objects.

CONCLUSIONS

Hydrogels that exhibit physical and mechanical properties comparable to those of the natural lens were successfully identified, synthesized, and characterized, and the feasibility of endocapsular polymerization was demonstrated.

Two-dimensional electrophoresis of membrane proteins using immobilized pH gradients

Two-dimensional electrophoresis (2-DE) is a highly resolving technique for arraying proteins by isoelectric point and molecular mass. To date, the resolving ability of 2-DE for protein separation is unsurpassed, thus ensuring its use as the fundamental separation method for proteomics. When immobilized pH gradients (IPGs) are used for isoelectric focusing in the first dimension, excellent reproducibility and high protein load capacity can be achieved. While this has been beneficial for separations of soluble and mildly hydrophobic proteins, separations of membrane proteins and other hydrophobic proteins with IPGs have often been poor. Stimulated by the growing interest in proteomics, recent developments in 2-DE methodology have been aimed at rectifying this situation. Improvements have been made in the area of protein solubilization and sample fractionation, leading to a revamp of traditional approaches for 2-DE of membrane proteins. This review explores these developments.

Cross-linked poly(N-acetylethylenimine) as an isoelectric focusing matrix

Agarose and polyacrylamide are the gels used for most analytical and micropreparative electrophoresis of biopolymers. In an alternative approach that offers different physico-chemical properties from these standard gels, nonionic hydrogels and amphigels composed of poly(N-acetylethylenimine) (PAEI) and a variety of cross-linkers were prepared and used as anticonvective matrices for isoelectric focusing. PAEI was prepared from the ring opening, ionic polymerization of 2-methyl-2-oxazoline. The N-acetyl side chains were hydrolyzed with aqueous sodium hydroxide to produce secondary amine sites which were used for the attachment of cross-linkers. Several cross-linkers were tested for their suitability for electrophoresis, and the cross-linker system based on the Diels-Alder reaction between a furan and maleimide tethered to PAEI gave a moldable gel that can be reversibly converted to a sol at 80 degrees C. This gel was used for isoelectric focusing under both denaturing and nondenaturing conditions. Several protein standards were resolved as well as was achieved with polyacrylamide.

Electrophoresis gel media: the state of the art

Some unique events have occurred in the last few years which might revolutionize the field of polyacrylamide gel electrophoresis. While it was widely recognized that such matrices could normally be cast with a small pore size distribution, typically of the order of a few nanometers diameter (for protein sieving), recent developments suggest that "macroporous" gels could also be produced in the domain of polyacrylamides. If constraints to chain motion are imposed during gel polymerization, large-pore structures can be grown. Such constraints can originate either from low temperatures or from the presence of preformed polymers in the gelling solution; in both cases, the growing chains are forced to "laterally aggregate" via inter-chain hydrogen bond formation. Upon consumption of pendant double bonds, such bundles are frozen in the three-dimensional space by permanent cross-links. As an additional development, a novel photopolymerization system is described, comprising a cationic dye (methylene blue) and a redox couple (sodium toluene sulfinate, a reducer, and diphenyliodonium chloride, a mild oxidizer). Methylene blue catalysis is characterized by a unique efficiency, ensuring >96% conversion of monomers, even in hydro-organic solvents and in the presence of surfactants, which normally quench or completely inhibit the persulphate-driven reaction. In addition, methylene blue-sustained photopolymerization can be operated in the entire pH 3-10 interval, where most other systems fail. Perhaps the most striking novelty in the field is the appearance of a novel monomer (N-acryloylaminopropanol, AAP) coupling a high hydrophilicity with a unique resistance to alkaline hydrolysis. Given the fact that a poly(AAP) matrix is 500 times more stable than a poly(acrylamide) gel, while being twice as hydrophilic, it is anticipated that this novel chemistry will have no difficulties in replacing the old electrophoretic anticonvective media. The review ends with a glimpse at novel sieving media in capillary zone electrophoresis: polymer networks. Such media, by providing an almost infinite range of pore sizes, due to the absence of a rigid support, allow sieving mechanisms to be operative over a wide interval of particle sizes, even up to genomic DNA. Viscous solutions of polymer networks, made with the novel poly(AAP) chemistry, allow repeated use of the same separation column, well above 50 injections. Silica-bound poly(AAP) chains provide effective quenching of electroosmosis and >200 analyses by isoelectric focusing.

Novel acrylamido monomers with higher hydrophilicity and improved hydrolytic stability: I. Synthetic route and product characterization

The novel acrylamido monomer reported by our group (N-acryloylaminoethoxyethanol, AAEE; Chiari et al., Electrophoresis 1994, 15, 177-186), found to combine high hydrophilicity with extraordinary resistance to alkaline hydrolysis, has come under closer scrutiny due to unexpected and random autopolymerization while stored as a 1/1 v/v water solution at 4 degrees C (possibly due to a greater oxidability of the ether group). We have additionally found a unique degradation pathway of the monomer, called "1-6 H-transfer", by which the C1 (on the double bond site), by constantly ramming against the C6, next to the ether oxygen (O7, which in fact favors the transfer of the hydrogen atom by C1), produces radicals which more efficiently add to the monomer favoring autopolymerization and cross-linking. A number of novel monomers is proposed while maintaining the other unique characteristics of AAEE. One of them, N-acryloylaminopropanol, offers all the unique, special qualities of AAEE, without the noxious aspects of autopolymerization. Additionally, a synthetic route was optimized, yielding an essentially pure product in a single reaction step, with a yield > 99% and an equivalent purity (> 99%). The synthesis consists in reacting acryloyl chloride at -40 degrees C in presence of a twofold molar excess of aminopropanol and in ethanol (instead of methanol) as solvent. Other solvents, as well as the use of triethylamine for neutralizing the HCl produced, were found to give a variety of undesired byproducts.

Sponge-like electrophoresis media: mechanically strong materials compatible with organic solvents, polymer solutions and two-dimensional electrophoresis

A new range of sponge-like media, called "electrophoresis sponges", is presented. They differ from electrophoresis gels primarily in that they are mechanically stronger, providing a permanent structure of directly measurable pore size dimensions. The new media are similar to capillary electrophoresis in terms of pore size range, they are mechanically strong with directly definable walls, and are compatible with polymer solutions. The sponges differ from capillary electrophoresis in that they provide large numbers of channels, with a corresponding high load capacity for simultaneous runs in multiple channels and they are compatible directly with multi-dimensional separations, such as high resolution two-dimensional electrophoresis. Furthermore, they can be molded (or cut) to any shape and retain that shape, they can be handled more easily than gels, they can be reused if necessary, they can be distributed in the same format between labs easily, and they can be stored indefinitely. Chemically, they can be hydrophilic or hydrophobic, with capability ranging from inert to reactive surfaces. Pore sizes can range from the sub-nanometer to 100 micron scale. Results with various hydrophobic sponges are reported for the carrier ampholyte-based isoelectric focusing of proteins. Broad and narrow pH gradients are established in the sponges that are more linear than those achieved with polyacrylamide gels. One- and two-dimensional electrophoresis of proteins has been achieved, for example with high resolution of the charge isomers of the haptoglobin beta chain, using sponge-based isoelectric focusing. Isoelectric focusing is about threefold faster in the tested sponges than in equivalent polyacrylamide gels. This improved speed is probably related to the larger sponge pores.(ABSTRACT TRUNCATED AT 250 WORDS)

Poly(ethylene glycol)methacrylate-acrylamide copolymer media for hydrophobic protein and low temperature electrophoresis

The properties of poly(ethylene glycol)methacrylate-acrylamide copolymer media (PEGMACs) were exploited in two ways: (i) in the first-dimensional gel of two-dimensional electrophoresis (2-DE) of hydrophobic proteins and (ii) for high speed, high-resolution electrophoresis at low temperatures. In the first application, improved resolution and yield of isoelectric focusing (IEF) separations for the hydrophobic protein zein was achieved compared to IEF in standard polyacrylamide gels. This appears promising as a candidate approach for higher resolution 2-DE mapping of uncharacterized hydrophobic proteins. In the second application, PEGMACs compatible with hydroorganic antifreeze buffer systems below cooling of the gels to low temperatures (-20 degrees C), which allowed greater current to be tolerated during electrophoresis. PEGMAC gels enabled us to perform sixfold faster electrophoretic separations and achieve threefold improved resolution of six standard proteins at the lower temperatures in a direct comparison with the normal sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) system. If this approach is coupled with more precise instrumentation to control low temperatures during electrophoresis, greater separation speeds and resolution may be anticipated.

Protein electrophoresis

Many significant advances have occurred recently in the field of protein electrophoresis and related technologies. Improvements have been made in capillary electrophoresis in apparatus design, detection, and capillary modification with coatings and fillers. The transfer of proteins to a blot, the capacity to analyze and detect proteins on it, and the ability to remove proteins from a blot, are also areas where important work has been done. Finally, gel electrophoresis has benefitted from new hardware, detergent and stain protocols, and matrices.

Polyhydroxy and polyethyleneglycol (meth)acrylate polymers: physical properties and general studies for their use as electrophoresis matrices

A new series of materials have been tested for their suitability as electrophoresis matrices. The mechanical and optical properties of gels composed of polyethyleneglycol (meth)acrylate esters or polyhydroxy (meth)acrylate esters in water and in various concentrations of organic solvents are described. Several crosslinkers including polyethyleneglycol and polyhydroxy di(meth)acrylates, piperazine diacrylate, and bisacrylamide were used in these studies. Electrophoretic migration and separation of a series of protein standards through polyethyleneglycol methacrylate (PEGM) 200, PEGM 400, and glyceryl methacrylate is demonstrated. Further, copolymerization of all of the monomers with acrylamide was performed and the distribution of monomer incorporation into the polymer network calculated. All monomers and copolymers that were examined by IR spectroscopy showed greater than 99% polymerization. These results justify their further study for biomolecule separations.