Preparation of rehydratable polyacrylamide gels and their application in ultrathin-layer isoelectric focusing

Laterally Aggregated Polyacrylamide Gels for Immunoprobed Isoelectric Focusing

Immunoprobed isoelectric focusing (IEF) resolves proteins based on differences in isoelectric point (pI) and then identifies protein targets through immunoprobing of IEF-separated proteins that have been immobilized onto a gel scaffold. During the IEF stage, the gel functions as an anti-convective medium and not as a molecular sieving matrix. During the immunoprobing stage, the gel acts as an immobilization scaffold for IEF-focused proteins via photoactive moieties. Here, we characterized the effect of gel pore size on IEF separation and in-gel immunoassay performance. We modulated polyacrylamide (PA) gel pore size via lateral chain aggregation initiated by PEG monomers. During IEF, the 2% PEG highly porous PA gel formulation offered higher resolution (minimum pI difference ∼0.07 ± 0.02) than unmodified 6%T, 3.3%C (benchmark) and 6%T, 8%C (negative control) PA gels. The highly porous gels supported a pH gradient with slope and linearity comparable to benchmark gels. The partition coefficient for antibodies into the highly porous gels (K = 0.35 ± 0.02) was greater than the benchmark (3×) and negative control (1.75×) gels. The highly porous gels also had lower immunoassay background signal than the benchmark (2×) and negative control (3×) gels. Taken together, lateral aggregation creates PA gels that are suitable for both IEF and subsequent in-gel immunoprobing by mitigating immunoprobe exclusion from the gels while facilitating removal of unbound immunoprobe.

Photopatterned free-standing polyacrylamide gels for microfluidic protein electrophoresis

Designed for compatibility with slab-gel polyacrylamide gel electrophoresis (PAGE) reagents and instruments, we detail development of free-standing polyacrylamide gel (fsPAG) microstructures supporting electrophoretic performance rivalling that of microfluidic platforms. For the protein electrophoresis study described here, fsPAGE lanes are comprised of a sample reservoir and contiguous separation gel. No enclosed microfluidic channels are employed. The fsPAG devices (120 μm tall) are directly photopatterned atop of and covalently attached to planar polymer or glass surfaces. Leveraging the fast <1 h design-prototype-test cycle - significantly faster than mold based fabrication techniques - we optimize the fsPAG architecture to minimize injection dispersion for rapid (<1 min) and short (1 mm) protein separations. The facile fabrication and prototyping of the fsPAGE provides researchers a powerful tool for developing custom analytical assays. We highlight the utility of assay customization by fabricating a polyacrylamide gel with a spatial pore-size distribution and demonstrate the resulting enhancement in separation performance over a uniform gel. Further, we up-scale from a unit separation to an array of 96 concurrent fsPAGE assays in 10 min run time driven by one electrode pair. The fsPAG array layout matches that of a 96-well plate to facilitate integration of the planar free standing gel array with multi-channel pipettes while remaining compatible with conventional slab-gel PAGE reagents, such as staining for label-free protein detection. Notably, the entire fsPAGE workflow from fabrication, to operation, and readout uses readily available materials and instruments - making this technique highly accessible.

Enzymological investigations on the causes for the PSE-syndrome, II. Comparative studies on glycogen phosphorylase from pig muscles

In order to investigate the cell biological causes for the fast breakdown of glycogen which is observed during the development of the PSE (pale, soft, exudative) syndrome in muscles of stress-susceptible pigs, muscle glycogen phosphorylase (GP) as a key enzyme in two isoforms, a and b, of the energy turnover was isolated from M. longissimus dorsi of normal and PSE-prone pigs of the German Landrace. GP b as well as GP a from normal and PSE-muscles exist in a dimeric form with a molecular weight of 97 000 D per subunit. The tendency for tetramerization of GP b increases in the presence of ATP, whereas the enzyme activity is simultaneously inhibited. The catalytic activities of GP a and GP b from both groups of animals show an optimum at pH 7.0. GP b can be activated to GP a by phosphorylation with the result of a 25% higher optimum specific activity in the case of normal and PSE-muscles. In interaction with glycogen and glucose-1-phosphate GP b follows the characteristics of a Michaelis-Menten kinetic, whereas the binding of AMP and phosphate proves to be allosteric. In comparison of the structural and kinetic characteristics of GP from normal as well as PSE-muscles no significant differences could be determined, indicating that GP does not belong to those factors which are triggering an accelerated energy turnover of ATP in muscles of stress-susceptible pigs.

Comparative studies of pyruvate kinase from PSE and normal pig muscles

A fast breakdown of glycogen is observed in muscles of stress-susceptible pigs leading to pale, soft and exudative (PSE) meat. We report a comparative study of pyruvate kinase from muscles of normal and PSE-prone pigs. Compared with the enzyme from normal muscle, pyruvate kinase isolated from PSE muscle shows a five times lower Michaelis constant, Km, for phosphoenol pyruvate and a more than ten times higher Kcat/Km value. The pH dependency of the enzymatic activity is shifted to more acidic values for pyruvate kinase from PSE muscles. According to isoelectric focusing, pyruvate kinase from PSE muscle consists of three isoforms, while only two isoforms are detectable in pyruvate kinase preparations from normal pigs. The various isoforms were isolated by preparative isoelectric focusing and their steady-state properties were compared. Isoform 3, which is found only in PSE muscle, shows a 10-fold higher specific activity, a 30-fold lower Km value and a 100-fold increased kcat/Km value for phosphoenol pyruvate as compared to isoform 1. The presence of isoform 3 in PSE muscle appears to be responsible for the high activity of this enzyme under the more acidic conditions prevailing in PSE muscle. In vitro phosphorylation and dephosphorylation experiments using total enzyme and purified isoenzyme 1 suggest that isoforms 2 and 3 arise from isoform 1 by phosphorylation. Thus protein phosphorylation seems to be responsible for the shift in activity of pyruvate kinase, a key enzyme of glycolysis, under the acidic conditions of PSE muscles.

Inbred testing of tomato (Lycopersicon esculentum L.) F1 varieties by ultrathin-layer isoelectric focusing of seed protein

To test seed lots of tomato F1 hybrid varieties for the presence of undesirable inbred seeds by electrophoresis, a method has been developed on the basis of ultrathin-layer isoelectric focusing. The method is based on the genetic variation of the seed protein PRS-1 which could be visualized by isoelectric focusing of a 5 mM NaCl-soluble seed protein extract in a pH 6-9 gel followed by protein staining. Two genetic variants of the PRS-1 protein, PRS-1+ and PRS-1(1), were found among open-pollinated varieties, as well as among F1 hybrid varieties. The isoelectric points (pI) of the PRS-1 proteins are 7.1 and 6.1 for PRS-1+ and PRS-1(1), respectively. The PRS-1 protein is unique to seed tissue and is located primarily in the embryo. A genetic 1:2:1 segregation of the gene Prs-1 among several F2 populations shows monogenic inheritance. Analysis of commercial F1 hybrid varieties from several seed companies indicated that the Prs-1(1) allele, in contrast to the Prs-1+ allele, is primarily present in gene pools of "Money-maker type" tomatoes. The described method is generally applicable to all tomato F1 varieties that are heterozygous for the gene Prs-1. With the described method one person can routinely analyze more than 768 seeds per day.

Rehydratable agarose gels: application to isoelectric focusing in 9 molar urea

A method is described for the preparation of rehydratable agarose gels, with specific application to the direct incorporation of 9 M urea and carrier ampholytes into rehydratable agarose gels for use in isoelectric focusing. After drying the agarose gel containing an uncharged linear polyacrylamide, one gel volume of a 9 M urea-carrier ampholyte solution is absorbed directly into the gel in 60 min, eliminating equilibration or dialysis of the gel in larger volumes of the 9 M urea-carrier ampholyte solution. Proteins with a molecular mass of 970,000 Da can be separated by isoelectric focusing in these rehydratable gels. The focused proteins can then be quantitatively transferred to nitrocellulose in less than 10 min, and any immunostaining procedure can be used to probe the blotted proteins. These agarose gels are easy to make, they rehydrate rapidly and they can be used in applications other than isoelectric focusing.

HydroLink gel electrophoresis (HLGE). I. Matrix characterization

A new gelatinous matrix is reported, having intermediate properties between those of polyacrylamide and agarose gels. The matrix has the unique property of being amphiphilic, i.e. of swelling in both plain water and polar organic solvents, and seems particularly well suited for electrophoresis of DNA. The compatibility with organic solvents includes 50% dimethyl sulphoxide, 50% tetramethyl urea, 50% acetonitrile and 50% tetrahydrofuran, the latter having a dielectric constant of 20. The matrix is hypothesized to consist of brush-like pillars, having a hydrophobic core and a hydrophilic coating. The latter is formed by short chains protruding in the surrounding liquid and able to coordinate large amounts of water.

The use of ultrathin-layer polyacrylamide gel isoelectric focusing in two-dimensional analysis of plant and fungal proteins

Although use of ultrathin polyacrylamide gel isoelectric focusing in the first dimension of two-dimensional analysis bestows a number of advantages, it has been little used by the plant science community. Nonstandardization along with problems unique to the format have probably delayed wider adoption. Relevant parameters were therefore tested in order to optimize resolution, reproducibility, economy and ease of use. Ultrathin-layer gels (200 microns in this study) used in the first dimension require a semirigid backing for support. Widely available matte-finished thin polyester film without chemical pretreatment was found to bind the gel adequately. The gel adheres to the film through all processing steps, yet, if desired, can be easily transferred to Whatman 3MM paper for special applications such as Western blotting. The ultrathin first-dimensional gels can be quickly dried on the polyester backing for convenient handling and long term storage. Strips cut from the dried gel for use in the second dimension are more easily manipulated than their tube format counterparts. The difficulty of disrupting and recovering microsamples of labeled leaf and root tissue prompted the invention of an efficient and simple communition device. An economical and efficient silver stain process is also described. This analytical technique was applied in an attempt to detect resistance gene products in different genetic backgrounds of maize. Although the ultrathin flatbed format provides as good as or better resolution than the tube gel system, the level of sensitivity was still inadequate to reveal the apparently rare resistance gene product.

Fast and sensitive protein staining with colloidal acid violet 17 following isoelectric focusing in carrier ampholyte generated and immobilized pH gradients

A new method is described for fast and sensitive staining of proteins following isoelectric focusing in carrier ampholyte and immobilized pH gradient polyacrylamide gels. After fixation with trichloroacetic acid the gels are stained for 5-10 min with 0.1-0.2% colloidal Serva Violet 17 (generic name: Acid Violet 17; Color Index No. 42,650) in 10% w/v phosphoric acid. After staining for only 0.5-3 min, major zones, corresponding to 100-500 ng protein, are visible without destaining on a weak background. Detection of minor components requires destaining with 3% w/v phosphoric acid for 5-80 min depending on gel thickness (120-500 microns) and type of support (fabric reinforced versus gels backed to a polyester film). For selected pH marker proteins (bovine serum albumin, carbonic anhydrase, horse myoglobin) a staining sensitivity of 1-2 ng/mm2 protein is found. Dye elution from stained fabric reinforced gels with 50% v/v dioxane-water, followed by absorbance measurements, results in a linear relationship over a range of 1-100 micrograms marker proteins. Staining with collodial Serva Violet 17 is the only method available for fast and high sensitivity and low background staining of immobilized pH gradient gels, without interference from selective dye binding in different pH ranges. Staining with the collodial dye is convenient by avoiding organic solvents with unpleasant vapors and potentially hazardous.

Isoelectric focusing of proteins in rewetted ultrathin polyacrylamide gel layers

Ultrathin layers of polyacrylamide gel bound to glass can be washed, air-dried, and stored for at least 1 year before rewetting in ampholyte solutions for isoelectric focusing. Short-term drying affects neither fluorescent banding of the ampholytes (not evident in conventional gels) nor resolution of complex protein mixtures while prolonged storage seems to have no deleterious effects. Layers are fully functional after soaking for 10 min in solutions that may contain 8 M urea and 10% sorbitol. Rewetting allows the rapid survey of different ampholytes, gradient stabilizers, separator compounds, or protein reagents and is adaptable to concentration modification of the pH gradient (alone or with a gel overlay), to focusing in a transverse urea gradient, and to electrophoresis across a preformed pH gradient. The procedure avoids protein modification by residual polymerizing reagents while adding to the convenience and economy of using ultrathin layers in relatively small formats.