A motor-driven syringe-type gradient maker for forming immobilized pH gradient gels

TheAlpher, Bethe andGamow of IEF, the alpha-Centaury of electrokinetic methodologies. Part II: Immobilized pH gradients

The present review (a follow up of Electrophoresis 2006, 27, 923-938 on conventional IEF) highlights the developmental steps of the IPG technology, from a nebulous start limiting the technique to just 1 pH unit intervals up to the description of extended pH gradients, encompassing as much as 8.5 pH units. Although computer algorithms had been developed for optimizing recipes so as to obtain the most precise and most linear pH gradients, it was also realized that nonlinear pH intervals, covering the pH 3-10 range, would be extremely beneficial in 2-D map analysis, since they would follow the pI distribution of proteins in living systems. The synthesis of a number of Immobiline chemicals (the acrylamido weak acids and bases meant to be incorporated into the nascent polyacrylamide chains) is also reported. The review ends with preparative aspects of IPGs, with the introduction of multicompartment electrolyzers with Immobiline membranes.

Immobilized concentration gradients of nerve growth factor guide neurite outgrowth

Axons are guided to their targets by a combination of haptotactic and chemotactic cues. We previously demonstrated that soluble neurotrophic factor concentration gradients guide axons in a model system. In an attempt to translate this model system to a device for implantation, our goal was to immobilize a stable neurotrophic concentration gradient for axonal (or neurite) guidance. Nerve growth factor (NGF) was immobilized within poly(2-hydroxyethylmethacrylate) [p(HEMA)] microporous gels using a gradient maker. The NGF was stably immobilized, with only approximately 0.05% of the amount originally incorporated into the gel released over an 8-day period. Immobilized NGF was bioactive: the percent of PC12 cells extending neurites on NGF-immobilized p(HEMA) gels was 16 +/- 2%, which was statistically the same as those exposed to soluble NGF (22 +/- 6%). We were able to predict and reproducibly create stable NGF concentration gradients in the gel. At an NGF concentration gradient of 357 ng/mL/mm, PC12 cell neurites were guided up the gradient. The facile, flexible, and reproducible nature of this method allowed us to translate soluble growth factor gradient models to stable growth factor gradient devices that may ultimately enhance axonal guidance and regeneration in vivo.

Capabilities and potentialities of transverse pore gradient gel electrophoresis

Transverse pore gradient gel electrophoresis is important as a tool for obtaining nonlinear Ferguson plots [log(mobility) vs. gel concentration], e.g. in application to DNA in polyacrylamide gels or to agarose gels, with the purpose of evaluating molecular properties (size, conformation, malleability) and gel fiber properties (fiber radius and length per unit volume). To date, it is capable of (i) yielding gel patterns ("Ferguson curves") of migration distance vs. predicted % T-range of the pore gradient, assuming its linearity; (ii) yielding information regarding molecular conformation from the intersection of Ferguson curves of unknowns (e.g. bent DNA) with those of standards; (iii) acquisition of Ferguson curves by computer, using prototype instrumentation; (iv) mathematical manipulation of acquired Ferguson curves to yielding Ferguson plots, providing that mobility in free solution has been assessed by capillary zone electrophoresis. The potentialities of the method remain unfulfilled to date due to (i) the unavailability, with a single exception, of an accurate and precise way to produce pore gradients of known shape; (ii) unavailability of a routinely applicable analysis for % T; (iii) unavailability of optimized, user-friendly and foolproof instrumentation for computer acquisition of Ferguson curves, including the present inapplicability of a commercially available electrophoresis apparatus with intermittent optical detection to transverse pore gradient gels; and (iv) unresolved problems in the statistical evaluation of Ferguson curves.

Characterization of the type of carbohydrate chains of the higher molecular weight (140 kDa) acid phosphatase of the frog liver

1. The higher molecular weight, (HMW, M(r) 140 kDa) acid phosphatase (AcPase) of the frog liver (Rana esculenta) was separated into enzymatically active components by isoelectric focusing in an immobilized pH gradient and their carbohydrate chains were analyzed by specific lectin binding after native blotting. 2. The lectin-binding patterns obtained with ConA, WGA, LcH and PNA as well as with WGA and PNA after desialylation indicate that the frog liver HMW AcPase contains predominantly N-linked complex and/or hybride type carbohydrate chains with terminal sialic acid and fucose residues; O-glycosylated enzyme components with free and sialic acid substituted Gal-GalNAc sequences were also detected.

Distinction between supercoiled and linear DNA in transverse agarose pore gradient gel electrophoresis

Four species of linear DNA and the first four members of a linking series, generated by treatment of plasmid DNA (PUC19, 2.7 kb) with mitochondrial topoisomerase I, were differentiated by transverse agarose pore gradient gel electrophoresis. The experimental curves of migration distance vs. agarose concentration (Ferguson curves) of supercoiled DNA exhibit a steeper trajectory than those of linear DNA of the same size range. As a consequence, the four supercoiled species exhibit an increase in apparent size (relative to linear DNA standards) with increasing agarose concentration. Both the crossing of the Ferguson curves with those of linear standards as well as the apparent size increase with agarose concentration can serve to detect supercoiled plasmid-sized DNA in mixtures with linear DNA.

Transverse agarose pore gradient gel electrophoresis of DNA

Transverse agarose pore gradient gels were prepared on GelBond in the concentration range of nominally 0.2-1.5% SeaKem GTG agarose, using density stabilization by glycerol and incorporation of a dye to define the gel concentration at each point on the pore gradient gel. The distribution of the dye was evaluated by photography, video-acquisition and digitization of the gradient mixture and by densitometry of the gel. The gel was applied to the electrophoresis of a 1-kb standard ladder of DNA fragments, using standard submarine apparatus. The method extends to agarose gel electrophoresis the benefits of semi-automated analysis of 'Ferguson curves' described in application to polyacrylamide gel by Wheeler et al. (J. Biochem. Biophys. Methods 24, 171-180).

Simultaneous Ferguson plot analysis, using electrophoresis on a single agarose pore gradient gel, of DNA fragments contained in a mixture

A recent study has demonstrated the feasibility of obtaining Ferguson plots in agarose gel electrophoresis, using a single pore gradient gel. We now report three remedies for defects in the previous experimental approach: (i) UV-absorbing media for density stabilization of the gel is avoided by replacing 5-(N-2,3-dihydroxypropylacetamido)-2,4,6-triiodo-N,N'-bis(2,3-dihy droxypropyl) isophthalamide (Nycodenz) with heavy water; this renders the method applicable to ethidium bromide-labeled DNA. (ii) The density stabilizing medium is kept from having an effect on field strength. (iii) Data collection by uninterrupted time-lapse photography is possible by using an apparatus with a quartz window. These three measures make the method practical for the gel electrophoretic identification and physical characterization of DNA species, potentially up to 50 kb in size.

Procedures and computer program for deriving the Ferguson plot from electrophoresis in a single pore gradient gel: application to agarose gel and a polystyrene particle

This study presents a computerized evaluation of pore gradient gel electrophoretograms to arrive at estimates for both the particle-free mobility and retardation coefficient, which is related to particle size. Agarose pore gradient gels ranging from 0.2 to 1.1% agarose were formed. Gel gradients were stabilized during their formation by a density gradient of 0-20% 5-(N-2,3-dihydroxypropylacetamido)- 2,4,6-triiodo-N,N'bis-(2,3-dihydroxypropyl)-isophthalamide (Nycodenz). Densitometry of gelled-in Bromophenol Blue showed that these pore gradients exhibited a linear central segment and were reproducible. Migration distances of polystyrene sulfate microspheres (36.5 nm radius) in agarose pore gradient gel electrophoresis were determined by time-lapse photography at several durations of electrophoresis. These migration distances were evaluated as a function of migration time as previously reported (D. Tietz, Adv. Electrophoresis 1988, 2, 109-169). Although this is not necessarily required, the mathematical approach used in this study assumed linearity of both the pore gradient and the Ferguson plot for reasons of simplicity. The data evaluation on the basis of the extended Ogston model is incorporated in a user-friendly program, GRADFIT, which is designed for personal computers (Macintosh). The results obtained are compared with (1) conventional electrophoresis using several gels of single concentration with and without Nycodenz, and (ii) a different mathematical approach for the analysis of gradient gels (Rodbard et al., Anal. Biochem. 1971, 40, 135-157). Moreover, a simple procedure for evaluating linear pore gradient gels using linear regression analysis is presented. It is concluded that the values of particle-free mobility and retardation coefficient derived from pore gradient gel electrophoresis using the different mathematical methods are statistically indistinguishable from each other. However, these values are different, albeit close, to those obtained from conventional Ferguson plots. One of the possible reasons for this relatively minor discrepancy is that the particle-free mobility changed slightly during electrophoresis, which has a different effect on electrophoresis in homogeneous gels (single time measurement) and pore gradient gels (multiple time measurements). The characterization of particles according to size and charge by pore gradient electrophoresis provides a significant operational simplification and sample economy compared to that requiring the use of several gel concentrations, although at the price of increased requirements of instrumentation.

Studies on the oligosaccharide heterogeneity of the isoelectric forms of the lower molecular weight acid phosphatase of frog liver

1. The lower molecular weight, heterogeneous acid phosphatase (AcPase) from the frog liver (Rana esculenta) containing AcPase I, II, III and IV was separated into enzymatically active components by isoelectric focusing in an immobilized pH gradient. 2. The blotted enzyme bands were characterized by their different binding patterns obtained with the lectins concanavalin A, wheat germ agglutinin (WGA), Lens culinaris hemagglutinin (LcH) and peanut agglutinin (PNA). 3. In situ neuraminidase treatment reduced the staining intensity of some WGA-bands and increased that of PNA-bands. 4. The finding that AcPases I, II, III and IV differ in their carbohydrate chain composition, together with previous results showing different bioactivities of AcPases III and IV, indicates a correlation between the glycosylation state of enzyme forms and their physiological action.

Electrofocusing of acid phosphatases from frog liver, using an immobilized pH gradient

Isoelectric focusing on carrier ampholyte-containing immobilized pH gradient gels was applied (i) to gels submerged in silicone oil on a Peltier cooled apparatus, (ii) to the separation of the higher molecular weight (HMW, Mr 140,000) and the lower molecular weight (LMW, Mr 38,000) acid phosphatases (AcPases) from frog livers. (i) Electrofocusing was conducted on gels submerged under silicone oil cooled and stirred on a Peltier-thermoregulated horizontal gel support plate. This procedure aimed at a) improving the temperature control of the gel by direct contact of coolant with the gel surface, and thus at being able to focus at the maximal field strength and consequently highest resolution; b) preventing evaporation from the gel and c) excluding atmospheric carbon dioxide. Silicone oil submersion did not abolish water loss from the gel into the electrolyte strips during isoelectric focusing, or a rippled gel surface. Absence of water exudation on the ripples noted previously by Atland [1] was observed. (ii) The electrofocusing of AcPases on immobilized pH gradients yielded patterns which remained stationary as a function of time, by contrast to previous analyses on carrier ampholyte generated pH gradients. The total number of enzymatically active components found in the enzyme preparations from different stages of purification and in the isolated HMW and LMW AcPases was 18. The HMW and LMW AcPases focused in characteristic pH ranges and exhibited qualitative and quantitative pattern differences. Their band patterns add up to that of a crude preparation containing both enzymes. Neither polyacrylamide gel electrophoresis (PAGE) at any nondenaturing pH, nor isoelectric focusing in carrier ampholytes with pattern changes due to the pH gradient drift were able to yield that result.

Toward a steady-state pore limit electrophoresis dimension for native proteins in two-dimensional polyacrylamide gel electrophoresis

Polyacrylamide gel electrophoresis in linear pore gradients (4.8 to 48% T, 5% CBis) provides for migration arrest, in a practical sense, after about 5000 Vh for proteins of 290 and 450 kDa, but not for smaller proteins over 20,000 Vh. The arrest is not due to inadequate field strength nor is it caused by water redistribution within pore gradient gels. The possibility is being discussed that exponential pore gradients, and a higher or a lower degree of crosslinking suggested by the literature may be remedies for the present failure to arrest the migration of smaller proteins.

The adsorption of large proteins in electrofocusing on immobilized pH gradients: I. Protein specificity and dependence on Immobiline and carrier ampholyte concentrations

Phycoerythrin, ferritin, urease, beta-galactosidase and thyroglobulin, with molecular masses in excess of 200 kDa, adsorb and consequently fail to migrate to, and focus at, their pI positions in electrofocusing in immobilized pH gradients at a total Immobiline concentration of 20 mM while they do focus normally in pH gradients formed by carrier ampholytes. The addition of carrier ampholytes (pH range 3.5-9.5) at concentrations of 0.1 to 5% to the Immobiline-containing gels reduces adsorption (desorbs) some but not all of the 5 proteins at specific Immobiline concentrations. The adsorption is not due to water redistribution and consequent reduction in gel porosity; nor is it due to conductivity minima across the pH gradient. The hypothesis that the presence of oligomeric Immobiline contributed to the protein adsorption is the subject of the accompanying report.