Dennis Brian Rylatt

Depletion of the highly abundant protein albumin from human plasma using the Gradiflow.

Pathological activation of the immune-competent glial cells is an obligatory event in neurodegenerative diseases. The secondary recruitment of astrocytes, resulting from an upgraded microglial activation, represents a critical point. Reactive astrocytes have to give up physiologically important functions (control of extracellular homeostasis and of synaptic transmission) and build a synergistic alliance with microglia in promoting oxidative, excitotoxic and beta-amyloid-induced neuronal damage. Growing understanding of the pathogenically relevant molecular signaling pathways opens new possibilities of pharmacological corrections at the second messenger level. Here, the respective know-how of endogenous modulators, such as adenosine, might be used. The aim should be a titration of the glia reaction in order to maintain supposed beneficial functions of reactive microglia and to prevent the dangerous involvement of astrocytes.

Preparative-scale isoelectric trapping separations using a modified Gradiflow unit

The Gradiflow BF200 preparative electrophoretic unit (Gradipore), which has been developed for size-based and charge-sign-based protein separations and in which the hydraulic flow path of the recirculating sample stream in the separation cartridge is orthogonal to the electric field, has been modified to carry out binary protein separations using the principles of isoelectric trapping. The disposable separation cartridge contained three isoelectric membranes which, along with the cartridge holder, formed the anode and cathode compartments and the anodic and cathodic separation compartments. The utility of the modified instrument was demonstrated by effecting a binary separation of chicken egg white across an isoelectric point 5.5 isoelectric membrane. The desalting and subsequent binary separation steps proved to be remarkably rapid, due to the favorable combination of short electrophoretic path, high electric field strength and large effective isoelectric membrane surface area.

Preparative electrophoresis: a general method for the purification of polyclonal antibodies

Antibodies were purified from normal rabbit, sheep, goat, rat, human and bovine serum using preparative electrophoresis on a Gradiflow in a single-step process using an asymmetrical cartridge with three different pore size polyacrylamide membranes. Recoveries in each case were over 80% and were higher than those obtained using affinity chromatography on protein A, protein G or protein L. Degree of purity was at least comparable with these methods. These results suggest that preparative electrophoresis can be considered a general method for the purification of research quantities of antibodies from multiple serum sources and may be particularly useful where the reactivity with protein A, G or L is unknown.

Gradiflow as a prefractionation tool for two-dimensional electrophoresis

The Gradiflow™, a preparative electrophoresis instrument capable of separating proteins on the basis of their size or charge, was used to separate whole cell lysates, prepared from bakers yeast (Saccharomyces cerevisiae) and Chinese snow pea seeds (Pisum sativum macrocarpon), into protein fractions of different pH regions. Both broad and narrow range (with a difference of approximately 1 pH unit) pH fractions were obtained. Analysis of the protein fractions by isoelectric focusing gels and two‐dimensional (2‐D) polyacrylamide gel electrophoresis indicated minimal overlap between the pH fractions. Further, when the prefractionated acidic samples were analyzed on pH 4–7 immobilized pH gradient 2‐D gels, improved resolution of the proteins within the chosen pH region was achieved compared to the unfractionated samples. This study demonstrates that the Gradiflow could be used as a preparative electrophoresis tool for the isolation of proteins into distinct pH fractions.

The purification of IgY from chicken egg yolk by preparative electrophoresis.

Chicken IgY has been purified from egg yolk by preparative electrophoresis on the Gradiflow, a system which has been employed for the purification of a wide range of proteins with high recovery and biological activity. Protein purification on the Gradiflow utilises electrophoresis with selected combinations of porous membranes and buffers. The purification of IgY was achieved by initial PEG lipid precipitation, then a single step Gradiflow run by a strategy based on the relatively high pI range of IgY compared to other egg yolk proteins. The IgY yields obtained from the delipidised supernatant are consistently greater than 80% by immunoassay. The purity of the IgY fraction compared favourably with IgY prepared using three commercial products.

Purification of the basic protein avidin using Gradiflow technology

The Gradiflow, a preparative electrophoresis instrument, which separates proteins on the basis of charge or size, was used to purify the basic protein avidin, pI 10, from chicken egg white. Using a charge based separation at pH 9.0, the high pI of avidin and lysozyme (pI 10.7) allows them to be easily separated from remaining egg white proteins, as these are the only positively charged proteins. In a second step at pH 10.2, the negatively charged avidin is separated from the positively charged lysozyme. This sequential two-step protocol was complete within 4.5h. Enzyme immunoassay of avidin fractions obtained indicated recoveries of 60-65% from one egg white with minimal lysozyme activity detected.

Design of a new, twelve-channel electrophoretic apparatus based on the Gradiflow technology

The Gradiflow technology, originally designed to carry out binary, size-based and charge sign-based electrophoretic protein separations, has been extended to simultaneously obtain multiple protein fractions from a single electrophoretic separation. The separation unit of the new apparatus houses the anode and cathode compartments and up to twelve shallow separation compartments through which the background electrolyte solution that contains the separated protein fractions is recirculated. The separation compartments are formed from grids as thin as 1.2 mm and polyacrylamide membranes as thin as 0.15 mm, all with corresponding multiple inlet and outlet ports. The average pore size of the polyacrylamide membranes can be varied to permit passage of proteins in the 5000-800 000 molecular mass range. The electric field, orthogonal to the flow paths of the recirculated background electrolyte, selectively moves the sample components across the polyacrylamide separation membranes. Selective protein transport can be achieved by exploiting differences in either the relative size of the proteins or the charge sign of the proteins. The advantages of the new apparatus stem from the synergistic combination of the short electrophoretic transfer distances, high electric field strength, large effective surface areas of the separation membranes, and the great flexibility with which apparati containing one to twelve separation compartments can be created.