Erythrocyte partitioning in dextran-poly(ethylene glycol) aqueous phase systems. Events in phase and cell separation

Partitioning and concentrating biomaterials in aqueous phase systems

Aqueous phase separation is a general phenomenon which occurs when structurally distinct water-soluble macromolecules are dissolved, above certain concentrations, in water. The number of aqueous phases obtained depends on the number of such distinct macromolecular species used. Aqueous two-phase systems, primarily those containing poly(ethylene glycol) and dextran, have been widely used for the separation of biomaterials (macromolecules, membranes, organelles, cells) by partitioning. The polymer and salt compositions and concentrations chosen greatly affect the physical properties of the phases. These, in turn, interact with the physical properties of biomaterials included in the phases and affect their partitioning. Specific extractions of biomaterials can be effected by including affinity ligands in the systems. The phase systems can also be used to obtain information on the surface properties of materials partitioned in them; to study interactions between biomaterials; and to concentrate such materials.

Reversible modification of thiol-containing polypeptides with poly (ethylene glycol) through formation of mixed disulfide bonds. The case of papaya proteinase III

Papaya proteinase III (PPIII) was purified, as the S-methylthio derivative from the latex of Carica papaya L., by ion-exchange chromatography. Separation of reactivable PPIII from the irreversibly oxidized molecular species of this enzyme was readily achieved after a selective conversion of the reactivated proteinase into the S-monomethoxypoly(ethylene glycol)thio derivative (S-mPEG thio PPIII). From this derivative, a PPIII preparation titrating 1 mol of thiol/mol of enzyme was regenerated. From the physicochemical properties of S-mPEG thio PPIII that were investigated, it is concluded that interactions between the mPEG and the PPIII chains occur only to a limited extent. In addition to its usefulness for purifying thiol-containing enzymes, the mPEG modification resulting from mixed disulfide bond formation may find other practical applications.

Separation of alkaline phosphatase isoforms with and without intact glycan-phosphatidylinositol anchors in aqueous polymer phase systems

Alkaline phosphatase (ALP) isoforms can be distinguished from each other by their partition characteristics in aqueous two-phase systems composed of water-soluble polymers, the phases of which are differentially sensitive to the presence of glycan-phosphatidylinositol anchors. Compared with detergent-based systems, the aqueous polymer systems have the advantage that micelle formation does not take place. Partition of anchor-intact and anchor-degraded molecules in the latter systems is further improved by attachment of a hydrophobic ligand to one of the phase forming polymers. In this way, anchor-intact molecules can be separated from molecules with degraded anchors in a single partition step. The method has been used to confirm that ALP in human serum is predominantly anchor degraded, whereas in bile it retains its anchor intact.

Preparation and preliminary characterization of poly(ethylene glycol)-pepstatin conjugate

The carboxyl function of pepstatin has been coupled, through an amide bond, to methoxypoly(ethylene glycol) (5 kDa), to which an amino function had been previously grafted. The mPEG-pepstatin conjugate inhibits hog pepsin (aspartic proteinase) in vitro as pepstatin itself, however, with a 400 times higher apparent Ki. The conjugate apparently does not inhibit proteinases belonging to other proteinase families such as serine (trypsin, carboxypeptidase Y), cysteine (Papaya proteinase III), or metallo (collagenase) proteinases.