Partition of ribosomes in two-polymer aqueous phase systems

Two-polymer aqueous phase systems are described in which ribosomes selectively partition into one of the phases. One of the phase systems is used to determine rapidly and conveniently binding of thiostrepton and erythromycin to Escherichia coli ribosomes under equilibrium conditions.     

Partition of rat erythrocytes in aqueous polymer twophase systems

The partition of rat erythrocytes between the top phase and interface of aqueous poly(ethylene glycol)-dextran two-phase systems containing 0.15 M NaCl and 0.01 M sodium phosphate depends on the association of the cells with microscopic globules of dextran that persist in the poly(ethylene glycol)-rich top phase after the horizontal interface between the two phases has formed.     

Partition of isomeric dipeptides in poly(ethylene glycol)/magnesium sulfate aqueous two-phase systems

A series of isomeric dipeptides, i.e., those containing identical residues but in different order such as Trp-Gly versus Gly-Trp, was partitioned in a poly(ethylene glycol) (PEG)/magnesium sulfate (MgSO4) aqueous two-phase system. Dipeptides having a more hydrophobic character favored the upper (PEG) phase. Moreover, the partition coefficients for isomeric dipeptides are different, with the partition coefficients for dipeptides containing the more hydrophobic residue in the C-terminal position being, in general, greater than the partition coefficients for corresponding isomers which contain the more hydrophobic residue in the N-terminal position. These observations can be attributed to the different interactions that the isomers have with specific two-phase systems.     

Partition of polysaccharide-coated liposomes in aqueous two-phase systems

Hydrophobized polysaccharides such as cholesterol-bearing pullulan (CHP), dextran (CHD) and mannan (CHM) effectively coat the liposomal surface. Partition of the hydrophobized polysaccharide-coated liposomes in an aqueous two-phase system (PEO (top)/pullulan (bottom) or PEO (top)/dextran (bottom)) was investigated (PEO = poly(ethylene oxide)). Conventional liposomes without a polysaccharide coat mostly locate at the interface between the two polymer phases. The polysaccharide-coated liposomes, on the other hand, were partly partitioned to the bottom polysaccharide phase depending on the structure of the hydrophobized polysaccharide on the liposomal surface. The affinity between the polysaccharide on the liposomal surface and that in the bulk bottom phase controls the efficiency of partition. The sequence of interaction strength between the two carbohydrates as the following: for the PEO/dextran two-phase system, dextran_(liposome)-dextran_(bulk) > mannan_(liposome)-dextran_(bulk) > pullulan_(liposome)-dextran_(bulk); while for the PEO/pullulan system, the sequence of interaction strength was pullulan_(liposome)-pullulan_(bulk) > dextran_(liposome)-pullulan_(bulk) ≈ mannan_(liposome)-pullulan_(bulk).     

The dynamics of phase partition. A study of parameters affecting rat liver organelle partitioning in aqueous two-polymer phase systems.

Separation of subcellular organelles by two-phase partition is thought to reflect differential partition of the organelles between the two phases or between one of the phases and the interface. Studies by Fisher and colleagues [Fisher & Walter (1984) Biochim. Biophys. Acta 801, 106-110] suggest that cell separation by phase partition is a dynamic process in which the partition changes with time. This is mainly due to association of the cells with sedimenting droplets of one phase in the bulk of the other. Rat liver organelle partition was studied to determine whether the same dynamic behaviour is observed. Partition was clearly time-dependent during 24 h at unit gravity, and was also affected by altering the volume ratio of the two phases and the duration of phase mixing. These results indicate that, as with cells, the partition of organelles between phases is a dynamic process, and is consistent with the demonstration that organelles adhere to the phase droplet surfaces. Optimization of the volume ratio between phases may lead to significant processing economies. Organelle sedimentation in the upper phase was significantly faster than in the isoosmotic sucrose. Theoretical modelling of apparent organelle sizes indicates that aggregation occurs in the poly(ethylene glycol)-rich upper phase. This phenomenon is likely to limit the use of this technique in organelle separations unless means can be found to decrease aggregation.     

Hydrophobic interaction determined by partition in aqueous two-phase systems. Partition of proteins in systems containing fatty-acid esters of poly(ethylene glycol).

In this report we describe a new method which is useful for measuring hydrophobic interactions between aliphatic hydrocarbon chains and proteins in aqueous environment. The method is based on partition of proteins in an aqueous two-phase system containing dextran and poly(ethylene glycol) and different fatty acid esters of poly(ethylene glycol). The partition is measured under conditions where contributions from electrostatic interactions are eliminated. The difference in partition of proteins in phase systems with and without hyrocarbon groups bound to poly(ethylene glycol), deltalog K, where K is the partition coefficient, is taken as a measure of hydrophobic interaction. Deltalog K varies with size of hydrocarbon chain and type of protein. The length of the aliphatic chain should be greater than 8 carbon atoms in order to get a measurable effect in terms of deltalog K. Bovine serum albumin, beta-lactoglobulin, hemoglobin and myoglobin have been shown to have different affinities for palmitic acid ester of poly(ethylene glycol). No hydrophobic effect could be observed for ovalbumin, cytochrome c or alpha-chymotrypsinogen A.     

Partition coefficient of bovine serum albumin in two-phase aqueous systems

Summary We measured partition coefficients of bovine serum albumin in the following two-phase aqueous systems: polyethylene glycol-dextran and polyethylene glycol-potassium phosphate. We report the effects on partition coefficients of variables such as relative molecular masses of polyethylene glycol and dextran, phase composition and temperature.Contribution of National Bureau of Standards, not subject to copyright.     

Partition of horseradish peroxidase in aqueous two-phase systems containing polyvinylpyrrolidone

Growing peroxidase utilisation in different industries encourages the search for high benefit/cost ratio purification methods such as aqueous two-phase partition. In this way, the partitioning behaviour of peroxidase from Armoracia rusticanaroots in polyvinylpirrolidone/Reppal and polyvinylpirrolidone/salt aqueous two-phase systems was investigated. Based on these results, a two-step purification process was developed. In the first system (polyvinylpyrrolidone K30/Reppal PES 200, pH 7.0), cell debris and some contaminating proteins were shifted to the bottom phase while peroxidase concentrated in the top phase. After discarding the bottom phase, the second step involved addition of magnesium sulphate thus forming a second aqueous two-phase system. At this step, the enzyme was extracted into the salt-rich bottom phase. The overall yield was 75% and the purification factor 7.3.This revised version was published online in October 2005 with corrections to the Cover Date.     

Partition and counter-current distribution of membrane particles in aqueous dextran-poly(ethylene glycol) two-phase systems with special reference to synaptosomes

Aqueous two-phase systems composed of water, dextran and poly(ethylene glycol) can be used for the separation of biological particles. The adjustment of the partition of such particles between the two phases and the interface between them has been studied by using a preparation of synaptosomes (from calf brain cortex) also containing free mitochondria. The partition has been affected by variation of polymer concentrations and addition of salts, e.g. phosphates and chloride. The time for separation of the phases showed a bimodal behaviour with an initially rapid formation of bulk phases followed by a slow phase separation. The relative amount of mixed phases at the time of the transition was proportional to the amount of particles included. Counter-current distribution with moderate time for the phase separation was carried out in such way that the interface material travelled with approximately half the speed of the moving upper phase. In this way the distribution of the particles between the upper phase and the interface as well as between the interface and the lower phase could be studied in the same experiment. The heterogeneity of the synaptosome preparation was clearly demonstrated by counter-current distribution at low polymer concentrations while no separation was obtained when the system contained larger amounts of polymers. Possible reasons for this behaviour are discussed.     

Partition features and renaturation enhancement of chymosin in aqueous two-phase systems

Aqueous two-phase systems of polyethylene glycol (molecular mass 1450, 3350 and 6000)-phosphate and polyethylene-polypropylene oxide (molecular mass 8400)-maltodextrin systems were used in order to study the partition features of recombinant chymosin from inclusion bodies. These systems in the presence of 8M urea were used for the solubilization of inclusion bodies containing recombinant chymosin and for the oxidative renaturation of this protein. Recombinant chymosin showed to be partitioned in favour of the top phase in all studied systems with a partition coefficient between 4 and 6. The recovery of the chymosin biological activity was 32% in the polyethylene-polypropylene oxide, while in the polyethylene glycol-phosphate the recovery was 50-59%. The results indicate that the liquid-liquid extraction would be an adequate tool able to isolate and concentrate chymosin from inclusion bodies with a yield of biological activity higher than that obtained from the standard method (43%).