Unique selectivity windows using selective displacers/eluents and mobile phase modifiers on hydroxyapatite

Retention Mechanism of Proteins in Hydroxyapatite Chromatography - Multimodal Interaction Based Protein Separations: A Model Study

BACKGROUND

Retention mechanism of proteins in hydroxyapatite chromatography (HAC) was investigated by linear gradient elution experiments (LGE).

MATERIALS AND METHODS

Several mobile phase (buffer) solution strategies and solutes were evaluated in order to probe the relative contributions of two adsorption sites of hydroxyapatite (HA) particles, C-site due to Ca (metal affinity) and P-site due to PO4 (cation-exchange). When P-site was blocked, two basic proteins, lysozyme (Lys) and ribonuclease A(RNase), were not retained whereas cytochrome C(Cyt C) and lactoferrin (LF) were retained and also retention of acidic proteins became stronger as the repulsion due to P-site was eliminated. The number of the binding site B values determined from LGE also increased, which also showed reduction of repulsion forces.

CONCLUSION

The selectivity (retention) of four basic proteins (RNase, Lys, Cyt C, LF) in HAC was different from that in ion-exchange chromatography. Moreover, it was possible to tune the selectivity by using NaCl gradient.

Antibody purification using affinity chromatography: a case study with a monoclonal antibody to ractopamine

The application of antibodies to small molecules in the field of bioanalytics requires antibodies with stable biological activity and high purity; thus, there is a growing interest in developing rapid, inexpensive and effective procedures to obtain such antibodies. In this work, a ractopamine (RAC) derivative, N-4-aminobutyl ractopamine (ABR), was synthesized for preparing new specific affinity chromatography to purify a murine monoclonal antibody (mAb) against RAC from ascites. The performance of the new specific chromatography was compared with four other purification methods in terms of recovery, purity and biological activity of mAb. These four purification methods were prepared by using specific ligands (RAC and RAC-ovalbumin) and commercial ligands (protein G and protein A), respectively. The results showed that the highest recovery (88.1%) was achieved using the new chromatography; in comparison, the recoveries from the other methods were all below 70%. The purity of the mAbs from the new chromatography was 88.3%, while, the highest purity of 97.6% was from protein G chromatography and the lowest purity of 84.7% was from protein A chromatography. The biological activity of the purified mAb from all of the chromatography methods was comparable in enzyme-linked immunosorbent immunoassay (ELISA).

Sample displacement chromatography as a method for purification of proteins and peptides from complex mixtures

Sample displacement chromatography (SDC) in reversed-phase and ion-exchange modes was introduced approximately twenty years ago. This method takes advantage of relative binding affinities of components in a sample mixture. During loading, there is a competition among different sample components for the sorption on the surface of the stationary phase. SDC was first used for the preparative purification of proteins. Later, it was demonstrated that this kind of chromatography can also be performed in ion-exchange, affinity and hydrophobic-interaction mode. It has also been shown that SDC can be performed on monoliths and membrane-based supports in both analytical and preparative scale. Recently, SDC in ion-exchange and hydrophobic interaction mode was also employed successfully for the removal of trace proteins from monoclonal antibody preparations and for the enrichment of low abundance proteins from human plasma. In this review, the principals of SDC are introduced, and the potential for separation of proteins and peptides in micro-analytical, analytical and preparative scale is discussed.