Immunoaffinity chromatography

Immunoaffinity chromatography is a process in which the binding affinity of an antigen to a parent antibody is utilized as a basis of separation. Owing to the customized avidity and specificity, monoclonal antibodies (Mabs) have become indispensable for both protein characterization and purification. The immunosorbent performance is dependent on the support matrix upon which the antibody is immobilized and on the activation chemistry used couple the antibody to the matrix. This report details, protocols to immobilize Mabs on commercially available supports, and a method to compute immunosorbent efficiency.     

Paralog chromatography

As a mixed mode ligand, a small peptide can mimic an antibody's paratope (antigen recognition site). This report describes the construction of a representative set of paratope analogs, or "paralogs," which can be conjugated to a chromatographic sorbent to combine desirable characteristics of traditional high-performance liquid chromatography columns with the specificity of a moderate affinity antibody. The broad utility of this novel set of protein separatory reagents is illustrated on the complex mixture of proteins in a yeast lysate.     

Countercurrent chromatography

Countercurrent chromatography is a newly developed versatile partition chromatography which totally eliminates the use of solid supports. The method utilizes the intriguing hydrodynamic behavior of two immiscible solvents in a rotating coiled tube. Various types of seal-free flow-through centrifuge schemes are introduced to facilitate a continuous elution process. The method yields high partition efficiencies comparable to liquid chromatography but without the complications arising from the use of solid supports. Countercurrent chromatography covers a wide spectrum of applicable samples ranging from small ions and molecules to macromolecules and even cell particles in both analytical and preparative scales.     

Immunoaffinity chromatography

The basic procedure of immunoaffinity chromatography (IAC) is described. The insoluble support matrices available for IAC and their activation chemistries, including some of the most recently introduced, are reviewed. Means of selecting the most appropriate monoclonal antibody (MAb) are described, although an empirical approach is still required for the final choice of antibody. Precise methods of runing IAC columns are surveyed including the binding, washing, and elution stages, although no precise recommendations can be made particularly for the elution step since this is unique to a particular MAb and antigen. All IAC sorbents lose activity with time through a combination of MAb inactivation and ligand leakage. The relative importance of the two phenomena is discussed, and suggestions are made to minimize the problem along with an indication of the relative stabilities of a range of coupling chemistries. A sample of the proteins purified by IAC is given together with pointers to the future of the technique.     

High-performance liquid chromatography of proteins by gel permeation chromatography

The ability of two high-performance liquid chromatography gel permeation columns to separate proteins was evaluated. These columns gave satisfactory molecular weight separations for some, but not all, proteins tested. These results indicate that there are limitations in confidence of molecular weight determinations made by this technique.     

Evaluation of radial chromatography versus axial chromatography, practical approach

Developments in packing and packing port design of radial columns in recent years have resulted in a claimed significant increase in performance of this process chromatography technology. In this first study, the main chromatographic parameters as efficiency, capacity factor, asymmetry and resolution were evaluated in a unique one-to-one comparison between a 120 ml bed-volume and 6 cm bed length radial chromatography mini-process column against a 50 mm diameter, 6 cm bed height and 120 ml bed-volume axial chromatography column. Radial chromatography showed an increase in efficiency by 31% in the number of plates per meter while the equilibration could be reduced by 0.4-0.5 column volumes. The asymmetry factor for bovine serum albumin in radial chromatography showed a reduction of 20% while the reduction of the asymmetry factor of the smaller protein ovotransferrin decreased even by 46% in comparison to the performance of the comparative axial chromatography column. Therefore in radial chromatography resolution improved up to 20%. The retention volume was similar in both cases. For radial chromatography, the decrease in "width at half height" at Height Equivalent of Theoretical Plates (HETP) measurements was 40% while the decrease of the over-all width of the peak was 27%. For adsorbed/desorbed proteins, the elution peak showed similar results: "width at half height" decreased to 45% while the over-all width of the peak decreased by 28%. The concentration of the non-retained protein in the flow-through (lysozyme), increased by 35% while the concentration of the eluted fraction (serum albumin bovine), increased with 40% in the radial chromatography columns. The better results obtained with the radial column were probably the consequence of the geometrical design of this device (larger inlet surface area and small outlet surface area which concentrate the eluted fraction).     

Improved performance of column chromatography by arginine: dye-affinity chromatography

Arginine has been effectively used in various column chromatographies for improving recovery and resolution, and suppressing aggregation. Here, we have tested the effectiveness of arginine as an eluent in dye-affinity column chromatography using Blue-Sepharose, which binds enzymes requiring adenyl-containing cofactors (e.g., NAD). A common eluent, NaCl, showed a broad elution peak with low recovery of lactate dehydrogenase, at most approximately 60% using 2M salt. The recovery decreased as the NaCl concentration was either decreased or increased; i.e., the recovery was maximum at 2M. On the contrary, addition of arginine to the eluent resulted in more than 80% recovery above 0.5M and the recovery was nearly independent of the arginine concentration. The elution peak was much sharper with arginine, leading to elution of more concentrated protein solution. Successful elution of proteins bound to the ATP-agarose resins by arginine was also described.     

Centrifugal precipitation chromatography

Centrifugal precipitation chromatography separates analytes according their solubility in ammonium sulfate (AS) solution and other precipitants. The separation column is made from a pair of long spiral channels partitioned with a semipermeable membrane. In a typical separation, concentrated ammonium sulfate is eluted through one channel while water is eluted through the other channel in the opposite direction. This countercurrent process forms an exponential AS concentration gradient through the water channel. Consequently, protein samples injected into the water channel is subjected to a steadily increasing AS concentration and at the critical AS concentration they are precipitated and deposited in the channel bed by the centrifugal force. Then the chromatographic separation is started by gradually reducing the AS concentration in the AS channel which lowers the AS gradient concentration in the water channel. This results in dissolution of deposited proteins which are again precipitated at an advanced critical point as they move through the channel. Consequently, proteins repeat precipitation and dissolution through a long channel and finally eluted out from the column in the order of their solubility in the AS solution. The present method has been successfully applied to a number of analytes including human serum proteins, recombinant ketosteroid isomerase, carotenoid cleavage enzymes, plasmid DNA, polysaccharide, polymerized pigments, PEG-protein conjugates, etc. The method is capable to single out the target species of proteins by affinity ligand or immunoaffinity separation.     

Analytical exclusion chromatography

This review summarizes the development of exclusion chromatography, also termed gel filtration, molecular-sieve chromatography and gel permeation chromatography, for the quantitative characterization of solutes and solute interactions. As well as affording a means of determining molecular mass and molecular mass distribution, the technique offers a convenient way of characterizing solute self-association and solute-ligand interactions in terms of reaction stoichiometry and equilibrium constant. The availability of molecular-sieve media with different selective porosities ensures that very little restriction is imposed on the size of solute amenable to study. Furthermore, access to a diverse array of assay procedures for monitoring the column eluate endows analytical exclusion chromatography with far greater flexibility than other techniques from the viewpoint of solute concentration range that can be examined. In addition to its widely recognized prowess as a means of solute separation and purification, exclusion chromatography thus also possesses considerable potential for investigating the functional roles of the purified solutes.     

Continuous annular chromatography

The principle of continuous annular chromatography (CAC) has been known for several decades. CAC is a continuous chromatographic mode, which lends itself to the separation of multi-component mixtures as well as of bi-component ones. In CAC, the mobile and stationary phases move in a crosscurrent fashion, which allows transformation of the typical one-dimensional batch column separation into a continuous two-dimensional one. With the exception of linear gradient elution, all chromatographic modes have at present been applied in CAC. This review focuses on the capacity of CAC for preparative bioseparation. The historical developments and the predecessors of modern CAC are briefly summarized. The state-of-the-art in the theoretical prediction and simulation of CAC separations is discussed, followed by an overview of current CAC instrumentation and example applications, especially for the isolation of proteins and other bio(macro)molecules. In this context, issues of scale up as well as method development and transfer from batch to continuous CAC columns are discussed using recent bioseparation efforts as pertinent examples.     

Scaling-up affinity chromatography

Recently in Trends in Biotechnology (Luong, J. T. et al., Vol. 5, 281–286), it was argued that affinity chromatography had disadvantages in productivity and operation and that other methods of exploiting affinity interactions needed to be developed. It has taken a long time for affinity methods to become accepted in biological processing, and it will take longer for new techniques to make a significant impact. In the meantime, affinity chromatography is being scaled up.     

Hydrophobic interaction chromatography

Hydrophobic interaction chromatography (HIC) is emerging as a useful technique for the separation of biological compounds. Advances in the past two years in HIC applications, stationary phases, eluents, and theory are reviewed. Recent applications of HIC processes include analytical and semi-preparative separations of a variety of proteins, such as isolectins, hemoglobins, calmodulin, and cardiotoxins. Additionally, HIC is being employed as a tool to investigate protein properties and mechanisms. Advances in HIC stationary phases include development of non-porous, microparticulate supports as well as supports with pore sizes up to 1000 Angstroms. Studies of HIC eluents have further shown the effects of mobile phase pH, water-structuring characterization, and surface tension increments on retention. Various retention mechanisms which have been presented are reviewed; and a correlation relating resolution to column and solute parameters is presented. Protein conformational effects at specific sites have been shown to have a significant impact on retention and specific examples illustrating such effects are discussed.     

Lectin affinity chromatography

A protocol is described for the preparation of lectin affinity chromatography columns using purified lectins and preactivated matrices. A general method is given for the purification of glycoproteins on immobilized Con A. Methods for immobilizing Con A on CDI agarose, Affi-Gel 15, and carbonyl-diimidazole-activated agarose are described.