High-performance liquid chromatography of amino acids, peptides and proteins. XCVIII. The influence of different displacer salts on the bandwidth properties of proteins separated by gradient elution anion-exchange chromatography

Influence of temperature on the retention behaviour of proteins in cation-exchange chromatography

The chromatographic behaviour of several amino acid derivatives, peptides and proteins has been investigated with the so called "tentacle-type" LiChrospher-100 SO3- adsorbent and an analogous poly(2-sulphoethylaspartamide) cation-exchange adsorbent, PolySulphoethyl A. In particular, the dependences of the retention properties of a range of biosolutes on temperature and the chromatographic residence time were evaluated with the objective of gaining further insight into the influence of ligand type and flexibility and the role of solute conformation on the chromatographic behaviour of proteins with these two strong cation-exchange chromatographic adsorbents. The results indicate that significant differences in the chromatographic retention behavior between proteins and low-molecular-mass solutes occur as a function of temperature and the type of co- and counter ions present in the mobile phase with both adsorbents. Moreover, the dependences of the Zc and log Kc values on temperature for most of the proteins examined exhibited significant changes in magnitude between 4 and 75 degrees C, whilst no equivalent changes were evident for low-molecular-mass solutes. With the "tentacle-type" LiChrospher-1000 SO3- adsorbent at higher temperatures, e.g., at 75 degrees C, most of the proteins could still be eluted although several exhibited very large increases in their retention parameters. With the PolySulphoethyl A adsorbent, on the other hand, none of the proteins examined were eluted at 75 degrees C. The results moreover indicate that hydrophobic interactions play an increasingly important role in protein retention with both types of ion-exchange adsorbents at higher temperatures, but are more dominant with the PolySulphoethyl A ligand. In general, the Zc values for the proteins with the "tentacle-type" LiChrospher-1000 SO3- adsorbent were greater than those obtained with the PolySulphoethyl A adsorbent, suggesting that the "tentacular" ligands present on this strong cation-exchange adsorbent interact with protein molecules through larger contact areas. Collectively, these investigations provide further support for the concept that the adsorption behaviour of proteins with the "tentacle-type" LiChrospher-1000 SO3- adsorbent and similar types of "tentacular" ligand systems involves a multilayer dissolution mechanism with the protein interacting with a more diffuse or extended Donnan double layer in the ion-exchange environment, resulting in multi-site binding processes.

Utility of protein electrophoretic analysis in the characterization of malignant tissues

High-resolution electrophoresis of samples from malignant tissues and tumour cells has developed from a simple analytical tool to a high-tech system requiring a lot of satellite techniques. Though this developmental history now demands additional expensive instrumentation and a detailed knowledge of protein chemistry, the usefulness of this technique in tumour biology has been dramatically enhanced. Consequently, electrophoretic techniques combined with additional high-resolution and sensitive analytical tools can now be used to elucidate a particular phenotype of a cancer cell; moreover, the chemical nature of this phenotype can be revealed. The way from the protein backwards to the gene is now open!

High-performance liquid chromatography of amino acids, peptides and proteins. C. Characterisation of coulombic interactive regions on hen lysozyme by high-performance liquid anion-exchange chromatography and computer graphic analysis

The molecular characteristics of the dominant anion-exchange binding site of hen egg white lysozyme (HEWL) has been investigated using a combination of high-performance liquid chromatographic techniques and computer graphic analysis of the X-ray crystallographic structure. These studies have indicated that the site of highest electrostatic potential, in terms of the density of negatively charged amino acid side chains, is located around the catalytic cleft area. The four residues tentatively identified to be involved in the electrostatic binding domain were aspartic acid 48, 52, 101 and glutamic acid 35. The number of these charged groups correlated with the maximum value of the chromatographically determined retention parameter (Zc value). Variations in the range of experimental Zc values obtained under different elution conditions have been interpreted in terms of conformational flexibility of the structural domains of HEWL which result in the opening or closure of the catalytic cleft during the retention process.

High-performance liquid chromatography of amino acids, peptides and proteins. XCIX. Comparative study of the equilibrium refolding of bovine, porcine and human growth hormone by size-exclusion chromatography

The equilibrium refolding of bovine, porcine and human growth hormone and ovine prolactin in guanidine hydrochloride has been investigated using high-performance size-exclusion chromatography (HPSEC). It was found that bovine and porcine growth hormones exhibited very similar refolding behaviour. However, the renaturation of human growth hormone followed a different pathway. In particular, the folding transition of human growth hormone occurred at 4.7 M guanidine hydrochloride compared to 3.8 and 3.5 M for the bovine and porcine molecules, respectively, and 3.5 M for ovine prolactin. The refolding mechanism of an internally clipped fragment derived from partial tryptic digestion, exhibited similar folding properties to the corresponding intact molecule. The internally clipped analogue existed as a relatively larger molecule under fully denaturing conditions. Reduction followed by carboxymethylation resulted in growth hormone molecules with significantly reduced stability and altered folding properties. The results have been correlated with differences in structure to further demonstrate the utility of HPSEC in the study of protein folding and stability.