Contamination-free and automated composition of a reaction mixture for nucleic acid amplification using a capillary electrophoresis apparatus.

The acceptance of the polymerase chain reaction (PCR) as an amplification method in molecular diagnostics and the rapid development of capillary electrophoresis (CE) as an analysis method of those PCR products was a reason for us to investigate further integration of those two techniques. Using a fused-silica capillary as a pipette we were able to compose a PCR mixture in the CE apparatus. Because a capillary can be thoroughly rinsed and the CE apparatus is a closed system, the risk of contamination and therefore the occurrence of false positive results is minimized. The fact that a CE system can be fully automated contributes to a more reproducible and standardized PCR composition protocol.

Application of free-solution capillary electrophoresis to the analytical scale separation of proteins and peptides.

The application of free solution capillary electrophoresis (FSCE) to the separation of protein and peptide mixtures is presented. Both qualitative and quantitative aspects of FSCE separations are considered. In addition, a brief introduction describing the separation principle behind FSCE separations and a discussion of electrophoretic mobility are included. The applications were chosen in order to highlight the selectivity of FSCE separations and to demonstrate applications of potential practical interest to the bioanalytical chemist. Comparison of FSCE relative to traditional analytical separation alternatives is stressed throughout. The examples are presented in three broad categories: protein separations, peptide separations, and the application of both to the analysis of recombinant protein products. In the first section, FSCE separations of peptide mixtures are presented which demonstrate the suitability of FSCE for the analysis of the purity of peptide samples, the homogeneity of peptide samples prior to sequencing, the identity of peptides by using electrophoretic mobility values, and the reduction of an intrachain disulfide bridge. In the second section, protein separations are presented that show the resolution of glycoproteins having the same primary structure and the separation of immune complexes from free unreacted antibody and antigen. In the final section, highly purified and well-characterized samples of biosynthetic human insulin (BHI), biosynthetic human growth hormone (hGH), and their derivatives were used to evaluate FSCE as a complement and/or alternative to conventional analytical separation techniques for the determination of purity and identity of biosynthetic human proteins. In addition, the quantitative aspects of FSCE analysis such as linearity of response, precision, and limit of detection were examined.

A semiempirical model for the electrophoretic mobilities of peptides in free-solution capillary electrophoresis.

In this study an attempt is made to explore the effect of a peptide's size, charge, and hydrophobicity on its electrophoretic mobility (mu) as measured by free-solution capillary electrophoresis with the aim of developing a semiempirical model which incorporates these effects. The effects of peptide size (which is measured by the number of amino acids in the polypeptide chain (n] and charge on mu are independently determined by experiment in a single solvent system and combined to give the relationship (formula; see text) where the constant 5.23 X 10(-4) is postulated to depend on the solvent system used. The form of Eq. [A.1] was confirmed, and the values of the constants 5.23 X 10(-4) and 2.47 X 10(-5) were determined, by measuring the electrophoretic mobilities of 40 peptides varying in size from 3 to 39 amino acids and varying in charge from 0.33 to 14.0. Furthermore, the effect of noncharged neutral amino acids on mobility was investigated and shown to be present, but only as a minor perturbation on the effects of size and charge.

Effect of buffer pH and peptide composition on the selectivity of peptide separations by capillary zone electrophoresis.

A series of 10 synthetic peptides containing varying degrees of charge and hydrophobicity was used to study the effects of peptide composition and buffer pH on the selectivity of separations by capillary zone electrophoresis (CZE). A simple model is used to explain the effect of buffer pH on the separation. It was found that pH is an important parameter affecting the selectivity of CZE separations. Furthermore, it is shown that the selectivity of the separation is such that peptides differing in neutral amino acid composition can be resolved, and that even differences in a peptide's amino acid sequence can be detected. A protease digest of beta-lactoglobulin A is shown as a practical example of a separation of a complex peptide mixture.