Capillary Electrophoresis Analysis of Prostate-Specific Antigen (PSA).

The Capillary Electrophoresis (CE) profile of isoforms (peaks) of a glycoprotein can be useful to show alterations in its posttranslational modifications (PTMs) linked to diseases. These changes can modify the electrophoretic mobility of these isoforms in a minor extent and, therefore, very reproducible CE methods are needed to detect them. In this chapter, a method for the analysis of prostate-specific antigen (PSA) by Capillary Zone Electrophoresis (CZE) with UV detection is detailed. High reproducibility in the separation of a large number of PSA isoforms is achieved by performing capillary conditioning in acid media and by using a background electrolyte (BGE) at pH 8.0 formulated with decamethonium bromide and urea.

Sample preparation of serum to allow capillary electrophoresis analysis of prostate specific antigen isoforms.

Prostate cancer is the second most frequently diagnosed cancer in men worldwide. Currently prostate specific antigen (PSA) serum concentration is the most used prostate cancer marker, but it only shows limited specificity. Because PSA glycosylation is altered by prostate cancer, detecting glycosylation changes could increase PSA specificity as a prostate cancer marker. Changes in PSA glycosylation can modify its electrophoretic- behavior and techniques such as capillary zone electrophoresis (CZE) and two-dimensional electrophoresis (2-DE) could be applied to detect changes in PSA glycosylation. Most serum PSA is complexed with alpha-1 antichymotrypsin (ACT). To have access to most of the PSA, the complexed PSA has to be released as free PSA (fPSA); in addition, this total fPSA must be purified from the serum matrix so that it can be analyzed using CZE. In this work a methodology for isolating PSA from serum for its CZE analysis was established. By using PSA standard, the effect of this methodology, which combines conditions for dissociating complexed PSA and immunoaffinity chromatographic purification, was studied. It was seen that this highly repeatable sample treatment did not noticeably alter the circular dichroism (CD) spectrum or the CZE pattern of PSA standard. Therefore, as a proof-of-concept, the developed sample treatment was applied to serum from a cancer patient with a high PSA content. The following observations can be made from these experiments: first of all, the 2-DE pattern of serum PSA remained unchanged after sample treatment; second, as hypothesized, the established sample preparation methodology made it possible to obtain the CZE pattern of PSA from serum; and third, the CZE pattern of serum PSA and of PSA standard from seminal plasma of healthy individuals, both submitted to the sample treatment method, showed some differences regarding the proportion of CZE peaks of the glycoprotein. These differences could be related to possible changes in the linkages of peptide backbone, in glycosylation or in other post-translational modifications between samples from both origins.

Comparative analysis of prostate-specific antigen by two-dimensional gel electrophoresis and capillary electrophoresis.

Serum levels of Prostate-Specific Antigen (PSA) are not fully specific for prostate cancer (PCa) diagnosis and several efforts are focused on searching to improve PCa markers through the study of PSA subforms that could be cancer associated. We have previously reported by 2DE a decrease in the sialic acid content of PSA from PCa compared to benign prostatic hyperplasia patients based on the different proportion of the PSA spots. However, faster and more quantitative techniques, easier to automate than 2DE, are desirable. In this study, we examined the potential of CE for resolving PSA subforms in different samples and compared the results with those obtained by 2DE. We first fractionated by OFFGEL the subforms of PSA from seminal plasma according to their pIs and analyzed each separated fraction by 2DE and CE. We also analyzed PSA and high pI PSA, both from seminal plasma, and PSA from urine of a PCa patient. These samples with different PSA spots proportions by 2DE, due to different posttranslational modifications, also presented different CE profiles. This study shows that CE is a useful and complementary technique to 2DE for analyzing samples with different PSA subforms, which is of high clinical interest.

Impact of capillary conditioning and background electrolyte composition on capillary electrophoresis analysis of prostate specific antigen isoforms.

Glycoproteins expressed in the human body can experience modifications as result of pathological situations. Detection of those changes can be useful as disease biomarkers. As a result of these modifications, size and/or electrical charge of the glycoprotein can be altered. Migration in capillary zone electrophoresis (CZE) is governed by the size to charge ratio of the analyte and therefore this separation technique can be used to monitor those modifications. At its turn, the alteration of the electrophoretical pattern of a given glycoprotein could be used as disease biomarker. To this aim, high repeatability for separation of a large number of peaks for a given glycoprotein is desirable. For prostate cancer, new markers are needed to decrease the high number of false positive results provided by the biomarkers currently used in clinics. In this sense, CZE methods for analysis of the several prostate specific antigen (PSA) peaks which this glycoprotein exhibit, called isoforms and containing one or more glycoforms, could be useful to study the PSA pattern as prostate cancer marker. In this study two complementary strategies to achieve both lot-to-lot capillary repeatability and high resolution of a large number of PSA isoforms are developed. Better performance and precision have been obtained for capillaries conditioned with HCl than for those conditioned with NaOH. Optimization of the background electrolyte (BGE) pH value to 8.0 and inclusion of 3M urea on its composition were the two factors of highest impact for enhancing resolution of the highest number of PSA peaks. Under the optimized conditions for capillary conditioning and BGE pH and composition, long-term resolution of 10 isoforms of PSA was achieved. Inter-day (n=3) %RSD was 0.55 for the ratio tm/tEOF, 1.15 for µeff, and 5.02 for % Acorr of the PSA peaks.

Immunoaffinity chromatographic isolation of prostate-specific antigen from seminal plasma for capillary electrophoresis analysis of its isoforms.

Prostate-specific antigen (PSA) concentration in serum has been the biomarker employed for prostate cancer diagnosis in the last two decades. However, new more specific biomarkers allowing a better differentiation of cancer from non-malignant prostate diseases are necessary. Glycosylation of PSA gives rise to different forms of the protein which can be separated into several isoforms by analytical techniques, such as CE. Because PSA glycosylation is influenced by pathological conditions, the CE pattern of PSA isoforms could be different in prostate cancer than in non-malignant prostate diseases. To study this CE pattern of PSA, prior purification of the protein from the biological fluid is mandatory. In this study an immunoaffinity chromatography method which allows PSA purification without altering the CE pattern is developed. An in-house prepared column produced with commercial anti-PSA antibodies is employed. The use of 1 M propionic acid as elution agent provides higher than 40% recovery of high purity PSA. CE analysis of PSA immunopurified from seminal plasma of a healthy individual shows the same 8 peaks as the commercially available PSA standard. Sample preparation only requires dilution with phosphate buffered saline prior to immunoaffinity purification. High repeatability for the sample preparation step was achieved (RSD% for percentage of corrected peak area in the range 0.6-5.3 for CE analysis of three independently purified seminal plasma aliquots compared to range 0.8-4.9 for a given aliquot analyzed three times by CE). IAC of five microliters seminal plasma provided enough PSA to achieve signal/noise ratio larger than 5 for the smallest CE isoforms.