A truncated precursor form of prostate-specific antigen is a more specific serum marker of prostate cancer.

Prostate-specific antigen (PSA) is a widely used serum marker for prostate cancer (PCa) but has limited specificity for distinguishing early PCa from benign prostatic hyperplasia, because both PCa and benign prostatic hyperplasia release PSA into the serum. We have identified previously a truncated form of precursor PSA (pPSA) in prostate tumor extracts consisting of PSA with a serine-arginine pro leader peptide ([-2]pPSA) instead of the normally expressed 7 amino acid pro leader peptide. In the current study we developed monoclonal antibodies to detect [-2]pPSA and other isoforms of pPSA for Western blot analysis. PSA was immunoaffinity purified from 100 to 200 ml of serum from each of five men with biopsy-proven cancer and three biopsy-negative men, all with total PSA levels in the diagnostically relevant range near 10 ng/ml. The truncated [-2]pPSA was estimated to range from 25 to 95% of the free PSA in the five PCa samples but only 6-19% of the free PSA in the biopsy-negative men. Immunohistochemical studies showed positive staining for [-2]pPSA in PCa epithelium and that [-2]pPSA was enriched in cancer cell secretions. In vitro activation studies showed that human kallikrein 2 and trypsin readily activated full-length pPSA but were unable to activate [-2]pPSA to mature PSA. Thus, [-2]pPSA, once formed, is a stable but inactive isoform of PSA. Truncated [-2]pPSA may represent an important new diagnostic marker for the early detection of PCa.

Seminal plasma contains "BPSA," a molecular form of prostate-specific antigen that is associated with benign prostatic hyperplasia.

BACKGROUND: We previously reported that levels of BPSA, a modified form of prostate-specific antigen (PSA), are significantly elevated in prostate transition-zone tissue exhibiting nodular hyperplastic changes associated with the presence of benign prostatic hyperplasia (BPH). BPSA was purified and found to contain a characteristic clip between Lys182 and Ser183. We now describe the identification of BPSA in seminal plasma. METHODS: PSA was purified from seminal plasma by immunoaffinity chromatography. The purified PSA was further resolved by hydrophobic interaction chromatography, and the individual PSA forms were analyzed by gel electrophoresis and N-terminal amino-acid sequencing. RESULTS: BPSA comprised about 8% of the PSA in pooled seminal plasma, and was identical to BPSA purified from prostate tissues. BPSA was cleanly resolved from all active and inactive forms of PSA. Other inactive forms of PSA in seminal plasma consisted largely of PSA clipped at Lys145, though about 30% of the inactive seminal plasma PSA was intact, mature PSA. CONCLUSIONS: BPSA represents a distinct form of inactive PSA in the seminal plasma that may represent a specific marker for the biochemical changes associated with nodular development in the prostate transition zone found in patients with BPH.

A dual-monoclonal sandwich assay for prostate-specific membrane antigen: levels in tissues, seminal fluid and urine.

BACKGROUND: Prostate-specific membrane antigen (PSMA) is a 750-residue integral membrane glycoprotein and the target of an in-vivo imaging agent for metastatic prostate carcinoma (PCa). PSMA expression in normal and diseased prostatic tissues has previously been demonstrated by immunohistochemical techniques. In order to quantify PSMA levels in tissue homogenates and physiological fluids, we have developed a dual monoclonal antibody (mAb) sandwich assay which detects the antigen at a sensitivity <1 ng/mL and which is linear across the working range 0-50 ng/mL. METHODS: The assay involves capture of the PSMA by a biotinylated mAb (7E11) immobilized onto a streptavidin-coated microtiter plate; this mAb binds to the N-terminus of the antigen. The captured PSMA is detected by an Eu-labelled mAb (PEQ226) which binds in the region corresponding to Residues 134-437 of the antigen. PSMA was purified from LNCaP cells by immunoaffinity chromatography, and used as a calibrator, based on its concentration by the bicinchoninic acid (BCA) protein assay. RESULTS: The assay was applied to a panel of normal and tumor tissues. Levels were highest in the prostate tissues (292-4254 ng/mg protein). Low levels (21-51 ng/mL) were observed in membranes from ovary and breast, and neglible levels (1-10 ng/mg) in membranes from skin, liver, intestine, and kidney. Levels in the corresponding cytosol fractions were 20-to 50-fold lower. The average PSMA level in seminal fluid from 21 donors was 9, 012 ng/mL. On average, levels in normal-male urine (3.47 ng/mL) were ten-fold higher than in normal-female urine (0.3 ng/mL). CONCLUSIONS: This report is the first to describe absolute quantitation of PSMA in tissues and fluids. Congruent with earlier tissue studies based on immunohistochemical staining and Western-blot analysis, prostate tissue membranes expressed the highest levels of PSMA.

Identification of a novel complex between human kallikrein 2 and protease inhibitor-6 in prostate cancer tissue.

Human kallikrein (hK) 2 is an arginine-selective serine protease expressed predominantly in the prostate that has an 80% sequence identity with prostate-specific antigen. Expression of hK2 is elevated in the tumor epithelium compared to benign prostate tissue. We have purified, sequenced, and identified a novel hK2 complex in prostate tissue consisting of hK2 and a serine protease inhibitor known as protease inhibitor-6 (PI-6). This 64-kDa SDS-PAGE stable complex is elevated in the tumor and is approximately 10% of total hK2. No comparable complex of prostate-specific antigen was detected. PI-6, also known as cytoplasmic antiprotease, has been characterized as an intracellular inhibitor of trypsin and chymotrypsin-like proteases, which has high homology to plasminogen activator inhibitor 1 and 2. The physiological role of PI-6 in the prostate and its relationship to hK2 and prostate cancer are under investigation.

Ala217 is important for the catalytic function and autoactivation of prostate-specific human kallikrein 2.

Prostate-specific human kallikrein, hK2, is a serine protease found in prostate tissues that has 78% amino acid sequence identity with prostate-specific antigen (PSA). We have previously reported the affinity purification of hK2 heterologously expressed in a hamster cell line and demonstrated an arginine-restricted substrate specificity. Here, we describe the cloning, expression, purification, and enzymatic activity of a mutant form of hK2 containing an alanine to valine substitution at residue 217 ([Val217]hK2). This mutant form was secreted into the serum-free spent media of recombinant cells as the stable proenzyme form ([Val217]phK2). Mild trypsin treatment was used to convert [Val217]phK2 to the active form, which had reduced catalytic function compared to the wild-type hK2. Kinetic studies using the chromogenic substrate D-H-Pro-Phe-Arg-4-nitroanilide showed that [Val217]hK2 has significantly decreased substrate binding, with a K(m) of 4200 microM compared to 11 microM for wild-type hK2. The k(cat) for [Val217]hK2 was more than 100-fold lower than for hK2. hK2, but not [Val217]hK2, was able to activate [Val217]phK2. [Val217]hK2 also showed altered specificity on a synthetic peptide substrate compared to wild-type hK2, which exhibited partial hydrolysis at a PSA chymotrypsin-like cleavage site as well as the trypsin-like site cleaved by hK2. These results indicate that Ala217 is a key residue affecting the catalytic properties of hK2.