Jari Leinonen

Activation of Type IV Procollagenases by Human Tumor-associated Trypsin-2

Increased production of proteinases, such as matrix metalloproteinases (MMPs), is a characteristic feature of malignant tumors. Some human cancers and cell lines derived from them also express trypsinogen, but the function of the extrapancreatic trypsin has remained unclear. In this study we cloned and sequenced trypsinogen-2 cDNA from human COLO 205 colon carcinoma cells and characterized the ability of the enzyme to activate latent human type IV procollagenases (proMMP-2 and proMMP-9). As shown by cloning and N-terminal amino acid sequencing, the amino acid sequence of tumor-associated trypsin-2 is identical to that of pancreatic trypsin-2. We found that both pancreatic trypsin-2 and tumor cell-derived trypsin-2 are efficient activators of proMMP-9 and are capable of activating proMMP-9 at a molar ratio of 1:1000, the lowest reported so far. Human trypsin-2 was a more efficient activator than widely used bovine trypsin and converted the 92-kDa proMMP-9 to a single 77-kDa product that was not fragmented further. The single peptide bond cleaved by trypsin-2 in proMMP-9 was Arg87-Phe88. The generation of the 77-kDa species coincided with the increase in specific activity of MMP-9. In contrast, trypsin-2 only partially activated proMMP-2. Trypsin-2 cleaved the Arg99-Lys100 peptide bond of proMMP-2 generating 62–65-kDa MMP-2 species. Trypsin-2-induced proMMP-2 and -9 conversions were inhibited by tumor-associated trypsin inhibitor added either prior to or during activation indicating that proMMPs were not activated autocatalytically. Trypsin-2 also activated proMMPs associated with tissue inhibitor of matrix metalloproteinases, the complexes of which are thought to be the major MMP forms in vivo. The ability of human tumor cell-derived trypsin-2 to activate latent MMPs suggests a role for trypsin-2 in initiating the proteinase cascade that mediates tumor invasion and metastasis formation.

Complex Formation Between PSA Isoenzymes and Protease Inhibitors

PURPOSE We have studied complex formation between the isoenzymes of prostate specific antigen (PSA) and protease inhibitors in vitro. MATERIALS AND METHODS Ion exchange chromatography and hydrophobic interaction chromatography (HIC) were used for rapid separation of PSA isoenzymes from inhibitors and for characterization of the complex formation. Immunofluorometric assays (IFMA) specific for free PSA, the PSA-alpha 1-antichymotrypsin (PSA-ACT) complex and for both of these (total PSA) were used to measure various forms of PSA. Loss of free PSA immunoreactivity was used to estimate complex formation with alpha 2-macroglobulin (A2M) and ACT, which also was measured by PSA-ACT IFMA. RESULTS Complex formation between PSA and A2M was more rapid than with ACT. After extended incubation, about 75% of PSA reacted with ACT and 85% with A2M. When added to a mixture of ACT and A2M at concentrations corresponding to those in plasma, only 17% of PSA formed a complex with ACT while 17% remained free and 66% was undetectable, indicating complex formation with A2M. After extended incubation of PSA-ACT at 37C, a significant proportion of PSA was released as free active PSA. When A2M was included in the reaction mixture, the loss of PSA-ACT was not accompanied by appearance of free PSA, an indication that it complexed with A2M. Five to 18% of nicked PSA complexed with ACT whereas 54 to 67% reacted with A2M. CONCLUSIONS alpha 2-macroglobulin is the major inhibitor of PSA when it reached the circulation. Contrary to earlier assumptions, nicked PSA can bind to A2M rendering it inaccessible to antibodies.

Serum complex of trypsin 2 and alpha 1 antitrypsin as diagnostic and prognostic marker of acute pancreatitis: clinical study in consecutive patients.

Abstract Objective: To estimate the usefulness of serum concentrations of the complex of trypsin 2 and (alpha)1 antitrypsin in diagnosing and assessing the severity of acute pancreatitis in comparison with serum C reactive protein, amylase, and trypsinogen 2 concentrations (reference markers). Design: Markers were measured in consecutive patients admitted with acute abdominal pain that was either due to pancreatitis or to other disease unrelated to the pancreas (controls). Setting: Department of surgery of a teaching hospital in Helsinki. Subjects: 110 patients with acute pancreatitis and 66 with acute abdominal diseases of extrapancreatic origin. On the basis of the clinical course, acute pancreatitis was classified as mild (82 patients) or severe (28 patients). Main outcome measures: Clinical diagnosis of acute pancreatitis and severity of the disease. Results: At admission all patients with acute pancreatitis had clearly raised concentrations of trypsin 2-(alpha)1 antitrypsin complex (32 μg/l), whereas only three of the controls had such values. Of the markers studied, trypsin 2-(alpha)1 antitrypsin complex had the largest area under the receiver operating curve, both in differentiating acute pancreatitis from extrapancreatic disease and in differentiating mild from severe disease. Conclusions: Of the markers studied, trypsin 2-(alpha)1 antitrypsin complex was the most accurate in differentiating between acute pancreatitis and extrapancreatic disease and in predicting a severe course for acute pancreatitis. Key messages This complex can be accurately measured in a sensitive immunoassay In this study the diagnostic and prognostic accuracy of serum concentrations of trypsin 2-(alpha)1 antitrypsin complex was determined in acute pancreatitis The complex was more accurate than trypsinogen 2, C reactive protein, and amylase in differentiating between acute pancreatitis and extrapancreatic disease and in predicting a severe course for the disease If the immunoassay could be automated determination of concentrations of trypsin 2-(alpha)1 antitrypsin complex could greatly improve the diagnosis of this common and potentially lethal disease

Prostate-specific antigen forms a complex with and cleaves α1-protease inhibitor in vitro

Complexes between prostate‐specific antigen (PSA) and α1‐protease inhibitor (API) occur in serum and they are of potential interest in the diagnosis of prostate cancer. Pure PSA‐API complexes are needed for development of specific assays, but complex formation has not earlier been achieved in vitro.

Novel Peptide Inhibitors of Human Kallikrein 2

Human kallikrein 2 (hK2) is a serine protease produced by the secretory epithelial cells in the prostate. Because hK2 activates several factors participating in proteolytic cascades that may mediate metastasis of prostate cancer, modulation of the activity of hK2 is a potential way of preventing tumor growth and metastasis. Furthermore, specific ligands for hK2 are potentially useful for targeting and imaging of prostate cancer and for assay development. We have used enzymatically active recombinant hK2 captured by a monoclonal antibody exposing the active site of the enzyme to screen phage display peptide libraries. Using libraries expressing 10 or 11 amino acids long linear peptides, we identified six different peptides binding to hK2. Three of these were shown to be specific and efficient inhibitors of the enzymatic activity of hK2 toward a peptide substrate. Furthermore, the peptides inhibited the activation of the proform of prostate-specific antigen by hK2. Amino acid substitution analyses revealed that motifs of six amino acids were required for the inhibitory activity. These peptides are potentially useful for treatment and targeting of prostate cancer.

Dual-Label Immunoassay for Simultaneous Measurement of Prostate-specific Antigen (PSA)-α1-Antichymotrypsin Complex Together with Free or Total PSA

BACKGROUND A major portion of prostate-specific antigen exists in circulation as a complex with alpha(1)-antichymotrypsin (PSA-ACT), whereas a minor part is free (fPSA). The proportion of PSA-ACT is increased in prostate cancer (PCa), but immunologic determination of PSA-ACT is hampered by a background produced by nonspecific adsorption of ACT to the solid phase. To reduce the nonspecific interference, we produced an antibody specific for complexed ACT and developed immunofluorometric assays (IFMAs) for simultaneous measurement of fPSA + PSA-ACT (fPSA/PSA-ACT) and PSA-ACT + total PSA (tPSA, PSA-ACT/tPSA). METHODS Monoclonal antibodies (MAbs) were produced by immunization with PSA-ACT. The dual-label time-resolved IFMAs for fPSA/PSA-ACT and PSA-ACT/tPSA used a capture MAb to tPSA, an Eu(3+)-labeled MAb to fPSA or complexed ACT, and an Sm(3+)-labeled MAb to complexed ACT or to tPSA as tracer antibodies. The clinical utility was evaluated using serum samples from individuals with or without PCa with PSA concentrations of 2.0-20.0 micro g/L. RESULTS One MAb (1D10) showed low cross-reactivity with free ACT and cathepsin G-ACT. A sandwich assay for PSA-ACT with 1D10 as tracer had a detection limit of 0.05 micro g/L, and with this assay, PSA-ACT was undetectable in female sera. The detection limit for fPSA was 0.004 micro g/L. Determinations of the ratio of fPSA to PSA-ACT and the proportions of fPSA/tPSA and PSA-ACT/tPSA provided the same clinical specificity for PCa and provided significantly better clinical specificity than did tPSA. CONCLUSIONS Background problems observed in earlier PSA-ACT assays are eliminated by the use of a MAb specific for complexed ACT as a tracer. The same clinical validity can be obtained by determination of fPSA or PSA-ACT together or in combination with tPSA.

Prostate-specific antigen and other prostate cancer markers

P antigen (PSA) is the most important serum marker for prostate cancer. It is increasingly used for screening and early detection, although 65% to 75% of moderately elevated PSA results are caused by benign prostatic hyperplasia (BPH).1 Of the immunoreactive PSA in serum, 65% to 95% occurs in complex with alpha1antichymotrypsin (ACT), and measurement of the proportion of free or complexed PSA reduces the frequency of false-positive results by 20% to 30%.1–3 However, additional improvement is desirable and appears to be possible using some new markers. A few percent of PSA in serum is complexed to alpha1-protease inhibitor (API)4 and 2% to 30% with alpha2-macroglobulin (A2M).5 PSAAPI, PSA-A2M, and human kallikrein-2 (hK2)6,7 have provided promising results. In addition to these prostate-specific markers, insulin-like growth factor-1 (IGF-1)8 and vascular endothelial growth factors (VEGF)9 may provide information on prostate cancer risk. Efficient use of these new markers requires the use of statistical methods for calculation of the combined impact of multiple variables.

Standardization of PSA determinations.

Standardization of determinations for prostate specific antigen (PSA) has become an important issue due to the widespread use of these determinations for prostate cancer screening. Standardization of this assay is complicated due to the occurrence of two major forms of PSA in serum, the free antigen and a complex between PSA and alpha 1-antichymotrypsin (PSA-ACT). These two forms of PSA are recognized differently by different antibodies, but by careful selection of antibodies, it is possible to design methods that measure each form equally. It is suggested, that standards for PSA and PSA-ACT should be prepared and established as international standards. Furthermore, reference methods should be established on the basis that these standards and carefully selected reference antibodies.

Reactivity of 77 antibodies to prostate-specific antigen with isoenzymes and complexes of prostate-specific antigen.

Seventy-seven antibodies submitted to the ISOBM TD-3 PSA Workshop (TD-3.1 and TD-3.2) were characterized by measuring their reactivity with isoenzymes of free prostate-specific antigen (PSA), PSA complexed to α1-antichymotrypsin (PSA-ACT) and α1-proteinase inhibitor (PSA-API). Antibodies were classified into 15 distinct groups according to their reaction profiles with the various isoenzymes. Some antibodies recognizing both free and complexed PSA were inaccurate in measuring total PSA. Eight of the 9 free PSA-specific antibodies cross-reacted more with PSA-API than with PSA-ACT, while 1 antibody reacted less with PSA-API than PSA-ACT. From the panel of antibodies 39 reacted with both free and complexed PSA and were classified as total PSA antibodies.

Trypsinogen-1, -2 and tumour-associated trypsin-inhibitor in bile and biliary tract tissues from patients with biliary tract diseases and pancreatic carcinomas.

The bile concentrations of trypsinogen-1, -2 and tumour-associated trypsininhibitor (TATI) were determined in 23 patients with benign biliary tract disease, two with biliary tract cancer, and in 15 with pancreatic cancer. We also examined the trypsinogen and TATI expression by immunohistochemistry in tissue specimens from biliary tract cancer and non-neoplastic extrahepatic biliary tract. High levels of trypsinogen-1, trypsinogen-2, and TATI occur in bile of most patients. In contrast to the trypsinogens, the levels of TATI were significantly higher in patients with malignant disease than in those with benign diseases (p=0.04). There was no significant correlation between trypsinogen-2 and amylase (r= 0.13, p=0.40), indicating that the occurrence of trypsinogen in bile is not a result of reflux of pancreatic fluid into the bile duct. Immunohistochemically, trypsinogen-2 was detected in five and TATI in 12 out of 15 non-neoplastic biliary tract specimens, and in four and seven out of 11 cholangiocarcinomas, respectively. High concentrations of trypsinogen-1, trypsinogen-2 and TATI occur in the bile of patients with non-neoplastic and malignant biliary tract disease and in patients with pancreatic cancer. At least part of the trypsinogen-2 and TATI found in bile appears to be derived from the biliary epithelium itself.The bile concentrations of trypsinogen-1, -2 and tumour-associated trypsin-inhibitor (TATI) were determined in 23 patients with benign biliary tract disease, two with biliary tract cancer, and in 15 with pancreatic cancer. We also examined the trypsinogen and TATI expression by immunohistochemistry in tissue specimens from biliary tract cancer and non-neoplastic extrahepatic biliary tract. High levels of trypsinogen-1, trypsinogen-2, and TATI occur in bile of most patients. In contrast to the trypsinogens, the levels of TATI were significantly higher in patients with malignant disease than in those with benign diseases (p=0.04). There was no significant correlation between trypsinogen-2 and amylase (r=0.13, p=0.40), indicating that the occurrence of trypsinogen in bile is not a result of reflux of pancreatic fluid into the bile duct. Immunohistochemically, trypsinogen-2 was detected in five and TATI in 12 out of 15 non-neoplastic biliary tract specimens, and in four and seven out of 11 cholangiocarcinomas, respectively. High concentrations of trypsinogen-1, trypsinogen-2 and TATI occur in the bile of patients with non-neoplastic and malignant biliary tract disease and in patients with pancreatic cancer. At least part of the trypsinogen-2 and TATI found in bile appears to be derived from the biliary epithelium itself.