Sylvain M. Cloutier scite author profile

The human KLK14 gene is one of the newly identified serine protease genes belonging to the human kallikrein family, which contains 15 members. KLK14 , like all other members of the human kallikrein family, is predicted to encode for a secreted serine protease already found in various biological fluids. This new kallikrein is mainly expressed in prostate and endocrine tissues, but its function is still unknown. Recent studies have demonstrated that KLK14 gene expression is up-regulated in prostate and breast cancer tissues, and that higher expression levels correlate with more aggressive tumors. In this work, we used phage-display substrate technology to study the substrate specificity of hK14. A phage-displayed random pentapeptide library with exhaustive diversity was screened with purified recombinant hK14. Highly specific and sensitive substrates were selected from the library. We show that hK14 has dual activity, trypsin- and chymotrypsin-like, with a preference for cleavage after arginine residues. A SwissProt database search with selected sequences identified six potential human protein substrates for hK14. Two of them, laminin alpha-5 and collagen IV, which are major components of the extracellular matrix, have been demonstrated to be hydrolyzed efficiently by hK14.

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Substrate specificity of human kallikrein 2 (hK2) as determined by phage display technology

Cloutier

Chagas

Mach

et al. 2002

European Journal of Biochemistry

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Human glandular kallikrein 2 (hK2) is a trypsin-like serine protease expressed predominantly in the prostate epithelium. Recently, hK2 has proven to be a useful marker that can be used in combination with prostate specific antigen for screening and diagnosis of prostate cancer. The cleavage by hK2 of certain substrates in the proteolytic cascade suggest that the kallikrein may be involved in prostate cancer development; however, there has been very little other progress toward its biochemical characterization or elucidation of its true physiological role. In the present work, we adapt phage substrate technology to study the substrate specificity of hK2. A phage-displayed random pentapeptide library with exhaustive diversity was generated and then screened with purified hK2. Phages displaying peptides susceptible to hK2 cleavage were amplified in eight rounds of selection and genes encoding substrates were transferred from the phage to a fluorescent system using cyan fluorescent protein (derived from green fluorescent protein) that enables rapid determination of specificity constants. This study shows that hK2 has a strict preference for Arg in the P1 position, which is further enhanced by a Ser in P¢1 position. The scissile bonds identified by phage display substrate selection correspond to those of the natural biological substrates of hK2, which include protein C inhibitor, semenogelins, and fibronectin. Moreover, three new putative hK2 protein substrates, shown elsewhere to be involved in the biology of the cancer, have been identified thus reinforcing the importance of hK2 in prostate cancer development.Keywords: cyan fluorescent protein; human kallikrein; phage display; prostate cancer; substrate.The human prostatic kallikreins hK3, or prostate specific antigen (PSA), is considered the gold standard for prostate cancer diagnosis and screening; however, hK2, the second prostatic kallikrein to be discovered [1], has recently emerged as a complementary marker for its positive correlation with prostate cancer grade and progression. PSA is more highly expressed in benign hyperplasia (BHP) than in cancer thus hK2 is helpful to further distinguish malignant from benign disease [2][3][4]. The recent discovery of 12 new members of the kallikrein family [5][6][7] could provide additional prostate cancer markers.In the seminal plasma, hK2 is mostly recovered complexed with protein C inhibitor [1]. Because hK2 cleaves, with trypsin-like specificity, certain components of the semen coagulum (fibronectin and semenogelins), it is possible that it has a role in the early stages of semen liquefaction, a biological process which immediately follows ejaculation [8]. In addition, in vitro studies have shown that hK2 can activate urokinase-type plasminogen activator [9] and inactivate plasminogen activator inhibitor-1 [10] leading to the activation of urokinase system. Moreover, hK2 degrades insulin-like growth factor binding proteins (IGF-BP) to release IGF, a putative local mitogenic signal for prostate cancer cells [11].Despi...

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Activation and enzymatic characterization of recombinant human kallikrein 8

Kishi

Cloutier²,

Kündig³

et al. 2006

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Human kallikrein 8 (hK8), whose gene was originally cloned as the human ortholog of a mouse brain protease, is known to be associated with diseases such as ovarian cancer and Alzheimer's disease. Recombinant human pro-kallikrein 8 was activated with lysyl endopeptidaseconjugated beads. Amino-terminal sequencing of the activated enzyme demonstrated the cleavage of a 9-aa propeptide from the pro-enzyme. The substrate specificity of activated hK8 was characterized using synthetic fluorescent substrates. hK8 showed trypsin-like specificity, as predicted from sequence analysis and enzymatic characterization of the mouse ortholog. All synthetic substrates tested containing either arginine or lysine at P1 position were cleaved by hK8. The highest k cat /K m value of 20=10 3 M -1 s -1 was observed with Boc-Val-Pro-Arg-7-amido-4-methylcoumarin. The activity of hK8 was inhibited by antipain, chymostatin, and leupeptin. The concentration for 50% inhibition by the best inhibitor, antipain, was 0.46 mM. The effect of different metal ions on the enzyme activity was analyzed. Whereas Na q had no effect on hK8 activity, Ni 2q and Zn 2q decreased the activity and Ca 2q , Mg 2q , and K q had a stimulatory effect. Ca 2q was the best activator, with an optimal concentration of approximately 10 mM.

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Evaluation of the CFP-substrate-YFP system for protease studies: advantages and limitations

et al. 2004

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A protease can be defined as an enzyme capable of hydrolyzing peptide bonds. Thus, characterization of a protease involves identification of target peptide sequences, measurement of activities toward these sequences, and determination of kinetic parameters. Biological protease substrates based on fluorescent protein pairs, which allow for use of fluorescence resonance energy transfer (FRET), have been recently developed for in vivo protease activity detection and represent a very interesting alternative to chemical substrates for in vitro protease characterization. Here, we analyze a FRET system consisting of cyan and yellow fluorescent proteins (CFP and YFP, respectively), which are fused by a peptide linker serving as protease substrate. Conditions for CFP-YFP fusion protein production in Escherichia coli and purification of proteins were optimized. FRET between CFP and YFP was found to be optimum at a pH between 5.5 and 10.0, at low concentrations of salt and a temperature superior to 25 degrees C. For efficient FRET to occur, the peptide linker between CFP and YFP can measure up to 25 amino acids. The CFP-substrate-YFP system demonstrated a high degree of resistance to nonspecific proteolysis, making it suitable for enzyme kinetic analysis. As with chemical substrates, substrate specificity of CFP-substrate-YFP proteins was tested towards different proteases and kcat/Km values were calculated.

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