Lysyl oxidase is secreted from fibrogenic cells as a 50-kDa proenzyme that is proteolytically processed to the mature enzyme in the extracellular space. To characterize the secreted proteinase activity, a truncated, recombinant form of lysyl oxidase was prepared as a proteinase substrate containing the sequence of the propeptide cleavage region. The processing proteinase activity secreted by cultured fibrogenic cells resists inhibitors of serine or aspartyl proteinases as well as tissue inhibitor of matrix metalloproteinases-2 (MMP-2) but is completely inhibited by metal ion chelators. Known metalloproteinases were tested for their activity toward this substrate. Carboxyl-terminal procollagen proteinase (C-proteinase), MMP-2, and conditioned fibrogenic cell culture medium cleave the lysyl oxidase substrate to the size of the mature enzyme. The NH 2 -terminal sequence generated by arterial smooth muscle conditioned medium and the C-proteinase but not by MMP-2, i.e. Asp-Asp-Pro-Tyr, was identical to that previously identified in mature lysyl oxidase isolated from connective tissue. The C-proteinase activity against the model substrate was inhibited by a synthetic oligopeptide mimic of the cleavage sequence (Ac-Met-Val-GlyAsp-Asp-Pro-Tyr-Asn-amide), whereas this peptide also inhibited the generation of lysyl oxidase activity in the medium of fetal rat lung fibroblasts in culture. In toto, these results identify a secreted metalloproteinase activity participating in the activation of prolysyl oxidase, identify inhibitors of the processing activity, and implicate procollagen C-proteinase in this role.Lysyl oxidase (protein-lysine 6-oxidase, EC 1.4.3.13) is a copper-dependent amine oxidase that oxidatively deaminates the ⑀-amino group of specific peptidyl lysine and hydroxylysine residues of collagen and of lysine in elastin. The resultant peptidyl aldehydes can spontaneously condense with other vicinal peptidyl aldehydes or with unreacted ⑀-amino groups to form inter-and intramolecular cross-linkages stabilizing the fibrous forms of these connective tissue structural proteins (1). Evidence has been presented that the inhibition of lysyl oxidase action toward collagen molecules results in the accumulation and ultimate proteolytic degradation of soluble collagen monomers, thus preventing the formation of insoluble collagen fibers (2). The participation of this enzyme is critical, therefore, to the development and repair of structurally sound connective tissues as in the respiratory, cardiovascular, and skeletal systems of the body.Recent studies of the pathway by which lysyl oxidase is produced in arterial smooth muscle cells revealed that the protein is translated as a 46-kDa preproenzyme. Following signal peptide cleavage, the proenzyme undergoes N-glycosylation apparently within the propeptide region, and the resulting 50-kDa proenzyme is then secreted into the extracellular space. The secreted proenzyme is then proteolytically converted to the functional catalyst derived from the COOH-terminal sequence of the propr...
Highly miniaturized P450 screening assays designed to enable facile analysis of P450 drug interactions in a 1536-well plate format with the principal human cytochrome P450 enzymes (CYP3A4, 2D6, 2C9, 2C19, and 1A2) and Vivid ® fluorogenic substrates were developed. The detailed characterization of the assays included stability, homogeneity, and reproducibility of the recombinant P450 enzymes and the kinetic parameters of their reactions with Vivid ® fluorogenic substrates, with a focus on the specific characteristics of each component that enable screening in a low-volume 1536-well plate assay format. The screening assays were applied for the assessment of individual cytochrome P450 inhibition profiles with a panel of selected assay modifiers, including isozyme-specific substrates and inhibitors. IC 50 values obtained for the modifiers in 96-and 1536-well plate formats were similar and comparable with values obtained in assays with conventional substrates. An overall examination of the 1536-well assay statistics, such as signal-to-background ratio and Z′ factor, demonstrated that these assays are a robust, successful, and reliable tool to screen for cytochrome P450 metabolism and inhibition in an ultra-high-throughput screening format. (Journal of Biomolecular Screening 2005:56-66)
The DPX-2 cell line, a derivative of HepG2 cells, harbors human PXR and a luciferase-linked CYP3A4 promoter. These cells were used in a panel of cell-based assays for a parallel assessment of CYP3A4 induction, metabolism, and inhibition at the cellular level. CYP3A4 induction in the DPX-2 cell line by various agents was monitored in 96-well plates by a luciferase-based transcriptional activation assay. Of the prototypical CYP3A4 inducers examined, all exhibited elevated luciferase activity in DPX-2 cells. CYP3A4 enzyme activity in noninduced and rifampicin-induced DPX-2 cells was also assessed using Vivid fluorogenic substrates. Significantly elevated CYP3A4 activity levels (2.8-fold ± 0.2-fold above DMSO-treated cells) were found in DPX-2 cells after 48 hours of exposure to rifampicin, but were undetectable in parental HepG2 cells. Rifampicin-induced activity levels were found to be suitable for assessing the inhibitory potential of new chemical entities in downstream CYP3A4 inhibition assays. The elevated CYP3A4 activity was inhibited 85% by 10 µM ketoconazole. In addition, a cytotoxicity assay to correct for possible toxic effects of compounds at the cellular level was applied. The comparative data obtained with a combination of the above assays suggests that the application of several independent in vitro technologies used in DPX-2 cells is the best possible strategy for the assessment of the complex phenomena of CYP3A4 induction and inhibition.
Large-scale screening of multiple compound libraries and combinatorial libraries for pharmacological activity is one of the novel approaches of the modern drug discovery process. The application of isozyme-specific high-throughput screening (HTS) assays for characterizing the interactions of potential drug candidates with major human drug-metabolizing cytochrome p450 enzymes (p450s) is newly becoming an essential part of this process. Fluorescence-based HTS assays have been successfully employed for in vitro assessment of drug-drug interactions and enzyme inhibition with several p450 isoforms, including CYP3A4, CYP2D6, CYP2C9, and CYP2C19. Here we describe a fluorescence-based HTS assay for detecting drug metabolism and inhibition with human CYP2E1. CYP2E1 plays an important role in the metabolism of several drugs, many solvents, and toxins and therefore has been repeatedly linked to numerous pathologies, including cancer, liver and kidney toxicity, diabetes, and alcoholism. The assay is based on the ability of a drug to compete with the fluorogenic Vivid CYP2E1 Blue Substrate for CYP2E1 metabolism and thus enables rapid screening of lead molecules for their inhibitory potential. We have used this assay to screen a panel of drugs and compounds for their effects on CYP2E1 metabolism and inhibition. Our results demonstrate the assay's usefulness in identifying CYP2E1 substrates and inhibitors and in enabling in-depth characterization of their interactions with the CYP2E1 isozyme. We also present detailed characteristics of the assay, including its dynamic range and Z'-factor values, which indicate that this robust assay is well suited for kinetic and inhibition studies in HTS formats.
Development of high throughput screening (HTS) assays for evaluation of a compound's toxicity and potential for drug-drug interactions is a critical step towards production of better drug candidates and cost reduction in the drug development process. HTS assays for drug metabolism mediated by cytochrome P450s are now routinely used in compound library characterization and for computer modeling studies. However, development and application of HTS assays involving UDP-glucuronosyltransferases (UGTs) are lagging behind. Here we describe the development of a fluorescence-based HTS assay for UGT1A1 using recombinant enzyme and fluorescent substrate in the presence of an aqueous solution of PreserveX-QML (QBI Life Sciences, Madison, WI) polymeric micelles, acting as a stabilizer and a blocker of nonspecific interactions. The data include assay characteristics in 384-well plate format obtained with robotic liquid handling equipment and structures of hits (assay modifiers) obtained from the screening of a small molecule library at the University of Wisconsin HTS screening facility. The application of the assay for predicting UGT-related drug-drug interactions and building pharmacophore models, as well as the effects of polymeric micelles on the assay performance and compound promiscuity, is discussed.
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