The prediction of biological activity spectra for substances as an approach for searching compounds with complex mechanisms of action was studied. New compounds with dual mechanisms of antihypertensive action were found by this approach. Biological activity spectra for substances were predicted on the basis of their structural formulas by the computer program PASS. Thirty molecular mechanisms of action of compounds from the MDDR 99.2 database, which cause the antihypertensive effect and can be predicted by PASS, have been identified. The analysis of predictions for compounds with 15 dual antihypertensive mechanisms of action from the MDDR 99.2 database has confirmed high accuracy of prediction. This approach was applied to databases of commercially available compounds (AsInEx and ChemBridge) and allowed us to select four substances that are potential inhibitors of angiotensin converting enzyme (ACE) and of neutral endopeptidase (NEP). At a later time, all these compounds were found to be the inhibitors of both ACE and NEP. The most potent compounds had IC(50) of 10(-7)-10(-9) M for ACE and 10(-5) M for NEP. New combinations of dual mechanisms of action never before found for antihypertensive compounds were predicted.
Aspartyl and cysteine proteinases at distinct stages of carcinogenesis were analyzed in rat embryo fibroblasts, sequentially immortalized and transformed by 2 different genes: the early region of simian adenovirus SA7 and c-Ha-ras oncogene. The dynamics of expression and distribution of proteinases throughout the transformation process were examined. It was shown that in immortalized and transformed cells the activities of the aspartyl and cysteine proteinases were expressed to a variable degree and that the expression was dependent on cell-propagation time in vitro. The increase in activity both of cathepsin-D-like aspartyl proteinase and of cathepsin-L- and -B-like cysteine proteinases in cell lysates was correlated with the stages of fibroblast transformation (immortalization and tumorigenic transformation). In all cell types the major part of cysteine proteinases was localized inside the cell, while the cathepsin-D-like proteinase was apparently predominant among secreted proteinases. The cathepsin-L-like proteinase accounts for the major part of the cysteine-proteinase activity as measured by Z-Phe-Arg-MCA hydrolysis. We suggest that considerable portions of the cathepsin-D- and -L-like proteinases in all cell lines studied are secreted as a complex with inhibitor(s) and that inhibitor expression plays an important role in regulating the activity of cathepsin-D-like proteinase at different stages of transformation. Cathepsin-L-like proteinase is probably secreted in the precursor form.
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