CAS:2270-20-4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: CAS:2270-20-4 (5-phenylpentanoic acid)
26 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The synthesis of 10 analogues of pepstatin modified so that statine is replaced by 4-amino-3-hydroxy-3,6-dimethylheptanoic acid (Me3Sta) or 4-amino-3-hydroxy-3-methyl-5-phenylpentanoic acid (Me3AHPPA) residues is reported. Both the 3S,4S and 3R,4S diastereomers of each analogue were tested as inhibitors of the aspartic proteases, porcine pepsin, cathepsin D, and penicillopepsin. In all cases the 3R,4S diastereomer (rather than the 3S,4S diastereomer) of the Me3Sta and Me3AHPPA derivatives was found to be the more potent inhibitor of the aspartic protease (Ki = 1.5-10 nM for the best inhibitors), in contrast to the results obtained with statine (Sta) or AHPPA derivatives, where the 3S,4S diastereomer is the more potent inhibitor for each diastereomeric pair of analogues. The Me3Sta- and Me3AHPPA-containing analogues are only about 10-fold less potent than the corresponding statine and AHPPA analogues and 100-1000-fold more potent than the corresponding inhibitors lacking the C-3 hydroxyl group. Difference NMR spectroscopy indicates that the (3R,4S)-Me3Sta derivative induces conformational changes in porcine pepsin comparable to those induced by the binding of pepstatin and that the (3S,4S)-Me3Sta derivatives do not induce the difference NMR spectrum. These results require that the C-3 methylated analogues of statine-containing peptides must inhibit enzymes by a different mechanism than the corresponding statine peptides. It is proposed that pepstatin and (3S)-statine-containing peptides inhibit aspartic proteases by a collected-substrate inhibition mechanism. The enzyme-inhibitor complex is stabilized, relative to pepstatin analogues lacking the C-3 hydroxyl groups, by the favorable entropy derived when enzyme-bound water is returned to bulk solvent.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Inhibition of aspartic proteases by pepstatin and 3-methylstatine derivatives of pepstatin. Evidence for collected-substrate enzyme inhibition. 392 73

Plasmodium falciparum is a major causative agent of malaria, a disease of worldwide importance. Inhibition of a hemoglobin degrading P. falciparum aspartic protease Plasmepsin II (Plm II) provides a viable strategy for antimalarial therapy. Linear peptidic inhibitors based on the 4(S)-amino-3(S)-hydroxy-5-phenylpentanoic acid at the P1-P1' positions are known which inhibit Plm II with improved selectivity over cathepsin D. A series of computations were performed in order to gain insight into the interactions of these inhibitors with Plm II. The docking and molecular dynamics simulations were performed on a model ligand/enzyme complex to optimize the variables involved in the generation of ligand/enzyme models. This protocol of docking and molecular dynamics (MD) simulation was then used to derive the ligand-enzyme complexes of the molecules used in the present study. Different modes of binding of pepstatin and the three linear inhibitors were studied. Molecular dynamics simulation was performed at 300K for 100ps with a time step of Ifs. The structural effects of ligand binding were analyzed on the basis of hydrogen bond interactions, interaction energies, hydrophobic contacts and RMS deviations in the resulting energy-minimized structures of the receptor-ligand complexes. The results indicate that hydrophobic and hydrogen bonding interactions are responsible for selective inhibition of Plm II and improved selectivity over cathepsin D. Hydrogen bonding interaction plays an important role for amino acid residues such as Asp-34, Asp-214, Thr-217, Ser-218, Val-78, Ser-79, Tyr-192 and Gly-216. The binding of the inhibitors to the enzyme, while producing no large distortions in the enzyme active site cleft, results in significant RMS deviations of the inhibitor, which represent the distortion of the inhibitor, effected by the proteinase. Thus, the information generated from this analysis should be useful for further work in the area of antimalarial research.
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PMID:Molecular dynamics simulations of the three dimensional model of plasmepsin II-peptidic inhibitor complexes. 1176 33