1. New inhibitors of human renin that contain novel Leu-Val replacements
J R Luly, N Yi, J Soderquist, H Stein, J Cohen, T J Perun, J J Plattner J Med Chem. 1987 Sep;30(9):1609-16. doi: 10.1021/jm00392a015.
Stereoselective syntheses of several nonpeptide fragments that function as Leu10-Val11 scissile bond replacements in human angiotensinogen are presented. The opening of N-protected aminoalkyl epoxide 3 with a variety of sulfur, oxygen, nitrogen, and carbon nucleophiles is a key reaction in the preparation of these novel fragments 4-8. The coupling of these fragments to protected dipeptides that mimic positions 8 and 9 in angiotensinogen produces inhibitors of human renin even though the molecules contain no functionality beyond what is formally the Val11 side chain of angiotensinogen. R groups that closely resemble that of the Val side chain are preferable; thus, isopropyl greater than or equal to higher alkyl greater than phenyl greater than substituted phenyl. Sulfur is the best X group; oxidation leads to slight (X = SO2) and significant (X = SO) decreases in inhibitory potency. One such inhibitor, 60, has an IC50 of 13 nM when tested with purified human renin at pH 6.0. The significant activity of these small inhibitors is thought to be due in part to the hydroxyl group of the fragment functioning as a transition-state analogue. Of these, the inhibitors that contain histidine show marked selectivity toward renin over a related aspartic proteinase, pepsin.
2. Synthesis and renin inhibitory activity of angiotensinogen analogues having dehydrostatine, Leu psi [CH2S]Val, or Leu psi [CH2SO]Val at the P1-P1' cleavage site
C W Smith, H H Saneii, T K Sawyer, D T Pals, T A Scahill, B V Kamdar, J A Lawson J Med Chem. 1988 Jul;31(7):1377-82. doi: 10.1021/jm00402a022.
The synthesis and in vitro renin inhibitory potencies of angiotensinogen (ANG) analogues having amide (CONH) bond replacements at P1-P1', the Leu-Val cleavage site, corresponding to Leu psi[CH2SO]Val, and the trans olefinic analogue of statine (Sta), 4(S)-amino-6-methyl-2(E)-heptenoic acid (dehydrostatine, Dhs), are reported. These are compared to P1-P1' Leu psi[CH2NH]Val-, Sta-, or Phe-Phe-substituted analogues of the same template. The Dhs pseudodipeptide was found to be an adequate mimic of a trans CONH bond and gave a peptide, H-Pro-His-Pro-Phe-His-Dhs-Ile-His-D-Lys-OH, approximately equal in potency to a Phe-Phe-containing inhibitor, but 200-fold less potent than its Sta-substituted congener. That the enhanced potency of the Sta-containing peptide most likely depends on hydrogen bonding as well as tetrahedral geometry is indicated by the 50-100-fold lower potency of the tetrahedral Leu psi[CH2S]Val and Leu psi[CH2SO]Val analogues as compared to the Leu psi[CH2NH]Val-containing congener.
3. Design, structure-activity, and molecular modeling studies of potent renin inhibitory peptides having N-terminal Nin-For-Trp (Ftr): angiotensinogen congeners modified by P1-P1' Phe-Phe, Sta, Leu psi[CH(OH)CH2]Val or leu psi[CH2NH]Val substitutions
T K Sawyer, D T Pals, B Mao, D J Staples, A E de Vaux, L L Maggiora, J A Affholter, W Kati, D Duchamp, J B Hester J Med Chem. 1988 Jan;31(1):18-30. doi: 10.1021/jm00396a006.
A structure-conformation-activity investigation of several angiotensinogen (ANG) based inhibitors of human renin modified by either Phe-Phe, Sta, Leu psi[CH2NH]Val, or Leu psi[CH(OH)CH2]Val at the P1-P1' clevage site and P5 Trp(Nin-For) (Ftr) was performed. Specifically, Ac-Ftr-Pro-Phe-His-Phe-Phe-Val-Ftr-NH2 (1) provided a potent (KI = 2.7 X 10(-8) M) P1-P1' Phe-Phe substituted renin inhibitor to initiate these studies. Substitution of the P1-P1' Phe-Phe in compound 1 by Sta effected a 1,000-fold increase in biological potency for the resultant octapeptide Ac-Ftr-Pro-Phe-His-Sta-Val-Ftr-NH2 (10; KI = 6.7 X 10(-11) M). Kinetic analysis of compound 10 showed it to be a competitive inhibitor of human renin catalyzed proteolysis of human ANG. Chemical modifications of the compounds 1 and 10 were evaluated on the basis of comparative human plasma renin inhibitory activities (IC50 values) in vitro. Carboxy-terminal truncation studies on compound 10 showed that the P2' Val and P3' Ftr residues could both be eliminated without significant loss (ca. 10-fold) in renin inhibitory activity as exemplified by the pentapeptide Ac-Ftr-Pro-Phe-His-Sta-NH2 (12; IC50 = 3.8 X 10(-9) M). In addition, the corresponding P1-P1' Leu psi[CH(OH)CH2]Val and Leu psi[CH2NH]Val derivatives of compound 12 were potent renin inhibitors: Ac-Ftr-Pro-Phe-His-Leu psi[CH(OH)CH2]Val-NH2 (13; IC50 = 3.1 X 10(-10) M) and Ac-Ftr-Pro-Phe-His-Leu psi[CH2NH]Val-NH2 (14; IC50 = 2.1 X 10(-8) M). The structure-conformation-activity properties of the N-terminal Ftr substitution of these human renin inhibitors was examined by (1) comparative analysis of several analogues of 1 and Ac-Ftr-Pro-Phe-His-Sta-Ile-NH2 (17; IC50 = 1.0 X 10(-10) M) having P5 site modifications by Trp, His, D-Ftr, and D-His, (2) deletion of the N-terminal Ftr residue from compounds 12 and 17, to provide Ac-Pro-Phe-His-Sta-Ile-NH2 (16; IC50 = 3.1 X 10(-8) M) and Ac-Pro-Phe-His-Sta-NH2 (15; IC50 = 5.6 X 10(-6) M), and (3) computer modeling and dynamics studies of compounds 1 and 17 bound to CKH-RENIN, a simulated human renin model, which were focused on identifying potential intermolecular interactions of their common P5-P2 sequence, Ac-Ftr-Pro-Phe-His, at the enzyme active site.(ABSTRACT TRUNCATED AT 400 WORDS)
