Angiotensin II vs its type I antagonists: conformational requirements for receptor binding assessed from NMR spectroscopic and receptor docking experiments.

The conformations of three angiotensin II (AII) peptide antagonists ([Sar1]-AII(1-7)-NH(2), [Sar1,Val5,Ala8]-AII and the AII antipeptide, [Glu1,Gly2,Val5,Val8]-AII) were assessed in a lipid medium. A common backbone turn was identified through modeling and spectroscopic studies. The His6 residue acted as a pivoting point beyond which each peptide adopted two distinct conformations. One principle conformer resembled that previously determined for AII while the other was designated as an AII antagonist like conformer. A computational overlay between the nonpeptide antagonist, Losartan, and both the AII and the AII like conformation of [Sar1,Val5,Ala8]-AII revealed common pharmacophoric points with RMS deviations between 1 and 1.5 A. Both the AII conformer and the AII antagonist like conformer of [Sar1,Val5,Ala8]-AII were docked into a model of the AT(1) receptor. Receptor residue Phe289 and Asp281 provided good contact points for both peptides. Some differences were also noted. The terminal carboxyl of AII contacted Lys199 of the receptor while that of [Sar1,Val5,Ala8]-AII bridged Arg23 at the top of helix 1. The Asp1 side chain of AII interacted with His183 of the receptor.

P-113D, an antimicrobial peptide active against Pseudomonas aeruginosa, retains activity in the presence of sputum from cystic fibrosis patients.

Antimicrobial peptides are a source of novel agents that could be useful for treatment of the chronic lung infections that afflict cystic fibrosis (CF) patients. Efficacy depends on antimicrobial activity against the major pathogens of CF patients, Pseudomonas aeruginosa, Staphylococcus aureus, and Haemophilus influenzae, in the environment of the CF patient's airway. We describe the in vitro efficacies of derivatives of histatins, which are histidine-rich peptides produced by the salivary glands of humans and higher primates. P-113, a peptide containing 12 of the 24 amino acid residues of the parent molecule, histatin 5, retained full antibacterial activity and had a good spectrum of activity in vitro against the prominent pathogens of CF patients. However, P-113 was not active in the presence of purulent sputum from CF patients. In contrast, P-113D, the mirror-image peptide with the amino acid residues in the D configuration, was stable in sputum, was as active as P-113 against pathogens of CF patients in the absence of sputum and retained significant activity in the presence of sputum from CF patients. Recombinant human DNase, which effectively liquefies sputum, enhanced the activity of P-113D in undiluted sputum against both exogenous (added) bacteria and endogenous bacteria. Because of its properties, P-113D shows potential as an inhalant in chronic suppressive therapy for CF patients.

Anticandida activity is retained in P-113, a 12-amino-acid fragment of histatin 5.

Through the analysis of a series of 25 peptides composed of various portions of the histatin 5 sequence, we have identified P-113, a 12-amino-acid fragment of histatin 5, as the smallest fragment that retains anticandidal activity comparable to that of the parent compound. Amidation of the P-113 C terminus increased the anticandidal activity of P-113 approximately twofold. The three histidine residues could be exchanged for three hydrophobic residues, with the fragment retaining anticandidal activity. However, the change of two or more of the five basic (lysine and arginine) residues to uncharged residues resulted in a substantial loss of anticandidal activity. A synthetic D-amino-acid analogue, P-113D, was as active against Candida albicans as the L-amino-acid form. In vitro MIC tests in low-ionic-strength medium showed that P-113 has potent activity against Candida albicans, Candida glabrata, Candida parapsilosis, and Candida tropicalis. These results identify P-113 as a potential antimicrobial agent in the treatment of oral candidiasis.

An investigation of angiotensin II agonist and antagonist analogues with 5,5-dimethylthiazolidine-4-carboxylic acid and other constrained amino acids.

To probe the receptor-bound conformational requirements of angiotensin II (ANG II) octapeptide agonists and antagonists, the synthesis and biological activities of [Sar1]ANG II agonist and [Sar1,X8]ANG II antagonist analogues (X8 = Ile, D-Phe, or Aib) bearing conformational constraints in positions 3, 5, and 7 were investigated and compared with previous literature efforts. The conformational constraints that were examined include Pro, Dtc (5,5-dimethylthiazolidine-4-carboxylic acid), Aib, Cle, (NMe)Ala, (NMe)Ile, and the lactam modification, L,L-lactam-Phe, previously described by Freidinger et al. (J. Org. Chem. 1982, 47, 104-109). Both [Sar1,(NMe)Ala3 and Pro3]ANG II retained agonist activity, while only [Sar1,(NMe)Ala3,Ile8]ANG II retained antagonist activity. [Sar1,Dtc5]ANG II displayed superior agonist activity, while both [Sar1,Dtc5 and Cle5,Ile8] ANG II displayed superior antagonist activity. In contrast to position 5, Dtc7 substitution for Pro7 of either [Sar1]ANG II or [Sar1,Ile8]ANG II gave analogues with reduced activities. These results are consistent with the hypothesis that conformations of [Sar1]ANG II and [Sar1,Ile8]ANG II containing a C7 conformation in position 7 are preferred for both ANG II agonist and antagonist activity. Incorporation of the L,L-lactam-Phe modification into [Sar1]ANG II gives a pure ANG II antagonist (pA2 8.3), comparable to saralasin (pA2 8.6). In positions 3, 5, and 7 the conformational requirements for the ANG II agonist [Sar1]ANG II and the ANG II antagonist [Sar1,Ile8]ANG II may be different. Individual substitution of (NMe)Ala3, Dtc5, D-Phe8 and Aib8 [[Sar1,Aib8]ANG II: Khosla et al. J. Med. Chem. 1977, 20, 1051-1055] into [Sar1,Ile8]ANG II gives analogues that retain antagonist activity. Multiple substitutions of these types of residues into [Sar1,Ile8]ANG II gives analogue 45 [Sar1,(NMe)Ala3,Dtc5,Aib8]ANG II, 46 [Sar1(NMe)Ala3,D-Phe8]AII, and 47 [Sar1,Dtc5,D-Phe8]AII, which display considerably reduced antagonist activity. In ANG II antagonists the construction of highly constrained analogues may not be possible by the additive substitution of "preferred" constrained amino acids into a single analogue.

Synthesis and biological activity of angiotensin II analogues containing a Val-His replacement, Val psi[CH(CONH2)NH]His.

The dipeptide mimic Val psi[CH(CONH2)NH]His (4) was incorporated into angiotensin II (AII) analogues to provide an octapeptide saralasin derivative (29) as well as tetrapeptide analogue 19. Three C-terminal tetrapeptides (21, 25, and 28) were also prepared. All compounds were tested for their ability to displace 3H-AII from rabbit adrenal gland homogenate and as antagonists of AII and AI on guinea pig ileum. The octapeptide analogue 29 was 700 times less active than the parent peptide 30. All the C-terminal fragments 19, 21, 25, and 28 have no measurable AII antagonist activity. Of the four tetrapeptide fragments, only 21 showed any appreciable binding activity.

Some characteristics of specific angiotensin II binding sites on bovine brain microvessel endothelial cell monolayers.

Angiotensin II (Ang II) binding sites were characterized in primary cultures of bovine brain microvessel endothelial cell (BMEC) monolayers. Binding of [3H]Ang II to BMECs was time dependent and saturable. Scatchard plot analysis of dose-dependent [3H]Ang II binding revealed a single population of binding sites (Kd = 3.1 nM, Bmax = 52 fmoles/mg protein). Sarathrin, an Ang II antagonist, and saralsin, a partial agonist, inhibited [3H]Ang II binding to BMEC monolayers, whereas two unrelated peptides, bradykinin and arginine-vasopressin, had no effect on the specific binding of [3H]Ang II. At 37 degrees C, [3H]Ang II was internalized in BMECs and this uptake appeared to be saturable. Nanomolar concentrations of Ang II and saralasin stimulated [3H]thymidine uptake in serum-free starved BMEC monolayers, corresponding to an increase in DNA synthesis. On the other hand, sarathrin had no effect on [3H]thymidine uptake. The affinity of the single population of Ang II of binding sites was consistent with the concentration range of Ang II actions demonstrated in several cell types including BMECs. The Ang II-mediated actions on DNA synthesis suggest that this peptide-hormone may possess growth regulating properties in BMECs through either surface or internal site interactions. Collective findings support the complex nature of Ang II in regulating vascular and nonvascular cell growth and permeability characteristics.