Design of potent dicyclic (4-10/5-8) gonadotropin releasing hormone (GnRH) antagonists.

With the ultimate goal of identifying a consensus bioactive conformation of GnRH antagonists, the compatibility of a number of side chain to side chain bridges in bioactive analogues was systematically explored. In an earlier publication, cyclo[Asp(4)-Dpr(10)]GnRH antagonists with high potencies in vitro and in vivo had been identified.(1) Independently from Dutta et al. (2) and based on structural considerations, the cyclic [Glu(5)-Lys(8)] constraint was also found to be tolerated in GnRH antagonists. We describe here a large number of cyclic (4-10) and (5-8) and dicyclic (4-10/5-8) GnRH antagonists optimized for affinity to the rat GnRH receptor and in vivo antiovulatory potency. The most potent monocyclic analogues were cyclo(4-10)[Ac-DNal(1), DFpa(2),DTrp(3),Asp(4),DArg(6),Xaa(10)]GnRH with Xaa = D/LAgl (1, K(i) = 1.3 nM) or Dpr (2, K(i) = 0.36 nM), which completely blocked ovulation in cycling rats after sc administration of 2.5 microgram at noon of proestrus. Much less potent were the closely related analogues with Xaa = Dbu (3, K(i) = 10 nM) or cyclo(4-10)[Ac-DNal(1), DFpa(2),DTrp(3),Glu(4),DArg(6),D/LAgl(10)]GnRH (4, K(i) = 1.3 nM). Cyclo(5-8)[Ac-DNal(1),DCpa(2),DTrp(3),Glu(5),DArg++ +(6),Lys(8), DAla(10)]GnRH (13), although at least 20 times less potent in the AOA than 1 or 2 with similar GnRHR affinity (K(i) = 0.84 nM), was found to be one of the most potent in a series of closely related cyclo(5-8) analogues with different bridge lengths and bridgehead chirality. The very high affinity of cyclo(5,5'-8)[Ac-DNal(1), DCpa(2),DPal(3),Glu(5)(betaAla),DArg(6),(D or L)Agl,(8)DAla(10)]GnRH 14 (K(i) = 0.15 nM) correlates well with its high potency in vivo (full inhibition of ovulation at 25 microgram/rat). Dicyclo(4-10/5-8)[Ac-DNal(1),DCpa(2),DTrp(3),Asp (4),Glu(5),DArg(6), Lys(8),Dpr(10)]GnRH (24, K(i) = 0.32 nM) is one-fourth as potent as 1 or 2, in the AOA; this suggests that the introduction of the (4-10) bridge in 13, while having little effect on affinity, restores functional/conformational features favorable for stability and distribution. To further increase potency of dicyclic antagonists, the size and composition of the (5-8) bridge was varied. For example, the substitution of Xbb(5') by Gly (30, K(i) = 0.16 nM), Sar (31, K(i) = 0.20 nM), Phe (32, K(i) = 0.23 nM), DPhe (33, K(i) = 120 nM), Arg (36, K(i) = 0.20 nM), Nal (37, K(i) = 4.2 nM), His (38, K(i) = 0.10 nM), and Cpa (39, K(i) = 0.23 nM) in cyclo(4-10/5,5'-8)[Ac-DNal(1),DCpa(2),DPal(3),Asp(4),G lu(5)(Xbb(5')), DArg(6),Dbu,(8)Dpr(10)]GnRH yielded several very high affinity analogues that were 10, ca. 10, 4, >200, 1, ca. 4, >2, and 2 times less potent than 1 or 2, respectively. Other scaffolds constrained by disulfide (7, K(i) = 2.4 nM; and 8, K(i) = 450 nM), cyclo[Glu(5)-Aph(8)] (16, K(i) = 20 nM; and 17, K(i) = 0.28 nM), or cyclo[Asp(5)-/Glu(5)-/Asp(5)(Gly(5'))-Amp(8)] (19, K(i) = 1.3 nM; 22, K(i) = 3.3 nM; and 23, K(i) = 3.6 nM) bridges yielded analogues that were less potent in vivo and had a wide range of affinities. The effects on biological activity of substituting DCpa or DFpa at position 2, DPal or DTrp at position 3, and DArg, DNal, or DCit at position 6 are also discussed. Interestingly, monocyclo(5-8)[Glu(5), DNal(6),Lys(8)]GnRH (18, K(i) = 1. (ABSTRACT TRUNCATED)

Synthesis and theoretical conformational studies of gonadotropin-releasing hormone analogs containing tetrahydroisoquinoline carboxylic acid.

A series of analogs of gonadotropin-releasing hormone (GnRH) containing the conformationally restrictive residue tetrahydroisoquinoline carboxylic acid (Tic) or its non-restricted parent phenylalanine were synthesized and evaluated for anti-ovulatory activity in the rat. The series, based on the potent linear parent compound Ac-DNal1-DCpa2-DPal3- Ser4-Tyr5-DPal6-Leu7-Arg8-Pro9-DAla10-NH2, included L-Tic in positions 1, 2, 3, 7 and 9, D-Tic in positions 1, 2, 3, 6 and 9, or D-Phe in positions 2 and 3 for comparison. The most potent analog in this series, with D-Tic in position 6, fully inhibited ovulation at 2.5 micrograms compared to near complete inhibition at 0.5 microgram for the parent compound. A theoretical analysis of the conformational restrictions imposed on mainchain and sidechain torsional angles by the incorporation of Tic was conducted in vacuo using molecular mechanics techniques. Using cyclo(4-10)-[Ac-delta 3Pro1,DCpa2,DTrp3,Asp4,DNal6,Dpr10]- GnRH as a template conformer for which NMR conformational data is available, it was found that the potency of the different analogs correlated with the strain energy required to deform the mainchain and backbone angles of residues to values which would be expected if Tic were present and if the analog assumed the same solution structure. In particular, the effect of DTic at position 6 is to maintain the type II' beta-turn involving residues 5-8 found in active GnRH analogs.