Potent and long-acting corticotropin releasing factor (CRF) receptor 2 selective peptide competitive antagonists

We present evidence that members of the corticotropin releasing factor (CRF) family assume distinct structures when interacting with the CRF(1) and CRF(2) receptors. Predictive methods, physicochemical measurements, and structure-activity relationship studies have suggested that CRF, its family members, and competitive antagonists such as astressin [cyclo(30-33)[DPhe(12),Nle(21),Glu(30),Lys(33),Nle(38)]hCRF((12-41))] assume an alpha-helical conformation when interacting with their receptors. We had shown that alpha-helical CRF((9-41)) and sauvagine showed some selectivity for CRF receptors other than that responsible for ACTH secretion(1) and later for CRF2.(2) More recently, we suggested the possibility of a helix-turn-helix motif around a turn encompassing residues 30-33(3) that would confer high affinity for both CRF(1) and CRF(2)(2,4) in agonists and antagonists of all members of the CRF family.(3) On the other hand, the substitutions that conferred ca. 100-fold CRF(2) selectivity to the antagonist antisauvagine-30 [[DPhe(11),His(12)]sauvagine((11-40))] did not confer such property to the corresponding N-terminally extended agonists. We find here that a Glu(32)-Lys(35) side chain to side chain covalent lactam constraint in hCRF and the corresponding Glu(31)-Lys(34) side chain to side chain covalent lactam constraint in sauvagine yield potent ligands that are selective for CRF(2). Additionally, we introduced deletions and substitutions known to increase duration of action to yield antagonists such as cyclo(31-34)[DPhe(11),His(12),C(alpha)MeLeu(13,39),Nle(17),Glu(31),Lys(34)]Ac-sauvagine((8-40)) (astressin(2)-B) with CRF(2) selectivities greater than 100-fold. CRF receptor autoradiography was performed in rat tissue known to express CRF(2) and CRF(1) in order to confirm that astressin(2)-B could indeed bind to established CRF(2) but not CRF(1) receptor-expressing tissues. Extended duration of action of astressin(2)-B vs that of antisauvagine-30 is demonstrated in the CRF(2)-mediated animal model whereby the inhibition of gastric emptying of a solid meal in mice by urocortin administered intraperitoneally at time zero is antagonized by the administration of astressin(2)-B but not by antisauvagine-30 at times -3 and -6 h while both peptides are effective when given 10 min before urocortin.     

Corticotropin releasing factor (CRF) agonists with reduced amide bonds and Ser7 substitutions

Strategies to generate competitive antagonists of bioactive peptides include several possible structural modifications such as the introduction of D-residues and of reduced amide bonds, the substitution of amino acid side chains, dimerization of fragments, and deletion of part of the sequence, among others. Whereas we have identified the two most likely residues responsible for receptor activation in corticotropin releasing factor (CRF) (Ser7 and Leu8)1 and generated potent antagonists by deleting residues 1-8,2,3 the question remained as to whether we could generate CRF antagonists with enhanced affinity after reduction of amide bonds at the N-terminus of CRF or through subtle alteration of those residues' side chains. Reduced amide bond replacements (psi[CH2NH]) between residues 6-9 in oCRF(5-41) (11, 12, 15) analogues consistently yielded potencies of <1% that of oCRF. Except for the 10psi11 and 12psi13 analogues 19 and 20, reduced amide bond replacements were generally well-tolerated in the longer hCRF(4-41) analogues, with the 7psi8-, 8psi9-, and 9psi10-modified peptides (13, 14, 18) yielding potencies that were 2-4 times that of hCRF. Although somewhat promising as agonists, they were, however, 3-7 times less potent than the parent [D-Pro4Nle21,38]-hCRF(4-41) (2). Since O-alkylation of Tyr3 in vasopressin yields an antagonist, and since Ser7 is one of the eight fully conserved residues in the CRF family (inclusive of sauvagine, urocortins, and urotensins) and likely to be critical for receptor binding, we synthesized cyclo(30-33)[Ser(OMe)7,D-Phe12,Nle21,Glu30,Lys33 ,Nle38]Ac-hCRF(7-41) (22), which was found to exhibit full efficacy and 40% of the potency of cyclo(30-33)[D-Phe12,Nle21,Glu30,Lys33, Nle38]Ac-hCRF(7-41) (5). Other substitutions at position 7 included aminoglycine (23, 24) and alkylated and/or acylated [alpha or alpha'-methyl (25-28), alpha'-formyl (29, 30), alpha'-formyl, alpha'-methyl (31), alpha'-acetyl (32), alpha'-acetyl, alpha'-methyl (33)], D- or L-aminoglycines. All analogues were active although less potent than the parent compound 2, and all elicited maximal ACTH response as compared to hCRF. The most potent analogue in this series (33) had the bulkiest side chain, Agl(Me, Ac), and was 60% and 80% as potent as the Ser7 analogue 5 and the Ala7 analogue 6, respectively. In conclusion, we found that neither reduction of the individual amide linkages between residues 6-11 and 12-13 nor introduction of a carbamide moiety in lieu of the side chain of Ser7 led to CRF antagonists.     

Stressin1-A, a potent corticotropin releasing factor receptor 1 (CRF1)-selective peptide agonist

The potencies and selectivity of peptide CRF antagonists is increased through structural constraints, suggesting that the resulting ligands assume distinct conformations when interacting with CRF1 and CRF2 receptors. To develop selective CRF receptor agonists, we have scanned the sequence -Gln-Ala-His-Ser-Asn-Arg- (residues 30-35 of [DPhe12,Nle21,38]Ac-hCRF4-41) with an i-(i+3) bridge consisting of the Glui-Xaa-Xbb-Lysi+3 scaffold, where residues i=30, 31, and 32. When i=31, stressin1-A, a potent CRF1 receptor-selective agonist was generated. In vitro, stressin1-A was equipotent to h/rCRF to release ACTH. Astressin1-A showed a low nanomolar affinity for CRF1 receptor (Ki=1.7 nM) and greater than 100-fold selectivity versus CRF2 receptor (Ki=222 nM). Stressin1-A released slightly less ACTH than oCRF in adult adrenal-intact male rats, with increased duration of action. Stressin1-A, injected intraperitoneally in rats, induced fecal pellet output (a CRF1 receptor-mediated response) and did not influence gastric emptying and blood pressure (CRF2 receptor-mediated responses).     

Influence of peptide CRF receptor antagonists upon the behavioural effects of human/rat CRF.

The effects of the corticotropin-releasing factor (CRF) receptor antagonists, alpha-helical CRF-(9-41), [D-Phe12,Nle21,38, CalphaMe-Leu37]humanCRF-(12-41) (D-PheCRF-(12-41)) and astressin ([cyclo(30-33)[D-Phe12,Nle21,38,Glu30,Lys33]h umanCRF-(12-41) upon hypophagic and motor activation response to human/ratCRF (h/rCRF) were investigated. All three antagonists (100 microg intracerebroventricular (i.c.v.)) blocked the effects of h/rCRF (1 microg i.c.v.) upon food intake and body weight change in food-deprived rats. In contrast, alpha-helical CRF-(9-41) and astressin (both at 100 microg i.c.v., but not lower doses), but not D-PheCRF-(12-41) (up to 100 microg i.c.v.), blocked h/rCRF (0.3 microg i.c.v.)-induced motor activation in rats in a familiar environment. The ability of D-PheCRF-(12-41) to block CRF-induced hypophagia, but not motor activation, suggests a selective action of this antagonist upon the behavioural effects of centrally administered h/rCRF.     

Design of monocyclic (1-3) and dicyclic (1-3/4-10) gonadotropin releasing hormone (GnRH) antagonists

Careful analysis of the NMR structures of cyclo(4-10)[Ac-Delta(3)Pro(1),DFpa(2),DTrp(3),Asp(4),DNal (6), Dpr(10)]GnRH, dicyclo(4-10/5-8)[Ac-DNal(1),DCpa(2),DTrp(3), Asp(4), Glu(5),DArg(6),Lys(8),Dpr(10)]GnRH, and dicyclo(4-10/5, 5'-8)[Ac-DNal(1),DCpa(2),DPal(3),Asp(4), Glu(5)(Gly),DArg(6),Dbu(8), Dpr(10)]GnRH showed that, in the N-terminal tripeptide, a type II beta-turn around residues 1 and 2 was probable along with a gamma-turn around DTrp(3)/DPal(3). This suggested the possibility of constraining the N-terminus by the introduction of a cyclo(1-3) scaffold. Optimization of ring size and composition led to the discovery of cyclo(1-3)[Ac-DAsp(1),DCpa(2),DLys(3),DNal(6), DAla(10)]GnRH (5, K(i) = 0.82 nM), cyclo(1,1'-3)[Ac-DAsp(1)(Gly), DCpa(2),DOrn(3),DNal(6),DAla(10)]GnRH (13, K(i) = 0.34 nM), cyclo(1, 1'-3)[Ac-DAsp(1)(Gly),DCpa(2),DLys(3),DNal(6),DA la(10)]GnRH (20, K(i) = 0.14 nM), and cyclo(1,1'-3)[Ac-DAsp(1)(betaAla), DCpa(2), DOrn(3),DNal(6),DAla(10)]GnRH (21, K(i) = 0.17 nM), which inhibited ovulation significantly at doses equal to or lower than 25 microgram/rat. These results were particularly unexpected in view of the critical role(s) originally ascribed to the side chains of residues 1 and 3.(1) Other closely related analogues, such as those where the [DAsp(1)(betaAla), DOrn(3)] cycle of 21 was changed to [DOrn(1)(betaAla), DAsp(3)] of cyclo(1,1'-3)[Ac-DOrn(1)(betaAla), DCpa(2),DAsp(3),DNal(6),DAla(10)]GnRH (22, K(i) = 2.2 nM) or where the size of the cycle was conserved and [DAsp(1)(betaAla), DOrn(3)] was replaced by [DGlu(1)(Gly), DOrn(3)] as in cyclo(1, 1'-3)[Ac-DGlu(1)(Gly),DCpa(2),DOrn(3),DNal(6),DA la(10)]GnRH (23, K(i) = 4.2 nM), were approximately 100 and 25 times less potent in vivo, respectively. Analogues with ring sizes of 18 ?cyclo(1, 1'-3)[Ac-DGlu(1)(Gly),DCpa(2),DLys(3),DNal(6),DA la(10)]GnRH (24)? and 19 ?cyclo(1,1'-3)[Ac-DGlu(1)(betaAla),DCpa(2),DLys( 3),DNal(6), DAla(10)]GnRH (25)? atoms were also less potent than 21 with slightly higher K(i) values (1.5 and 2.2 nM, respectively). These results suggested that the N-terminal tripeptide was likely to assume a folded conformation favoring the close proximity of the side chains of residues 1 and 3. The dicyclic analogue dicyclo(1-3/4-10)[Ac-DAsp(1),DCpa(2),DLys(3),Asp (4),DNal(6), Dpr(10)]GnRH (26) was fully active at 500 microgram, with a K(i) value of 1 nM. The in vivo potency of 26 was at least 10-fold less than that of monocyclic cyclo(1-3)[Ac-DAsp(1),DCpa(2),DLys(3),DNal(6), DAla(10)]GnRH (5); this suggested the existence of unfavorable interactions between the now optimized and constrained (1-3) and (4-10) cyclic moieties that must interact as originally hypothesized. Tricyclo(1-3/4-10/5-8)[Ac-DGlu(1),DCpa(2), DLys(3),Asp(4),Glu(5), DNal(6),Lys(8),Dpr(10)] GnRH (27) was inactive at 500 microgram/rat with a corresponding low affinity (K(i) = 4.6 nM) when compared to those of the most potent analogues (K(i) < 0.5 nM).     

Structure-activity relationship of neurokinin A(4-10) at the human tachykinin NK(2) receptor: the effect of amino acid substitutions on receptor affinity and function

A structure-activity study of the neurokinin A (NKA) fragment NKA(4-10) was performed to investigate the importance of amino acid residues for receptor efficacy, potency and affinity at the NK(2) receptor in human colon circular muscle. Fourteen analogs of NKA(4-10) were produced with substitutions at positions 4, 5, 7, 9 and/or 10 of NKA. Their potencies were determined by in vitro contractile responses and affinities by radioligand binding using [125I]NKA. Functional potency was enhanced 8-fold by single amino acid substitutions with Lys(5) and MeLeu(9) but not significantly altered by substitutions Glu(4), Arg(5), His(5) and Nle(10). The multiply-substituted analogs [MeLeu(9),Nle(10)]NKA(4-10), [Lys(5),MeLeu(9),Nle(10)]NKA(4-10) and [Lys(5),(Tyr(7)),MeLeu(9),Nle(10)]NKA(4-10) displayed 6-9-fold increase in potency. Although [Arg(5),Nle(10)]NKA(4-10) was similar in potency to NKA(4-10), it was the only analog to show significantly reduced efficacy. All analogs were able to compete fully for [125I]NKA binding. [Lys(5),MeLeu(9)]NKA(4-10), [MeLeu(9),Nle(10)]NKA(4-10), [Lys(5),Nle(10)]NKA(4-10) and analogs containing single substitutions with Glu(4), Arg(5), Lys(5) and MeLeu(9) displayed significantly higher affinity, whereas those with Nle(10) and [Glu(4),Nle(10)] substitutions showed significantly lower affinity than NKA(4-10). There was a positive correlation (r=0.63) between binding affinity and functional potency, which was markedly improved (r=0.95) by removal of three analogs: [Lys(5),MeLeu(9),Nle(10)]NKA(4-10), [Lys(5),Tyr(7),MeLeu(9),Nle(10)]NKA(4-10) and [Lys(5),Tyr(I(2))(7),MeLeu(9),Nle(10)]NKA(4-10). These exhibited similar binding affinities to that of NKA(4-10) but were more potent in functional studies, possibly indicating a different mechanism of receptor interaction. In conclusion, substitution of Ser(5) with Lys, and/or N-methylation of Leu(9), were the most effective changes to increase functional and binding potency of NKA(4-10) at the human colon NK(2) receptor.     

Design of potent dicyclic (1-5/4-10) gonadotropin releasing hormone (GnRH) antagonists

In three earlier papers, the structures and biological potencies of numerous mono- and dicyclic antagonists of GnRH were reported. Among these, two families, each containing two to four members were identified that had very high antagonist potencies in an antiovulatory assay (within a factor of 2 of those of the most potent linear analogues) and high affinities (K(i) < 0.5 nM) for the rat GnRH receptor (rGnRHR). The most favored cycles bridged the side chains of residues (4-10),(1,2) (5-8),(2) (4-10/5-8),(2) (1-3),(3) and (1-3/4-10).(3) Our goal was to identify a consensus model of bioactive conformations of GnRH antagonists, yet these biocompatible constraints did not sufficiently restrain the spatial location of the N-terminal tripeptide with respect to the C-terminal heptapeptide, due largely to the rotational freedom about the bonds connecting these regions. Examination of models derived from NMR studies of cyclo(4-10) analogues suggested a large number of possible cyclic constraints such as cyclo (0-8), (1-8), or (2-8). All analogues tested with these substitutions were inactive as antiovulatory agents at 1 mg/rat (5-9) and had low affinity for rGnRHR. On the other hand, bridging positions 3 and 8 with a [DAsp(3)] to [Dbu(8)] (12, K(i) = 13 nM) or [Orn(8)] (13, K(i) = 14 nM) in the parent compound cyclo(3-8)[Ac-DNal(1),DCpa(2),DXaa(3), Arg(5),DNal(6),Xbb(8),DAla(10)]GnRH yielded analogues that blocked ovulation at 250 microgram/rat. Analogue 14 (K(i) = 2.3 nM), with a [DAsp(3), Lys(8)] bridge, was fully active at 50 microgram/rat. Loss of potency (>20-fold) was observed with the substitution of [DAsp(3)] in 14 by [DGlu(3)] in 15 (K(i) = 23 nM). Dicyclic analogues possessing the (4-10) cycle and selected (1-6), (2-6), and (2-8) cycles led to analogues that were inactive at doses of 500 microgram/rat or larger. Two analogues with (1-8/4-10) cycles (16, K(i) = 1.1 nM) or (3-8/4-10) cycles (22, K(i) = 17 nM) showed full antiovulatory potency at 250 microgram/rat. None of these substitutions yielded analogues potent enough (>80% inhibition of ovulation at 5 microgram/rat or less and K(i) < 0.5 nM) to be candidates for structural analysis by NMR. On the other hand, four dicyclic (1, 1'-5/4-10) analogues met this criterion: dicyclo(1, 1'-5/4-10)[Ac-Asp(1)(Gly),DCpa(2),DTrp(3),Asp(4),Dbu(5 ), DNal(6), Dpr(10)]GnRH (32, K(i) = 0.22 nM), dicyclo(1, 1'-5/4-10)[Ac-Asp(1)(Gly),DCpa(2),DNal(3),Asp(4),Dbu(5 ), DNal(6), Dpr(10)]GnRH (34, K(i) = 0.38 nM), dicyclo(1, 1'-5/4-10)[Ac-Asp(1)(betaAla),DCpa(2), DTrp(3),Asp(4),Dbu(5),DNal(6), Dpr(10)]GnRH (40, K(i) = 0.15 nM), and dicyclo(1, 1'-5/4-10)[Ac-Glu(1)(Gly), DCpa(2),DTrp(3),Asp(4),Dbu(5),DNal(6), Dpr(10)]GnRH (41, K(i) = 0.24 nM). Since they differed slightly in terms of the (1,1'-5) bridge length (21 and 22 atoms) and bridgehead configuration, we may hypothesize that they assume similar bioactive conformations that satisfy a very discriminating receptor, since many other closely related analogues were significantly less potent.     

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)     

Behavioral effects of central administration of the novel CRF antagonist astressin in rats.

Astressin, a novel corticotropin releasing factor (CRF) antagonist, has been found to be particularly potent at inhibiting the hypothalamo-pituitary-adrenal axis. The aim of the present study was to determine the effects in rats of astressin in attenuating the anxiogenic-like response produced by social stress and intracerebroventricular (ICV) CRF administration on the elevated plus-maze, and ICV CRF-induced locomotor activation in the rat. Astressin significantly reversed the anxiogenic-like response induced by both social stress and ICV rat/humanCRF (r/hCRF) on the elevated plus-maze, but failed to block the effects of r/hCRF-induced locomotor activity in a familiar environment. When these results were compared to previous studies performed with the same paradigms using other CRF antagonists, astressin showed effects similar to those of D-PheCRF(12-41) on plus-maze performance. However, contrary to alpha-helicalCRF(9-41) and D-PheCRF(12-41), astressin had no effect on CRF-induced locomotor activity. These results suggest that astressin may have a unique anti-CRF profile compared to previously tested antagonists.     

Neurohypophyseal hormone receptors in the septum are implicated in social recognition in the rat

The effects on social recognition memory of (Arg(8))-vasopressin (AVP-(1-9), [pGlu(4), Cyt(6)]AVP-(4-8) and oxytocin locally administered into the rat's septum were investigated. In the behavioural paradigm used, a juvenile intruder was presented to an adult resident male rat twice for 5 min, with an inter-exposure interval of 120 min. Peptide-free residents investigated the juvenile during the second encounter as long as during the first encounter. Intraseptal injection just after the first encounter with graded doses of (Arg(8))-vasopressin, [pGlu(4),Cyt(6)]AVP-(4-8) or oxytocin caused a decrease of social investigation, as compared to placebo treatment, indicating facilitation of social recognition. The least effective dose was 100pg, 200pg and 300pg respectively. The action of vasopressin was blocked by both d(CH(2))(5)[Tyr(Me)(2)]AVP and d(CH(2))(5)[D-Ile(2)Ile(4)]AVP, V(1) and V(2) vasopressinergic receptor antagonists, but not by desGly(NH(2))(9)-d(CH(2))(5)[Tyr(Me)(2)Thr(4)]-OVT, an oxytocinergic receptor antagonist. None of the antagonists blocked the oxytocin-facilitating action on social recognition. They also did not affect social recognition when injected alone. The effects of vasopressin seem to be mediated by vasopressinergic receptors dissimilar to those found in the periphery, while the receptors involved in the action of oxytocin remain to be elucidated.     

Broad spectrum anti-RNA virus activities of titanium and vanadium substituted polyoxotungstates

Seven polyoxotungstates substituted with vanadium or titanium atoms were examined for their activity against Flaviviridae (Dengue fever virus, DFV), Orthomyxoviridae (influenza virus type A, fluV-A), Paramyxoviridae (respiratory syncytial virus, RSV, parainfluenza virus type 2, PfluV-2 and canine distemper virus, CDV) and Lentiviridae (human immunodeficiency virus type 1, HIV-1) families. Among the seven polyoxotungstates examined, PM-43 [K(5)[SiVW(11)O(40)]], PM-47 [K(7)[BVW(11)O(40)]], and PM-1001 [K(10)Na(VO)(3)(SbW(9)O(33))(2)]26H(2)O contained vanadium. PM-1002 had the same core structure of (VO)(3)(SbW(9)O(33))(2) as PM-1001; however, three V atoms of PM-1001 consisted of two V(IV) and one V(V) and those of PM-1002 consisted of three V(IV). On the other hand, PM-518 [[Et(2)NH(2)](7)[PTi(2)W(10)O(40)]], PM-520 [Pri(2)NH(2)](5)[PTiW(11)O(40)] and PM-523 [PriNH(3)](6)H[PTi(2)W(10)O(38)(O(2))(2)]H(2)O all contained titanium. All compounds showed broad spectrum antiviral activity against all viruses examined except for PMs-43, -518 and -523 which did not exhibit inhibitory activity at >/=50 microM against PfluV-2, CDV and DFV, respectively. All compounds were inhibitory against HIV replication at an EC(50) of less than 2.0 microM. Among them, PMs-1001 and -1002 showed the most potent inhibition. The compounds were not toxic for MDCK, HEp-2 and Vero cells at a concentration of 200 microM. For the exponentially growing MT-4 cells, the vanadium containing polyoxometalates (PMs-43, 47, 1001, 1002) showed toxicity at concentrations between 41 and 47 microM. On the other hand, titanium containing polyoxometalates (PMs-518, -520, -523) were not toxic at 100 microM. The mechanism of anti-HIV action of PM-1001 was analyzed: it affected the binding of HIV to the cell membrane and syncytium formation between HIV-infected and uninfected cells.     

A novel N-terminal cyclic dynorphin A analogue cyclo(N,5)[Trp(3),Trp(4),Glu(5)] dynorphin A-(1-11)NH(2) that lacks the basic N-terminus

A novel N-terminal-to-side chain cyclic dynorphin A analogue lacking the basic N-terminus was designed based on Ac[Lys(2),Trp(3),Trp(4),d-Ala(8)]dynorphin A-(1-11)NH(2) (Wan et al. J. Med. Chem. 1999, 42, 3011-3013). cyclo(N,5)[Trp(3),Trp(4),Glu(5)]dynorphin A-(1-11)NH(2) showed similar kappa opioid receptor affinity (K(i) = 27 nM) and selectivity (K(i) ratio (kappa/mu/delta) = 1/12/330) to the linear peptide and antagonized dynorphin A-(1-13)NH(2) at kappa opioid receptors. This is the first opioid peptide cyclized through the N-terminus that retains high opioid receptor affinity.     

Full agonists of CCK8 containing a nonhydrolyzable sulfated tyrosine residue

The sulfate ester of CCK26-33 or CCK8 (Asp-Tyr(SO3H)-Met-Gly-Trp-Met-Asp-Phe-NH2) borne by the tyrosine residue is a critical determinant of the biological activity of this peptide. In order to increase the stability of this molecule, the sulfated tyrosine has been replaced by a synthetic amino acid (L,D)Phe(p-CH2SO3Na) in which the OSO3H group was replaced by the nonhydrolyzable CH2SO3H group. Both isomers were separated by chromatography and the stereochemistry of the Phe(p-CH2SO3Na) residue in each peptide was established by NMR spectroscopy. The biological activities of the new derivatives Ac[X27, Nle28,Nle31]CCK27-33 were compared with those of Boc[Nle28,Nle31]CCK27-33, an equiactive analogue of CCK8 and Boc[D-Tyr(SO3Na)27,Nle28,Nle31]CCK27-33. Besides their highly enhanced chemical stability, Ac[L-Phe(p-CH2SO3Na)27,Nle28,Nle31]CCK27-33 and Ac[D-Phe(p-CH2SO3Na)27,Nle28,Nle31]CCK27-33 display high affinity for peripheral and central CCK receptors (KI congruent to 10(-9) M) and proved to be full agonists in the stimulation of pancreatic secretion as well as in the in vitro CCK8-induced contractions of the guinea pig ileum.     

Importance of the aromatic residue at position 6 of [Nle(10)]neurokinin A(4-10) for binding to the NK-2 receptor and receptor activation.

Steric and electrostatic requirements at position 6 of [Nle(10)]NKA(4-10), a full agonist of NK-2 receptors, for molecular recognition by the receptor were studied. Two series of peptide analogues, (a) p-substituted analogues, [p-X-Phe(6), Nle(10)]NKA(4-10), where X = F, Cl, Br, I, NH(2), NO(2), and (b) [D-Phe(6),Nle(10)]NKA(4-10), [Trp(6),Nle(10)]NKA(4-10), and [Chex-Ala(6),Nle(10)]NKA(4-10), were synthesized, and their biological activity was examined. Competition binding experiments with [(3)H]NKA were performed using cloned human NK-2 receptors expressed in CHO cells. Antagonistic and agonistic properties of the analogues were studied using an in vitro functional assay with hamster tracheal rings. The rank order of potency of agonists was [Nle(10)]NKA(4-10) approximately [p-F-Phe(6),Nle(10)]NKA(4-10) > [p-NH(2)-Phe(6),Nle(10)]NKA(4-10) > [p-Cl-Phe(6),Nle(10)]NKA(4-10) > [p-NO(2)-Phe(6),Nle(10)]NKA(4-10) > [Trp(6),Nle(10)]NKA(4-10). Size and planarity of the aromatic side chain were crucially important for the biological activity, whereas electron-donating and electron-withdrawing properties of the para-substituent were less important. The results favor the hypothesis that weakly polar pi-pi interactions exist between the aromatic group and the receptor.     

Identification of potent and selective neuropeptide Y Y(1) receptor agonists with orexigenic activity in vivo

Neuropeptide Y (NPY) binds to a family of G-protein coupled receptors termed Y(1), Y(2), Y(3), Y(4), Y(5), and y(6). The use of various receptor subtype-selective agonists and antagonists has facilitated identification of the receptor subtypes responsible for mediating many of the biological effects of NPY. For example, the potent orexigenic activity of NPY is believed to be mediated by both the Y(1) and Y(5) receptor subtypes. Several selective Y(5) receptor agonists that stimulate food intake in rodents are available, but no selective Y(1) receptor agonist has been reported. We have identified several NPY analogs that bind the NPY Y(1) receptor with high affinity and exhibit full agonist activity, measured as inhibition of forskolin-stimulated cAMP production in cells expressing the cloned NPY Y(1) receptor. [D-Arg(25)]-NPY, [D-His(26)]-NPY, Des-AA(10--17)[Cys(7,21),Pro(34)]-NPY, Des-AA(11--18)[Cys(7,21),D-Lys(9)(Ac)]-NPY, Des-AA(11--18)[Cys(7,21),D-Lys(9)(Ac),Pro(34)]-NPY, Des-AA(11--18)[Cys(7,21),D-Lys(9)(Ac),D-His(26)]-NPY and Des-AA(11--18)[Cys(7,21),D-Lys(9)(Ac),D-His(26), Pro(34)]-NPY bind the NPY Y(1) receptor with K(i) values of 0.9 +/- 0.2, 2.0 +/- 0.3, 0.2 +/- 0.05, 0.7 +/- 0.1, 0.2 +/- 0.01, 2.2 +/- 0.3, and 1.2 +/- 0.3 nM, respectively, and inhibit forskolin-stimulated cAMP production with EC(50) values of 0.2 +/- 0.02, 0.5 +/- 0.04, 0.3 +/- 0.03, 0.5 +/- 0.05, 0.4 +/- 0.16, 5.3 +/- 0.32, and 5.1 +/- 0.97 nM, respectively. These peptides are highly selective for the NPY Y(1) receptor relative to the NPY Y(2), Y(4), and Y(5) receptors. [D-Arg(25)]-NPY, [D-His(26)]-NPY and Des-AA(11--18)[Cys(7,21), D-Lys(9)(Ac),D-His(26),Pro(34)]-NPY stimulate food intake dose-responsively in Long-Evans rats for at least 4 h after intracerebroventricular administration. Although the involvement of Y(1) receptors in several physiological activities, such as vasoconstriction and anxiolysis, remains to be investigated, adequate tools are now available.     

Iterative approach to the discovery of novel degarelix analogues: substitutions at positions 3, 7, and 8. Part II

Degarelix (FE200486, Ac-d-2Nal(1)-d-4Cpa(2)-d-3Pal(3)-Ser(4)-4Aph(l-Hor)(5)-d-4Aph(Cbm)(6)-Leu(7)-ILys(8)-Pro(9)-d-Ala(10)-NH(2)) is a potent and very long acting antagonist of gonadotropin-releasing hormone (GnRH) after subcutaneous administration in mammals including humans. Analogues of degarelix were synthesized, characterized, and screened for the antagonism of GnRH-induced response in a reporter gene assay in HEK-293 cells expressing the human GnRH receptor. The duration of action was also determined in the castrated male rat assay to measure the extent (efficacy and duration of action) of inhibition of luteinizing hormone (LH) release. Structurally, this series of analogues has novel substitutions at positions 3, 7, and 8 and N(alpha)-methylation at positions 6, 7, and 8 in the structure of degarelix. These substitutions were designed to probe the spatial limitations of the receptor's cavity and to map the steric and ionic boundaries. Some functional groups were introduced that were hypothesized to influence the phamacokinetic properties of the analogues such as bioavailability, solubility, intra- or intermolecular hydrogen bond forming capacity, and ability to bind carrier proteins. Substitutions at positions 3 ([N(beta)-(2-pyridyl-methyl)d-Dap(3)]degarelix, IC(50) = 2.71 nM) (5), 7 ([Pra(7)]degarelix, IC(50) = 2.11 nM) (16), and 8 ([N(delta)-(IGly)Orn(8)]degarelix, IC(50) = 1.38 nM) (20) and N-methylation ([N(alpha)-methyl-Leu(7)]degarelix, IC(50) = 1.47 nM) (32) yielded analogues that were equipotent to degarelix (2) in vitro (IC(50) = 1.64 nM) but shorter acting in vivo. Out of the 33 novel analogues tested for the duration of action in this series, two analogues ([N(epsilon)-cyclohexyl-Lys(8)]degarelix, IC(50) = 1.50 nM) (23) and ([N(beta)-(IbetaAla)Dap(8)]degarelix, IC(50) = 1.98 nM) (26) had antagonist potencies and duration of action similar to that of azaline B {inhibited LH (>80%) release for >72 h after sc injection to castrated male rats at a standard dose of 50 mug/rat in 5% mannitol}. Under similar conditions analogues ([N(gamma)-(IGly)Dab(8)]degarelix, IC(50) = 1.56 nM) (21) and ([IOrn(8)]degarelix, IC(50) = 1.72 nM) (18) had a longer duration of action {inhibited LH (>96 h) release} than azaline B; however they were shorter acting than degarelix. Hydrophilicity of these analogues, a potential measure of their ability to be formulated for sustained release, was determined using RP-HPLC at neutral pH yielding analogues with shorter as well as longer retention times. No correlation was found between retention times and antagonist potency or duration of action.     

N-methylated analogs of Ac[Nle28,31]CCK(26-33): synthesis, activity, and receptor selectivity.

A series of singularly N-methylated analogs of Ac[Nle28,31]CCK(26-33) were synthesized by the solid-phase methodology, and their biological activity was tested in three different in vitro bioassays. The bioassays employed were the guinea pig gallbladder (GPGB), stomach (GPS), and ileum (GPI). All N-methyl analogs were agonists in all three bioassays. N-Methylation at either N- or C-terminals did not affect potency and selectivity, whereas N-methylation of internal residues [Nle28,(N-Me)Nle31]- and [Nle28,31,(N-Me)Trp30]CCK(26-33) in the sequence resulted in analogs which were 10-fold less potent than Ac[Nle28,31]CCK(26-33) in all three preparations. Different rank orders of potencies observed for [Nle28,31,Sar29]- and [Nle28,31,(N-Me)Asp32]CCK(26-33) analogs correspond to increased selectivity to either GPGB or GPS, respectively. We propose that systematic N-methylation of single amide bonds in a bioactive peptide should be conducted as an additional routine to probe structure-activity relationships.     

Antagonistic effects of human cyclic MBP(87-99) altered peptide ligands in experimental allergic encephalomyelitis and human T-cell proliferation.

The immunodominant myelin basic protein (MBP) peptide comprising residues 87-99 is a self-antigen in multiple sclerosis (MS). In Lewis rats this epitope induces experimental allergic encephalomyelitis (EAE), a demyelinating disease of the central nervous system, and is a model of MS. Structure-activity studies have shown that Lys(91) and Pro(96) residues are important for encephalitogenicity. Replacement of Lys and/or Pro residues with Arg and/or Ala, respectively, results in suppression of EAE. A potent linear altered peptide ligand of the immunodominant sequence MBP(83-99) has been selected for clinical trial (Nat. Med. 2000, 6, 1167, 1176). In the present report, two cyclic analogues, cyclo(91-99)[Ala(96)]MBP(87-99) and cyclo(87-99)[Arg(91), Ala(96)]MBP(87-99) were designed by NMR and molecular modeling data on human MBP(87-99) epitope (Val(87)-His-Phe-Phe-Lys-Asn-Ile-Val-Thr-Pro-Arg-Thr-Pro(99)) and its linear antagonist peptide analogue [Arg(91), Ala(96)]MBP(87-99). These analogues (altered peptide ligands) inhibited EAE in Lewis rats and decreased inflammation in the spinal cord. In addition, the analogue cyclo(87-99)[Arg(91), Ala(96)]MBP(87-99) induced proliferation of human peripheral blood T-cells. These cyclic MBP(87-99) peptide analogues may lead to the design of potent antagonist mimetics for treating MS.     

Respiratory actions of tachykinins in the nucleus of the solitary tract: effect of neonatal capsaicin pretreatment

1. The respiratory response to microinjection of capsaicin and tachykinin receptor agonists into the commissural nucleus of the solitary tract (cNTS) was investigated in adult, urethane-anaesthetized rats which had been pretreated with capsaicin (50 mg kg(-1) s.c.) or vehicle (10% Tween 80, 10% ethanol in saline) as day 2 neonates. 2. Microinjection of capsaicin (1 nmol) into the cNTS of vehicle-pretreated rats, significantly reduced respiratory frequency (59 breaths min(-1), preinjection control, 106 breaths min(-1)) without affecting tidal volume (VT). In capsaicin-pretreated rats, the capsaicin-induced bradypnoea was markedly attenuated (minimum frequency, 88 breaths min(-1); control, 106 breaths min(-1)). 3. In vehicle-pretreated rats, microinjection of substance P (SP, 33 pmol), neurokinin A (NKA, 33 pmol) and NKB (330 pmol), and the selective NK(1) tachykinin receptor agonists, [Sar(9), Met(O(2))(11)]-SP (33 pmol) and septide (10 pmol), increased VT (maxima, 3.60 - 3.93 ml kg(-1)) compared with preinjection control (2.82 ml kg(-1)), without affecting frequency. The selective NK(3) agonist senktide (10 pmol) also increased VT (3.93 ml kg(-1)) which was accompanied by a bradypnoea (-25 breaths min(-1)). The selective NK(2) agonist, [Nle(10)]-NKA(4-10) (330 pmol) increased VT slightly but significantly decreased frequency (-12 breaths min(-1)). In capsaicin-pretreated rats, VT responses to SP and [Sar(9), Met(O(2))(11)]-SP were increased whereas the response to septide was abolished. Both the VT and bradypnoeic responses to senktide and [Nle(10)]-NKA(4-10) were significantly enhanced. 4. These results show that neonatal capsaicin administration markedly reduces the respiratory response to microinjection of capsaicin into the cNTS. The destruction of capsaicin-sensitive afferents appears to sensitize the NTS to SP, NKB, [Sar(9),Met(O(2))(11)]-SP, senktide and [Nle(10)]-NKA(4-10). Moreover, the loss of septide responsiveness in capsaicin-pretreated rats, suggests that 'septide-sensitive' NK(1) receptors may be located on the central terminals of afferent neurons.     

Design and synthesis of a novel potent myelin basic protein epitope 87-99 cyclic analogue: enhanced stability and biological properties of mimics render them a potentially new class of immunomodulators

A cyclic analogue, [cyclo(87-99)MBP(87)(-)(99)], of the human immunodominant MBP(87)(-)(99) epitope, was designed based on ROESY/NMR distance information and modeling data for linear epitope 87-99, taking into account T-cell (Phe(89), Lys(91), Pro(96)) and HLA (His(88), Phe(90), Ile(93)) contact side-chain information. The cyclic analogue was found to induce experimental allergic encephalomyelitis (EAE), to bind HLA-DR4, and to increase CD4 T-cell line proliferation, like that of the conformationally related linear MBP(87)(-)(99) epitope peptide. The mutant cyclic peptides, the cyclo(91-99)[Ala(96)]MBP(87)(-)(99) and the cyclo(87-99)[Arg(91)Ala(96)]MBP(87)(-)(99), reported previously for suppressing, to a varying degree, autoimmune encephalomyelitis in a rat animal model, were found in this study to possess the following immunomodulatory properties: (i) they suppressed the proliferation of a CD4 T-cell line raised from a multiple sclerosis patient, (ii) they scored the best in vitro TH2/TH1 cytokine ratio in peripheral blood mononuclear cell cultures derived from 13 multiple sclerosis patients, inducing IL-10 selectively, and (iii) they bound to HLA-DR4, first to be reported for cyclic MBP peptides. In addition, cyclic peptides were found to be more stable to lysosomal enzymes and Cathepsin B, D, and H, compared to their linear counterparts. Taken together, these data render cyclic mimics as putative drugs for treating multiple sclerosis and potentially other Th1-mediated autoimmune diseases.