Inactivation of a serotonin-gated ion channel by a polypeptide toxin from marine snails.

The venom of predatory marine snails is a rich source of natural products that act on specific receptors and ion channels within the mammalian nervous system. A 41-amino acid peptide, final sigma-conotoxin GVIIIA, was purified on the basis of its ability to inactivate the 5-HT3 receptor, an excitatory serotonin-gated ion channel. final sigma-Conotoxin contains a brominated tryptophan residue, which may be important for peptide activity because the endogenous ligand for the 5-HT3 receptor is a hydroxylated derivative of tryptophan. final sigma-Conotoxin inactivates the 5-HT3 receptor through competitive antagonism and is a highly selective inhibitor of this receptor. Serotonin receptors can now be included among the molecular targets of natural polypeptide neurotoxins.

BRCA1 is phosphorylated at serine 1497 in vivo at a cyclin-dependent kinase 2 phosphorylation site.

BRCA1 is a cell cycle-regulated nuclear protein that is phosphorylated mainly on serine and to a lesser extent on threonine residues. Changes in phosphorylation occur in response to cell cycle progression and DNA damage. Specifically, BRCA1 undergoes hyperphosphorylation during late G1 and S phases of the cell cycle. Here we report that BRCA1 is phosphorylated in vivo at serine 1497 (S1497), which is part of a cyclin-dependent kinase (CDK) consensus site. S1497 can be phosphorylated in vitro by CDK2-cyclin A or E. BRCA1 coimmunoprecipitates with an endogenous serine-threonine protein kinase activity that phosphorylates S1497 in vitro. This cellular kinase activity is sensitive to transfection of a dominant negative form of CDK2 as well as the application of the CDK inhibitors p21 and butyrolactone I but not p16. Furthermore, BRCA1 coimmunoprecipitates with CDK2 and cyclin A. These results suggest that the endogenous kinase activity is composed of CDK2-cyclin complexes, at least in part, concordant with the G1/S-specific increase in BRCA1 phosphorylation.

The effect of Plasmodium falciparum infection on expression of monocyte surface molecules.

Plasmodium falciparum infection may result in severe malaria in susceptible individuals. The pathogenesis of severe disease is probably a combination of the sequestration of infected erythrocytes and overstimulation of the immune response. Monocytes are a key source of many of the pro-inflammatory agents implicated but also are found sequestered in blood vessels. However, little is known about the monocyte phenotype in malaria disease. Flow cytometry was performed on fresh whole blood to determine surface expression of four receptors during acute severe and non-severe malaria and again during convalescence when uninfected. Three hundred and fifty-six children with P. falciparum infection were studied and were found to show increased expression of intercellular adhesion molecule-1 (ICAM-1), urokinase plasminogen activator receptor (uPAR), CD23 and chemokine receptor 5 (CCR5) (P<0.001) during acute disease compared with convalescent levels. Using multivariate analysis, it was found that large increases in expression of ICAM-1 (odds ratio (OR) 2.44, 95% CI 1.80-3.32) and uPAR (OR 3.14, 95% CI 1.93-5.09) but small increases in expression of CD23 (OR 0.82, 95% CI 0.68-0.96) were independently associated with severe malaria. These results give an insight into the cellular processes occurring in severe malaria and suggest that pathology is based on a complex repertoire of pro- and anti-inflammatory processes.

Primary structure of a novel gonadotropin-releasing hormone in the brain of a teleost, Pejerrey.

The neuropeptide GnRH is the major regulator of reproduction in vertebrates acting as a first signal from the hypothalamus to pituitary gonadotropes. Three GnRH molecular variants were detected in the brain of a fish, pejerrey (Odontesthes bonariensis), using chromatographic and immunological methods. The present study shows that one form is identical to chicken GnRH-II (sequence analysis and mass spectrometry) and the second one is immunologically and chromatographically similar to salmon GnRH. The third form was proven to be a novel form of GnRH by isolating the peptide from the brain and determining its primary structure by chemical sequencing and mass spectrometry. The sequence of the novel pejerrey GnRH is pGlu-His-Trp-Ser-Phe-Gly-Leu-Ser-Pro-Gly-NH(2), which is different from the known forms of the vertebrate and protochordate GnRH family. The new form of GnRH is biologically active in releasing gonadotropin and GH from pituitary cells in an in vitro assay.

Primary structure and function of three gonadotropin-releasing hormones, including a novel form, from an ancient teleost, herring.

The evolution of GnRH and the role of multiple forms within the brain are examined. Three forms of GnRH were purified from the brain of Pacific herring (Clupea harengus pallasi) and characterized using Edman degradation and mass spectrometry. Two forms correspond with the known structures of chicken GnRH-II and salmon GnRH that are found in many vertebrate species. The third form, designated herring GnRH (hrGnRH), has a primary structure of pGlu-His-Trp-Ser-His-Gly-Leu-Ser-Pro-Gly-NH2. This novel peptide is a potent stimulator of gonadotropin II and GH release from dispersed fish pituitary cells. The content of hrGnRH in the pituitary was 8-fold that of salmon GnRH and 43-fold that of chicken GnRH-II, which provides supporting evidence that hrGnRH is involved in the release of gonadotropin. Herring is the most phylogenetically ancient animal in which three forms of GnRH have been isolated and sequenced. Our evidence suggests that the existence of three GnRHs in the brain of one species 1) is an ancestral condition for teleosts, 2) has the potential for separate regulation of the distinct GnRHs, and 3) may be an evolutionary advantage for refined control of reproduction in different environments.

Sequence of two gonadotropin releasing hormones from tunicate suggest an important role of conformation in receptor activation.

The primary structure of two forms of gonadotropin releasing hormone (GnRH) from tunicate (Chelyosoma productum) have been determined based on mass spectrometric and chemical sequence analyses. The peptides, tunicate GnRH-I and -II, contain features unprecedented in vertebrate GnRH. Tunicate GnRH-I contains a putative salt bridge between Asp5 and Lys8. A GnRH analog containing a lactam bridge between Asp5 and Lys8 was found to increase release of estradiol compared with that of the native tunicate GnRH-I and -II. Tunicate GnRH-II contains a cysteine residue and was isolated as a dimeric peptide. These motifs suggest that the conformation plays an important role in receptor activation.

Analysis of adhesive domains from the A4VAR Plasmodium falciparum erythrocyte membrane protein-1 identifies a CD36 binding domain.

The A4VAR is a variant antigen expressed by a clonal line that binds CD36 and intercellular adhesion molecule-1, ICAM-1. We have cloned and sequenced the extracellular domain coded by the A4var gene. To probe the relationship between A4var expression and parasite adhesion to ICAM-1, var mRNA and protein expression were analyzed in an enriched population of A4 parasites that displayed higher ICAM-1 binding. By Northern analyses, A4var was the predominant var message and antisera raised against a recombinant A4VAR protein reacted with the majority of infected erythrocytes, reinforcing previous conclusions that A4VAR binds ICAM-1. A4VAR contains five Duffy-binding like (DBL) domains, and two cysteine-rich interdomain regions (CIDR) domains. DBL and CIDR domains from A4VAR were expressed in mammalian cells to determine which regions mediate binding to CD36 and ICAM-1. Using several different binding assays, the A4VAR CIDR1 was the only domain found to bind CD36. In contrast, the same assays were unable to identify the ICAM-1 binding domain in A4VAR. This is the first time that each of the DBL and CIDR domains from a Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1) have been systematically expressed and tested for binding. These results confirm that CIDR1 is sufficient to bind CD36 without any apparent contribution from other domains.

Current status of the Plasmodium falciparum genome project.

The Plasmodium falciparum Genome Project is a collaborative effort by many laboratories that will provide detailed molecular information about the parasite, which may be used for developing practical control measures. Initial goals are to prepare an electronically indexed clone bank containing partially sequenced clones representing up to 80% of the parasite's genes and to prepare an ordered set of overlapping clones spanning each of the parasite's 14 chromosomes. Currently, clones of genomic DNA, prepared as yeast artificial chromosomes, are arranged into contigs covering approximately 70% of the genome of parasite clone 3D7, gene sequence tags are available from more than contigs covering approximately 70% of the genome of parasite clone 3D7, gene sequence tags are available from more than 20% of the parasite's genes, and approximately 5% of the parasite's genes are tentatively identified from similarity searches of entries in the international sequence databases. A total of > 0.5 Mb of P. falciparum sequence tag data is available. The gene sequence tags are presently being used to complete YAC contig assembly and localize the cloned genes to positions on the physical map in preparation for sequencing the genome. Routes of access to project information and services are described.

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.

Conformationally restricted competitive antagonists of human/rat corticotropin-releasing factor.

Corticotropin releasing factor (CRF) is a 41-peptide amide which stimulates the release of ACTH (Vale et al. Science 1981, 213, 1394). CRF has been postulated to assume an alpha-helical conformation upon binding to its pituitary receptor (Hernandez et al. J. Med. Chem. 1993, 36, 2860). We have exploited this hypothesis in the design of a limited series of cyclic analogues and have taken into consideration the effects of side-chain deletion (Alanine scan, Kornreich et al. J. Med. Chem. 1992, 35, 1870) as well as of changes in chirality (Rivier et al. J. Med. Chem. 1993, 36, 2851), with the rationale that side chains necessary for binding could also be replaced by side-chain bridges. In particular, we have used computer modeling to predict likely side chain bridging opportunities and evaluated the effects of such replacements by correlating biological results with those derived from CD spectroscopy. We have synthesized 38 monocyclic peptide amides, competitive antagonists of human/rat CRF, using solid-phase methodology on MBHA resin. After purification by preparative RP-HPLC, the peptides were analyzed by RP-HPLC and capillary zone electrophoresis and characterized by mass spectroscopy and amino acid analysis. CRF antagonists were tested for their ability to interfere with CRF-induced release of ACTH by rat anterior pituitary cells. In most cases, one of the bridge heads was located at a position where substitution by a D-residue was tolerated (i.e., positions 12 and 20). It has become clear that careful optimization of bridge length and chirality is critical. This is best exemplified by the fact that out of the 38 analogues that were synthesized and tested, only two, [cyclo(20-23)[DPhe12,Glu20,Lys23, Nle21,38]h/rCRF12-41 and cyclo(20-23)[DPhe12,Glu20,Orn23,Nle21,38] h/rCRF12-41], were found to be more potent (3 and 2 times, respectively) than [DPhe12,Nle21,38]h/rCRF12-41, the parent compound. Six analogues belonging to two different families were found to be half as potent as the standard, 18 had 2-20% of the potency of the standard, and the others were significantly less potent. CD results of all analogues in 50% TFE (a concentration of TFE that induced nearly maximum helicity of [DPhe12,Nle21,38]h/rCRF12-41) suggest that while helicity may be an important factor for CRF analogue recognition, little correlation is found between percent helicity as determined by spectral deconvolution and biological activity in vitro.

Single point D-substituted corticotropin-releasing factor analogues: effects on potency and physicochemical characteristics.

In an attempt to determine which conformational parameters are important for the biological activity of ovine corticotropin-releasing factor (oCRF), we have synthesized in significant amounts (50-200 mg) and characterized chemically, structurally (CD), and biologically, oCRF analogues with substitution of each amino acid by its corresponding D-isomer. Out of 37 of these analogues, three were found to be equipotent to, or twice as potent as, oCRF, 13 had potencies in the range from 10 to 60%, 17 had potencies ranging from 1 to 10%, and the four others had potencies less than 0.5%. None of the analogues antagonized oCRF-induced release of ACTH in vitro at concentrations > or = 1000 oCRF. Since antagonists to CRF action can be generated by deletion of the first 8-14 residues, a series of CRF antagonists which exhibit significantly higher in vitro and in vivo biological potency than [Met18,Lys23,Glu27,29,40,Ala32,41,-Leu33,3 6,38] h/rCRF, [alpha-helical-CRF9-41], is also described. [D-Phe12,Nle21,38,Arg36]h/rCRF, in particular, was found to be ca. 15 times more potent than alpha-helical-CRF9-41 in vitro. In the rat, however, this analogue was about as effective as alpha-helical-CRF9-41 in blocking CRF-induced decrease in mean arterial blood pressure and increase in heart rate. Its potency in blocking epinephrine release by CRF was not significantly different from that of alpha-helical-CRF9-41. In the adrenalectomized rat, [Lys36]alpha-helical-CRF(9-41) (1.7 mg/kg) blunted the effect of endogenous CRF over a 90-min period; by comparison, a similar dose of alpha-helical-CRF9-41 was effective for less than 1 h.

Defining structural requirements for neuropeptide Y receptors using truncated and conformationally restricted analogues.

To further elucidate the minimum bioactive conformation of neuropeptide Y (NPY), a series of truncated and conformationally constrained analogues has been prepared. The synthesis and purification of these peptides was achieved using routine laboratory strategies and techniques. Parent molecules consisted of the native NPY N-terminal 1-4 and C-terminal 25-36 segments, having the residue 5-24 core replaced by either a single flexible omega-aminoalkanoic acid, or a more rigid Pro-Gly or Pro-DAla sequence which was expected to constrain a putative turn, and allow the N- and C-termini to align. Cross-linking between residues 2 and 27 through lactamization using side-chain length and chirality suggested by computer simulations, resulted in cyclo-(2/27)-des-AA7-24[Glu2,Gly6,DDpr27]NPY that exhibited very high affinity (Ki = 0.3 versus 0.3 nM for NPY) for the Y2 receptor using SK-N-BE2 human neuroblastoma cells, yet very low affinity for the Y1 receptor using SK-N-MC human neuroblastoma cells (Ki = 130 versus 2.0 nM for NPY). The added constraint resulting from bridging in this analogue as well as in others suggested that the combination of the deletion of residues 5-24 and the introduction of an internal ring produced exclusive selectivity for the Y2 receptor with little or no loss of affinity. The tolerance of structural recognition was further demonstrated as a second ring was introduced which was expected to constrain the amphiphilic alpha-helix, resulting in the full Y2 agonist dicyclo (2/27,28/32)-des-AA7-24 [Glu2,32,DAla6,DDpr27,Lys28]NPY. Improvement of Y1 binding activity was achieved only by including more residues (des-AA10-17) in the central PP-fold region, while allowing limited flexibility of the termini. Although the length of the bridge seemed to have little effect on binding potency, changes in the location of and chirality at the bridgehead resulted in analogues with different binding affinities. Combination of optimum structural modifications resulted in cyclo-(7/21)-des-AA10-18[Cys7,21]NPY, an analogue shortened by 25% but retaining comparable binding properties to that of native NPY at Y1 and Y2 receptor types (Ki = 5.1 and 1.3 nM, respectively).

Gonadotropin-releasing hormone antagonists: novel members of the azaline B family.

A series of antagonists of gonadotropin-releasing hormone (GnRH) homologous to azaline B ([Ac-DNal1,DCpa2,DPal3,Aph5(Atz),DAph6+ ++(Atz),ILys8,DAla10]GnRH) was synthesized, characterized, and tested in a rat antiovulatory assay (AOA). Selected analogues were also tested in both an in vitro dispersed rat pituitary cell culture assay for inhibition of GnRH-stimulated luteinizing hormone release and an in vitro histamine release assay. The duration of action of some of the most potent and safest analogues in those assays was also determined in the castrated male rat in order to measure the extent (efficacy and duration of action) of inhibition of luteinizing hormone release. Structurally, this series of analogues has novel substitutions (X and Y) in the structure of the azaline B precursor: [Ac-DNal1,DCpa2,DPal3,-Aph5(X),DAph6(Y),++ +ILys8,DAla10]GnRH. These substitutions were designed to confer increased hydrophilicity as compared to that of azaline B (determined by relative retention times on a C18 reverse phase column using a triethylammonium phosphate buffer at pH 7.3) or to make them more easily accessible synthetically. Some bulky substituents were introduced in order to probe the spatial limitations of the receptor's cavity. These substitutions include acylated 4-aminophenylalanine at positions 5 and/or 6 (29 analogues), N alpha-methylated backbone substitutions (six analogues), N omega-isopropylaminophenylalanine at position 8, and hydrophilic amino acids at position 1. Out of 20 novel analogues tested for long duration of action in this series, only seven ([Ac-DNal1,DCpa2,DPal3,Aph5,DAph6,ILys8 ,DAla10]GnRH, [Ac-DNal1,DCpa2,DPal3,Aph5(For),DAph6(For) ,ILys8,DAla10]GnRH, [Ac-DNal1,DCpa2,DPal3,Aph5(Ac),DAph6(Ac),- ILys8,DAla10]GnRH (acyline), [Ac-DNal1,DCpa2,DPal3,Aph5(Pio),DAph6++ +(Pio),ILys8,DAla10]GnRH, [Ac-DNal1,DCpa2,DPal3,Aph5(Atz),DAph6++ +(Ac),ILys8,DAla10]GnRH, [Ac-DNalDCpa2,DPal3,Aph5(Atz-beta Ala),DAph6(Atz-beta Ala),ILys8, DAla10]GnRH, [Ac-DNal1,DCpa2,DPal3,Aph5(Atz-Gab), DAph6(Atz-Gab),ILys8,DAla10]GnRH) had relative potencies and/or duration of action comparable to those of azaline B. The others were one-half to one-tenth as effective as azaline B. N alpha-Methylated backbone substitutions at position 5 yielded analogues that were significantly more hydrophilic presumably because of the breakage of the NH alpha-Tyr5 to Arg8-CO hydrogen bond reported to stabilize a beta-turn encompassing residues 5-8 and which favored beta-sheet formation as shown earlier by Haviv et al. This substitution resulted, however, in an increased potency in the histamine release assay and in significantly shorter duration of action. Similarly, attempts at replacing isopropyllysine in position 8 by either isopropyl-4-aminophenylalanine or isopropyl-4-(aminomethyl)phenylalanine resulted in loss of potency in the AOA. Changes in chirality at position 1 or 10 resulted in analogues that were one-tenth and one-half as potent, respectively, as acyline.(ABSTRACT TRUNCATED AT 400 WORDS)

Gonadotropin-releasing hormone antagonists with N omega-triazolylornithine, -lysine, or -p-aminophenylalanine residues at positions 5 and 6.

In order to be used as fertility regulators in humans, gonadotropin releasing hormone (GnRH) antagonists must be extremely potent and long acting and exhibit negligible side effects such as stimulating histamine release. To this aim, we have recently synthesized a series of analogues with the standard Ac-DNal1-DCpa2-DPal3 substitutions, where the N omega-amino function of ornithine, lysine, or p-aminophenylalanine (Aph) was converted to the aminotriazolyl (atz) derivatives at positions 5 and 6 with further modifications at positions 7 and 10. The analogues were tested for their ability to bind to pituitary cell membranes, to release histamine in a mast cell assay, to inhibit luteinizing hormone (LH) secretion by castrated male rats or cultured pituitary cells, and to interfere with the ovulation in intact female rats. While the subcutaneous (sc) injection of 50 micrograms of Azaline A (7, [Ac-DNal1,DCpa2,DPal3,Lys5(atz),DLys6++ +(atz),ILys8,DAla10]GnRH) dissolved in 0.2 mL of an aqueous media significantly inhibited LH release in the castrated male rat for 24 h, the same dose of Azaline B (11), [Ac-DNal1,DCpa2,DPal3,Aph5(atz),DAph6++ +(atz),ILys8,DAla10]GnRH, inhibited LH release for 72 h. A similar long duration of action was observed for Antide ([Ac-DNal1,DCpa2,DPal3,Lys5(Nic),DLys6(Nic ),ILys8,DAla10]GnRH) but not for Nal-Glu ([Ac-DNal1,DCpa2,DPal3,Arg5,4-(pmethoxybenzoy l)-D-2-Abu6,DAla10]GnRH). In the same paradigm, a 5-fold dilution of the peptide (50 micrograms in 1 mL) and the use of three injection sites rather than one resulted in significantly shorter duration of action for most of the peptides tested. This suggested that long duration of action might be the result of slow release from the injection site(s). In order to investigate this possibility, Nal-Glu and Azaline B were injected intravenously (i.v.) at three doses (10, 50, 250 micrograms) to castrated male rats. At all doses, both peptides significantly lowered LH levels for 8 h. By 24 h, Nal-Glu (250 micrograms) and Azaline B (50 and 250 micrograms) still measurably inhibited LH secretion. Finally, only Azaline B (250 micrograms) was still active at 48 h. These findings demonstrate that subtle structural modifications will yield peptides with different half-lives after iv administration. These findings led us to investigate the effects of other structural modifications on duration of action. We observed that systematic substitutions at positions 7 (NMeLeu) and 10 (Pro9-NHEt, and Gly-NH2) were found to be deleterious. Of interest was the observation that only the DAla10-NH2 substitution led to long duration of action and enzymatic stability under the conditions tested.(ABSTRACT TRUNCATED AT 400 WORDS)

Alanine series of ovine corticotropin releasing factor (oCRF): a structure-activity relationship study.

Previous structure-activity relationship studies of CRF have shown that residues 1-4 were not necessary for receptor binding or transduction, that residues 4-8 were important for activation, and that residues 12-41 were mostly responsible for binding. Finally it was proposed that CRF assumed an alpha-helical structure when interacting with its receptor. By systematic substitution of each residue (except residues 1-4) in ovine CRF (oCRF) by Ala, we have investigated the role played by individual side chains in receptor recognition and activation. Out of 33 analogues (synthesized using SPPS on an MBHA resin, purified by RPHPLC and characterized by amino acid and mass spectral analyses), a significant loss of biological potency (less than 1% potency of native) was observed for 6 analogues ([Ala6], [Ala8], [Ala10], [Ala12], [Ala14], and [Ala38]); 12 analogues had biological potencies ranging from 1% to 60% and ranked as follows: [Ala35] less than [Ala16] less than [Ala9] less than [Ala19] less than [Ala15] less than [Ala13] less than [Ala7] less than [Ala23] less than [Ala11] less than or equal to [Ala21] less than [Ala27] less than or equal to [Ala18]; 8 analogues were found to be equipotent (greater than 60% and less than 150%) ([Ala5], [Ala17], [Ala26], [Ala29], [Ala30], [Ala34], [Ala36], and [Ala37]; and 7 analogues were found to be approximately 2-5 times more potent than native oCRF ([Ala25] = [Ala40] less than or equal to [Ala39] less than or equal to [Ala33] less than [Ala20] less than [Ala22] less than [Ala32], in an in vitro pituitary cell culture assay. In summary, the Ala substitutions which showed the greatest loss of potency (less than 1% of native oCRF) were those replacing hydrophobic residues while those showing the greatest increase in potency were replacing hydrophilic residues. Of the 22 Ala-containing analogues in the C-terminal half of the molecule, 17 analogues have equal or greater potencies than native oCRF. Substitution of Ala in the N-terminal region (residues 5-19) on the other hand is generally detrimental to biological activity. These results suggest that the side chains of residues 5-19 are very important for receptor binding and activation while, in the C-terminal region, the amino acid side chains may be more responsible for structural conservation than for functional expression.

Structural requirements for neuropeptide Y18-36-evoked hypotension: a systematic study.

It has been shown that NPY and select C-terminal fragments of NPY that evoke a hypotensive response upon intraarterial administration in the rat also cause mast cell degranulation and histamine release in vitro. Additionally, elevation of plasma histamine levels has been observed concomitant with the hypotensive effect of NPY and various C-terminal fragments. In order to investigate whether the hypotensive response to NPY18-36 is correlated to this observed elevation of histamine in vivo, we sought to characterize the structural requirements for each activity. We conducted a systematic replacement of each amino acid in NPY18-36 by its D-isomer. Additionally, various modifications were made to the N- or C-terminii of NPY18-36. The following rank order of potency was obtained for the hypotensive action of these analogues of NPY18-36 relative to NPY18-36. Only one analogue ([D-Tyr21]NPY18-36) exhibited significantly enhanced potency. Eleven analogues of NPY18-36, ([D-Thr32]-, [D-Arg35]-, [D-Ile31]-, [D-Leu30]-, [D-Tyr27]-, [D-Ser22]-, [D-Tyr36]-, [D-Gln34]-, [D-Asn29]-, [D-Ala23]-, and [D-Arg33]NPY18-36) were equipotent with NPY18-36. Four analogues ([D-His26]-, [D-Ile28]-, and [D-Ala18]NPY18-36 and -NPY18-27) had reduced potency (10-80%) while eight analogues ([D-Arg19]-, [D-Tyr20], [D-Leu24]-, [D-Arg25]-, [Ac-Ala18]-, [Me-Ala18]-, [desamino-Ala18]NPY18-36 and NPY18-36 free acid) failed to produce a significant hypotensive response (less than 10%) at the doses tested. The sensitivity of NPY18-36 to chiral inversion of single residues or other modifications at the N-terminus suggested the presence of a conformationally well defined N-terminal pharmacophore. Additionally, five NPY18-36 analogues were tested for elevation of plasma histamine levels. The rank order of potency ([D-Thr32]NPY18-36 = [D-Tyr21]NPY18-36 much greater than NPY18-36 greater than [D-Ala18]NPY18-36 greater than [Ac-Ala18]NPY18-36) was correlated with each analogue's potency at evoking a hypotensive response. In contrast, NPY1-36 failed to evoke an elevation in plasma histamine levels despite its hypotensive effects. Hence, we conclude that the magnitude of the hypotensive response evoked by an NPY18-36 analogue is primarily a function of its ability to elevate plasma histamine levels. However, the mechanism underlying NPY1-36-evoked hypotension appears to be different.

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.

Constrained corticotropin-releasing factor (CRF) agonists and antagonists with i-(i+3) Glu-Xaa-DXbb-Lys bridges.

We hypothesized that covalent constraints such as side-chain to side-chain lactam rings would stabilize an alpha-helical conformation shown to be important for the recognition and binding of the human corticotropin-releasing factor (hCRF) C-terminal 33 residues to CRF receptors. These studies led to the discovery of cyclo(20-23)[DPhe12,Glu20,Lys23,Nle21,38]hCRF (12-41) and of astressin ¿cyclo(30-33)[DPhe12,Nle21,38,Glu30,Lys33]hCR F(12-41)¿, two potent CRF antagonists, and of cyclo(30-33)[Ac-Leu8,DPhe12,Nle21, Glu30,Lys33,Nle38]hCRF(8-41), the shortest sequence equipotent to CRF reported to date (Rivier et al. J. Med. Chem. 1998, 41, 2614-2620 and references therein). To test the hypothesis that the Glu20-Lys23 and Glu30-Lys33 lactam rings were favoring an alpha-helical conformation rather than a turn, we introduced a D-amino acid at positions 22, 31, and 32 in the respective rings. Whereas the introduction of a D-residue at position 31 was only marginally deleterious to potency (ca. 2-fold decrease in potency), introduction of a D-residue at position 22 and/or 32 was favorable (up to 2-fold increase in potency) in most of the cyclic hCRF, alpha-helical CRF, urotensin, and urocortin agonists and antagonists that were tested and was also favorable in linear agonists but not in linear antagonists; this suggested a unique and stabilizing role for the lactam ring. Introduction of a [DHis32] (6) or acetylation of the N-terminus (7) of astressin had a minor deleterious or a favorable influence, respectively, on duration of action. In the absence of structural data on these analogues, we conducted molecular modeling on an Ac-Ala13-NH2 scaffold in order to quantify the structural influence of specific L- and DAla6 and L- and DAla7 substitutions in [Glu5,Lys8]Ac-Ala13-NH2 in a standard alpha-helical configuration. Models of the general form [Glu5,LAla6 or DAla6,LAla7 or DAla7,Lys8]Ac-Ala13-NH2 were subjected to high-temperature molecular dynamics followed by annealing dynamics and minimization in a conformational search. A gentle restraint was applied to the 0-4, 1-5, and 8-12 O-H hydrogen bond donor-acceptor pairs to maintain alpha-helical features at the N- and C-termini. From these studies we derived a model in which the helical N- and C-termini of hCRF form a helix-turn-helix motif around a turn centered at residue 31. Such a turn brings Gln26 in close enough proximity to Lys36 to suggest introduction of a bridge between them. We synthesized dicyclo(26-36,30-33)[DPhe12,Nle21,Cys26,Glu30 ,Lys33,Cys36, Nle38]Ac-hCRF(9-41) which showed significant alpha-helical content using circular dichroism (CD) and had low, but measurable potency ¿0. 3% that of 6 or ca. 25% that of [DPhe12,Nle21,38]hCRF(12-41)¿. Since the 26-36 disulfide bridge is incompatible with a continuous alpha-helix, the postulate of a turn starting at residue 31 will need to be further documented.

Astressin analogues (corticotropin-releasing factor antagonists) with extended duration of action in the rat.

In earlier reports we identified specific point substitutions (DPhe12,Nle21,38), cyclization strategies [in particular, introduction of lactam rings such as that of cyclo(Glu30,Lys33)], and deletions (residues 1-7) in the CRF molecule that led to agonists. We also noted that further deletions (residues 8-14) produced antagonists such as astressin ¿cyclo(30-33)[DPhe12,Nle21,38, Glu30, Lys33]hCRF(12-41)¿ (1). We hypothesized that the lactam ring promoted conformational stability to yield analogues with increased potency both in vitro and in vivo as compared to that of their linear counterparts. Additionally, we reported that cyclo(30-33)[DPhe12,Nle21,38, Glu30,DHis32,Lys33]hCRF(12-41) (3) and dicyclo(26-36,30-33)[Ac-Asp9,DPhe12,Nle21,38, Cys26, Glu30,Lys33, Cys36]hCRF(9-41) were ca. twice and 1/100 as potent as astressin, respectively, suggesting a putative turn that encompasses residues 30-33 (previous paper: Koerber et al. J. Med. Chem. 1998, 41). To increase the potency of 1 and/or 3 in vivo, we extended their chain length by one (5-8), two (9, 10), and three (11, 12) residues at the N-terminus and acetylated (6, 8, 10, 12). Of the compounds tested for duration of action (1, 3-6, 8), we found 6 and 8 to be slightly longer-acting than astressin or [DHis32]astressin, while their potencies in vitro were not significantly different from that of 3. Additionally, we introduced CalphaMe-leucine residues in lieu of leucine at positions 14, 15, 19, 27, and 37 in [DHis32]astressin. The analogue [CalphaMe-Leu27,DHis32]astressin (16) was more potent (although not statistically in all cases) than the other four analogues in vitro. While acetylation of the N-terminus of 16 (i.e., 18) or of [CalphaMe-Leu27]astressin (i.e., 19) did not have a significant effect on in vitro potency, elongation of the N-terminus by one or three residues in addition to acetylation resulted in cyclo(30-33)[DPhe12,Nle21,CalphaMe-Leu27,Glu3 0,DHis32,Lys33, Nle38]Ac-hCRF(11-41) (21), cyclo(30-33)[DPhe12,Nle21,CalphaMe-Leu27, Glu30,Lys33,Nle38]Ac-hCRF(9-41) (22), and cyclo(30-33)[DPhe12, Nle21, CalphaMe-Leu27,Glu30,DHis32,Lys33,Nle38 ]Ac-hCRF(9-41) (23) that were longer-acting than 6 and 8 (ca. 2 h inhibition of ACTH secretion at 25 micrograms/adrenalectomized rat). Analogues 22 and 23 were also more potent than astressin at reversing intracisternal CRF- and abdominal surgery-induced delay of gastric emptying in conscious rats.