Identification of Gln8-GnRH and His5,Trp7,Tyr8-GnRH in the hypothalamus and extrahypothalamic brain of the ostrich (Struthio camelus)

Gonadotropin-releasing hormone (GnRH) molecular forms were studied in extracts of ostrich hypothalamus and extrahypothalamic brain using high performance liquid chromatography, radioimmunoassay with region-specific antisera and assessment of luteinizing hormone (LH)-releasing activity using chicken dispersed pituitary cells. Two molecular forms of GnRH with chromatographic, immunological and biological properties identical to those of Gln8-GnRH and His5,Trp7,Tyr8-GnRH were demonstrated in both the hypothalamic and extrahypothalamic brain extracts. A greater proportion of His5,Trp7,Tyr8-GnRH was present in the hypothalamus than in extrahypothalamic brain. It is likely that these two forms of GnRH are present in all bird species, since the chicken and the ostrich have evolved separately.     

Luteinizing hormone releasing activity of [Gln8]-LHRH and [His5, Trp7, Tyr8]-LHRH in the cockerel, in vivo and in vitro

The luteinizing hormone (LH)-releasing activity of two distinct chicken luteinizing hormone releasing hormones ([Gln8]-LHRH and [His5, Trp7, Tyr8]-LHRH) were evaluated in white Leghorn cockerels. In the first study, thirty birds were randomly allotted to five groups and injected, i.v., with 0.9% saline, [Gln8]-LHRH (cLHRH I, 1 microM or 10 microM) or [His5, Trp7, Tyr8]-LHRH, (cLHRH II; 1 microM or 10 microM). Blood samples were drawn prior to and through 60 min following the injection, and plasma was collected for LH determination. In the second study, anterior pituitary cells from cockerels were dispersed and preincubated for 1 hr. Approximately 1.5 X 10(5) cells per tube were incubated with either Medium 199 buffer (control), 8-bromo-cAMP or various doses of cLHRH I or cLHRH II at final concentrations ranging from 0.02 to 100.0 nM. At the end of a two hour incubation, supernatant was collected and the concentration of LH determined. Injection of cLHRH I or cLHRH II at 1 microM and 10 microM levels caused a significant increase in blood LH concentrations which peaked 5 min following injection. There were, however, no differences between the stimulatory effect of cLHRH I compared to cLHRH II at either dose. On the other hand, cLHRH II was found to be 4.7 times more potent than cLHRH I in stimulating LH release from dispersed pituitary cells. It is suggested that cLHRH II may have greater affinity for the gonadotroph receptor, greater uptake by the cell, and/or that it may be more resistant to in vitro degradation than cLHRH I. On the other hand, an extra pituitary site of degradation may be more effective in metabolizing cLHRH II, resulting in its equipotency with cLHRH I, in vivo.     

Trp7,Leu8]LH-RH in reptilian brain

Luteinizing hormone-releasing hormone (LH-RH) immunoreactive peptides in acetic acid extracts of lizard (Cordylis nigra) brain were studied by high performance liquid chromatography (HPLC) and radioimmunoassay with region-specific antisera. Four different LH-RH immunoreactive peptides were detected. The major form co-eluted with salmon brain LH-RH, [Trp7,Leu8]LH-RH, in a cation exchange and three reverse phase HPLC systems which were specifically designed to separate a range of LH-RH analogues. The interaction of this major LH-RH immunoreactive peptide with a number of antisera directed against different regions of mammalian, chicken and salmon LH-RH was similar to the relative interaction of [Trp7,Leu8]LH-RH with these antisera. These data strongly indicate that the major form of lizard brain LH-RH is identical to salmon brain LH-RH [( Trp7,Leu8]LH-RH). The three additional molecular forms of immunoreactive LH-RH in lizard brain appear to differ from mammalian LH-RH in the middle to C-terminal region of the molecule.     

Chromatographic and immunological evidence for mammalian GnRH and chicken GnRH II in eel (Anguilla anguilla) brain and pituitary

Gonadotropin-releasing hormone (GnRH) peptides in the brain and pituitary of the European eel (Anguilla anguilla) were investigated by reverse phase high performance liquid chromatography (HPLC) and radioimmunoassay with region-specific antisera. Two GnRH molecular forms were demonstrated in brain and pituitary extracts. One form eluted in the same position as synthetic mammalian GnRH on HPLC and was recognized by antibodies directed against the NH2 and COOH termini of mammalian GnRH as well as by antibodies to the middle region. The second form eluted in the same position as synthetic chicken GnRH II and was recognized by specific antibodies to this molecule. Salmon GnRH and chicken GnRH I were not detected. The occurrence of mammalian GnRH in teleost fish suggests that this molecular form is more ancient than was previously suspected and arose earlier than in primitive tetrapods, or that it has arisen in the eel through random mutation of salmon GnRH. The lack of salmon GnRH in the eel brain indicates that this molecular form is not common to all teleost species. The finding in eel brain of chicken GnRH II, which has previously been described in species of Mammalia, Aves, Reptilia, Amphibia, Osteichthyes, and Chondrichthyes, supports our hypothesis that this widespread structural variant may represent an early evolved and conserved form of GnRH.     

Identification of Tyr(290(6.58)) of the human gonadotropin-releasing hormone (GnRH) receptor as a contact residue for both GnRH I and GnRH II: importance for high-affinity binding and receptor activation

Molecular modeling showed interactions of Tyr (290(6.58)) in transmembrane domain 6 of the GnRH receptor with Tyr (5) of GnRH I, and His (5) of GnRH II. The wild-type receptor exhibited high affinity for [Phe (5)]GnRH I and [Tyr (5)]GnRH II, but 127- and 177-fold decreased affinity for [Ala (5)]GnRH I and [Ala (5)]GnRH II, indicating that the aromatic ring in position 5 is crucial for receptor binding. The receptor mutation Y290F decreased affinity for GnRH I, [Phe (5)]GnRH I, GnRH II and [Tyr (5)]GnRH II, while Y290A and Y290L caused larger decreases, suggesting that both the para-OH and aromatic ring of Tyr (290(6.58)) are important for binding of ligands with aromatic residues in position 5. Mutating Tyr (290(6.58)) to Gln increased affinity for Tyr (5)-containing GnRH analogues 3-12-fold compared with the Y290A and Y290L mutants, suggesting a hydrogen-bond between Gln of the Y290Q mutant and Tyr (5) of GnRH analogues. All mutations had small effects on affinity of GnRH analogues that lack an aromatic residue in position 5. These results support direct interactions of the Tyr (290(6.58)) side chain with Tyr (5) of GnRH I and His (5) of GnRH II. Tyr (290(6.58)) mutations, except for Y290F, caused larger decreases in GnRH potency than affinity, indicating that an aromatic ring is important for the agonist-induced receptor conformational switch.     

Identification of three crucial histidine residues (His115, His132 and His297) in porcine deoxyribonuclease II

DNase II is an acid endonuclease that is involved in the degradation of exogenous DNA and is important for DNA fragmentation and degradation during cell death. In an effort to understand its catalytic mechanism, we constructed plasmids encoding nine different histidine (H)-to-leucine (L) mutants for porcine DNase II and examined the enzyme properties of the expressed mutant proteins. Of the mutants, all but H132L were secreted into the medium of expressing cells. Six of the mutated DNase II proteins (H41L, H109L, H206L, H207L, H274L and H322L) showed enzyme activity, whereas the H115L, H132L and H297L mutants exhibited very little activity. The H115L and H297L mutants were found to undergo correct protein folding, but were inactive. To further examine these mutants, we expressed H115A and H297A DNase II mutants; these mutants were inactive, but their DNase activities could be rescued with imidazole, indicating that His115 and His297 are likely to function as a general acid and a general base respectively in the catalytic centre of the enzyme. In contrast with the secreted mutants, the H132L mutant protein was found in cell lysates within 16 h after transfection. This protein was inactive, improperly folded and was drastically degraded via the proteosomal pathway after 24 h. The polypeptide of another substitution for His132 with lysine resulted in the misfolded form being retained in endoplasmic reticulum.     

Design and synthesis of a gonadotropin-releasing hormone (GnRH) analogue, [Tyr(OMe)5,d-Glu6,Aze9]GnRH: Receptor binding, gonadotropin release and ovulation studies

Summary Gonadotropin-releasing hormone (GnRH) stimulates the release and synthesis of gonadotropin hormones (GtH) and is the key regulator of reproduction. The present study was carried out to design a potent GnRH analogue containing Tyr(OMe) at position 5 and ad-amino acid at position 6. This was based on a previous study in which [Tyr(OMe)⁵]GnRH was shown to have reduced potency compared to GnRH. A novel GnRH peptide containing Tyr(OMe)⁵ andd-Glu⁶ in combination with other substitutions at positions 9 and 10 was synthesized in the present study and tested for binding to the rat pituitary as well as potency in terms of gonadotropin (GtH) release in the goldfish pituitary and ovulation in sea bass. The results demonstrate that the replacement of the glycine residue at position 6 with ad-Glu in combination with the substitution of proline at position 9 with azetidine (Aze) increased the binding and biological activity of [Tyr(OMe)⁵]GnRH. The observed increased potency is likely to be related to the improved resistance to degradation. The present findings may lead to the development of a more potent GnRH agonist for inducing ovulation in fish.     

Design and Synthesis of Potent Tyr(OMe)5-Gonadotropin-Releasing Hormone (GnRH) Analogues with Modifications at Positions 6, 9 and 10

Summary We have recently reported the synthesis and the conformational properties of some Gonadotropin-releasing hormone (GnRH) analogues in which the tyrosine residue at position 5 is substituted with tyrosine-O-methyl (Keramida et al., Let. Pept. Sci., 3 (1996) 257/Matsoukas et al., Eur. J. Med. Chem., 32 (1997) 927). The analogue [Tyr-(OMe)⁵]-GnRH was found to exert a lower degree of desensitization than the native GnRH peptides in terms of pituitary gonadotropin (GTH) release in goldfish. Compared to GnRH, however, [Tyr-(OMe)⁵]-GnRH exerted a lower GTH-release potency in cultured goldfish pituitary fragments, and was bound with a lower binding affinity to the rat pituitary GnRH receptors. In order to increase the potency of [Tyr-(OMe)⁵]-GnRH, we have synthesized a group of GnRH peptides containing Tyr-(OMe)⁵ in combination with other substitutions at positions 6, 9 and 10 and we have estimated their binding affinity for the rat pituitary receptors and gonadotropin (GTH) release potency in the goldfish pituitary. A selected number of these analogues was also tested for their ability to induce ovulation in seabass. The important structural modifications that increased the binding and gonadotropic activity of [Tyr(OMe)⁵]-GnRH in vitro and in vivo were found to include the replacement of the proline at position 9 with azetidine, glycine amide terminus with an alkyl amide group and Gly⁶ residue with hydrophilicd-amino acids such asd-Arg⁶. Overall, the findings provide SAR information on a group of novel GnRH peptides that can be also used to induce ovulation in teleosts.     

Trp22, Trp24, and Tyr8 play a pivotal role in the binding of the family 10 cellulose-binding module from Pseudomonas xylanase A to insoluble ligands

Aromatic amino acids are believed to play a pivotal role in carbohydrate-binding proteins, by forming hydrophobic stacking interactions with the sugar rings of their target ligands. Family 10 cellulose-binding modules (CBM10s), present in a number of cellulases and xylanases expressed by Pseudomonas fluorescens subsp. cellulosa, contain two tyrosine and three tryptophan residues which are highly conserved. To investigate whether these amino acids play an important role in the interaction of CBM10 from P. fluorescens subsp. cellulosa xylanase A (Pf Xyn10A) with cellulose, each of these residues was changed to alanine in CBM10 expressed as a discrete module or fused to the catalytic domain of Pf Xyn10A (CBM10-CD), and the capacity of the mutant proteins of CBM10-CD to bind the polysaccharide was evaluated. The data showed that W22A, W24A, and Y8A bound very weakly to cellulose compared to the wild-type protein, while Y12A retained its capacity to interact with the glucose polymer. When the W7A mutation was introduced into CBM10 the protein domain did not accumulate in Escherichia coli. In contrast, the W7A mutant of CBM10-CD was efficiently expressed in E. coli, although the protein bound very weakly to cellulose. NMR spectra of wild-type CBM10, W22A, and W24A were very similar, suggesting that the mutations did not significantly affect the protein fold. Titration of wild-type CBM10, W22A, and W24A with N-bromosuccinimide indicated that Trp22 and Trp24 were on the surface of the protein, while Trp7 was buried. Collectively, these data indicate that Trp22, Trp24, and Tyr8 play a direct role in the binding of Pf Xyn10A CBM10 to cellulose. The results are discussed in the light of the three-dimensional structure of CBM10 [Raghothama, S., Simpson, P. J., Szabó, L., Nagy, T., Gilbert, H. J., and Williamson, M. P. (2000) Biochemistry 39, 978-984].     

Gonadotropin-releasing hormone in elasmobranch (electric ray, Torpedo marmorata) brain and plasma: chromatographic and immunological evidence for chicken GnRH II and novel molecular forms.

Gonadotropin-releasing hormone (GnRH) peptides in the brain, testis and plasma of an electric ray (Torpedo marmorata) were investigated by gel filtration chromatography, reverse phase high performance liquid chromatography and radioimmunoassay with region-specific antisera. In the brain, two major forms of GnRH were demonstrated. One form had identical chromatographic and immunological properties to chicken GnRH II, and the second, novel, molecular form had structural features in common with mammalian, chicken II and salmon GnRHs. A minor, early-eluting immunoreactive peak, possibly also a novel GnRH, was also evident. Immunoreactive GnRH was not detected in the testis. In the plasma, a single major early-eluting immunoreactive peak was demonstrated. This peak, identical to the minor peak observed in the brain, is likely to represent a novel form of GnRH which has immunological properties in common with mammalian, chicken II and salmon GnRHs. Immunoreactive GnRH was not detected in the plasma of species from other vertebrate classes, including rabbit, chicken, monitor lizard, clawed toad, frog, cichlid fish and lamprey. The finding of chicken GnRH II in a species of Chondrichthyes adds further support to our hypothesis that this widespread structural variant may represent an early-evolved and conserved form of GnRH. The presence of a GnRH molecular form in the plasma of the electric ray suggests that GnRH may reach target organs (pituitary and gonads) via the general circulation in some species of Chondrichthyes.     

The roles of Tyr(CD1) and Trp(G8) in Mycobacterium tuberculosis truncated hemoglobin O in ligand binding and on the heme distal site architecture

The crystal structure of the cyano-met form of Mt-trHbO revealed two unusual distal residues Y(CD1) and W(G8) forming a hydrogen-bond network with the heme-bound ligand [Milani, M., et al. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 5766-5771]. W(G8) is an invariant residue in group II and group III trHbs and has no counterpart in other globins. A previous study reported that changing Y(CD1) for a Phe causes a significant increase in the O2 combination rate, but almost no change in the O2 dissociation rate [Ouellet, H., et al. (2003) Biochemistry 42, 5764-5774]. Here we investigated the role of the W(G8) in ligand binding by using resonance Raman spectroscopy, stopped-flow spectrophotometry, and X-ray crystallography. For this purpose, W(G8) was changed, by site-directed mutagenesis, to a Phe in both the wild-type protein and the mutant Y(CD1)F to create the single mutant W(G8)F and the double mutant Y(CD1)F/W(G8)F, respectively. Resonance Raman results suggest that W(G8) interacts with the heme-bound O2 and CO, as evidenced by the increase of the Fe-O2 stretching mode from 559 to 564 cm-1 and by the lower frequency of the Fe-CO stretching modes (514 and 497 cm-1) compared to that of the wild-type protein. Mutation of W(G8) to Phe indicates that this residue controls ligand binding, as evidenced by a dramatic increase of the combination rates of both O2 and CO. Also, the rate of O2 dissociation showed a 90-1000-fold increase in the W(G8)F and Y(CD1)F/W(G8)F mutants, that is in sharp contrast with the values obtained for the other distal mutants Y(B10)F and Y(CD1)F [Ouellet, H., et al. (2003) Biochemistry 42, 5764-5774]. Taken together, these data indicate a pivotal role for the W(G8) residue in O2 binding and stabilization.     

Identification of 7(8) and 8(9) unsaturated adrenal steroid metabolites produced by patients with 7-dehydrosterol-delta7-reductase deficiency (Smith-Lemli-Opitz syndrome)

Patients with Smith-Lemli-Opitz syndrome have impaired ability to synthesize cholesterol due to attenuated activity of 7-dehydrosterol-delta(7)-reductase which catalyses the final step in cholesterol synthesis. Accumulation of 7- and 8-dehydrocholesterol is a result of the disorder and potentially these sterols could be used as precursors of a novel class of delta(7) and delta(8) unsaturated adrenal steroids and their metabolites. In this study, we have analyzed urine from SLOS patients in the anticipation of characterizing such metabolites. Gas chromatography/mass spectrometry (GC/MS) was used in the identification of two major metabolites as 7- and 8-dehydroversions of the well-known steroid pregnanetriol. Other steroids, such as 8-dehydro dehydroepiandrosterone (8-dehydro DHEA) and 7- or 8-dehydroandrostenediol were also identified, and several more steroids are present in urine but remain uncharacterized. As yet, the study provides no evidence for the production of ring-B unsaturated metabolites of complex steroids, such as cortisol. We believe that the following transformations can utilize ring-B dehydroprecursors: StAR transport of cholesterol, p450 side chain cleavage, 17-hydroxylase/17,20-lyase, 3beta-hydroxysteroid dehydrogenase, 3alpha-hydroxysteroid dehydrogenase, 17beta-hydroxysteroid dehydrogenase, 20alpha-hydroxysteroid dehydrogenase and 5beta-reductase. We have yet to prove the activity of adrenal 21-hydroxylase, 11beta-hydroxylase or 5alpha-reductase towards 7- or 8-dehydroprecursors.     

Identification of diverse molecular forms of GnRH in reptile brain

Gonadotropin-releasing hormone (GnRH) molecular forms in the brains of three reptiles, Alligator mississippiensis (alligator), Calcides ocellatus tiligugu (skink) and Podarcis s. sicula (lizard) were characterized by high performance liquid chromatography (HPLC) and radioimmunoassay with region-specific antisera, and by assessment of luteinizing (LH)-releasing activity in chicken dispersed pituitary cells. In alligator brain two GnRHs had identical properties to the two known forms of chicken hypothalamic GnRH (Gln⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH) in their elution on two reverse phase HPLC systems, cross-reaction with region-specific GnRH antisera, and ability to release LH. In skink brain, one immunoreactive and bioactive GnRH form, which eluted in the same position as His⁵,Trp⁷,Tyr⁸-GnRH on reverse phase HPLC, was identified. Three bioactive and immunoreactive GnRHs were detected in lizard brain. One form had similar properties to salmon brain GnRH (Trp⁷,Leu⁸-GnRH). The other two GnRH-like peptides are novel forms. One of these forms eluted in the same position as Gln⁸-GnRH on HPLC but had different immunological properties, while the third form was a rather hydrophobic species which appeared to be modified in the middle region of the molecule.     

Structure-activity relationships of trout bradykinin ([Arg(0),Trp(5),Leu(8)]-bradykinin)

Trout bradykinin ([Arg⁰,Trp⁵,Leu⁸]-BK) produces sustained and concentration–dependent contractions of isolated longitudinal smooth muscle from trout stomach, although mammalian BK is without effect. Circular dichroism studies have demonstrated that trout BK, unlike mammalian BK, does not adopt a stable β-turn conformation, even in the presence of sodium dodecyl sulfate (SDS) or trifluoroethanol. The myotropic actions of a series of analogs in which each amino acid in trout BK was replaced by either alanine or the corresponding D-isomer were investigated. The peptides with Ala⁴, D-Pro³, D-Trp⁵, D-Ser⁶, and D-Pro⁷ substitutions were inactive and did not act as antagonists of trout BK. The analog with [Ala⁵] was a weak partial agonist. The substitution (Arg⁰ → Ala) led to >50-fold decrease in potency but, in contrast to the importance of Phe⁸ in both BK and desArg⁹-BK in activating the mammalian B₂ and B₁ receptors respectively, substitutions at Leu⁸ in trout BK had only a minor effect on potency. Antagonists to the mammalian B₂ receptor generally contain a D-aromatic amino acid at position 7 of BK but the analog [Arg⁰,Trp⁵,D-Phe⁷,Leu⁸]-BK was a weak agonist at the trout receptor. Similarly, the potent nonpeptide mammalian B₂ receptor antagonist FR173657 was without effect on the action of trout BK. These data suggest the hypothesis that the receptor binding conformation of trout BK is defined by the central region (residues 3–7) of the peptide but is adopted only upon interaction with the receptor. The bioactive conformation is probably stabilized by an ionic interaction between Arg⁰ in the peptide and an acidic residue in the receptor.     

Site-Directed Mutagenesis of BmK AGP-SYPU1: The Role of Two Conserved Tyr (Tyr5 and Tyr42) in Analgesic Activity

In this study, the role of two conversed tyrosines (Tyr5 and Tyr42) from the scorpion toxin BmK AGP-SYPU1 was investigated with an effective Escherichia coli expression system. Site-directed mutagenesis was used to individually substitute Tyr5 and Tyr42 with hydrophobic or hydrophilic amino acids, and the extent to which these scorpion toxin BmK AGP-SYPU1 tyrosines contribute to analgesic activity was evaluated. The results of the mouse-twisting test showed that Tyr5 and Tyr42 are associated with the analgesic activity of the toxin because the analgesic activities of Y5F and Y42F were significantly increased compared with the rBmK AGP-SYPU1; however, the Y5W had decreased activity. The results of molecular simulation reveal the following: (1) for analgesic activity, the core domain of the scorpion toxin BmK AGP-SYPU1 is key and (2) for pharmacological function, Tyr42 is most likely involved when the core domain conformation is altered. These studies identify a new relationship between the structure and analgesic activity of the scorpion toxin BmK AGP-SYPU1 and are significant for further research and the application of analgesic peptides.     

Conformational constraint of mammalian,chicken, and salmon GnRHs,but not GnRH II,enhances binding at mammalian and nonmammalian receptors: evidence for preconfiguration of GnRH II

Mammalian GnRH (mGnRH) is believed to interact with mGnRH type I receptors in a beta-II' turn conformation involving residues 5-8. This conformation can be constrained by substitution of a D-amino acid at position 6 or by a lactam ring involving residues 6 and 7, thereby increasing receptor binding affinity. It has been proposed that this is not the case for non-mGnRH receptors. However, we show that this conformational constraint increases the binding affinity of mammalian, chicken, and salmon GnRH for the chicken and catfish receptors, as well as for the mouse receptor. Therefore, we conclude that the beta-II' turn conformation enhances ligand binding for non-mGnRH as well as mGnRH type I receptors. In contrast, most substitutions of a D-amino acid in position 6 have limited effect on binding affinity for GnRH II. We suggest that this ligand is preconfigured through intramolecular interactions, which accounts for its high binding affinity and total conservation of primary structure over 500 million years of evolution.     

Intermolecular interactions in staphylokinase-plasmin(ogen) bimolecular complex: function of His43 and Tyr44

Staphylokinase (SAK) forms a 1:1 stoichiometric complex with human plasmin (Pm) and switches its substrate specificity to generate a plasminogen (Pg) activator complex. Site-directed mutagenesis of SAKHis43 and SAKTyr44 demonstrated the crucial requirement of a positively charged and an aromatic residue, respectively, at these positions for optimal functioning of SAK-Pm activator complex. Molecular modeling studies further revealed the role of these residues in making cation-pi and pi-pi interactions with Trp215 of Pm and thus establishing the crucial intermolecular contacts within the active site cleft of the activator complex for the cofactor activity of SAK.