Adrenal luteinizing hormone releasing hormone receptors.

Paraffin sections of mouse adrenals processed with antiserum to luteinizing hormone-releasing hormone (LHRH) in the unlabeled antibody enzyme method reveal moderate staining in the cytoplasm of cells of zona fasciculata and reticularis. The stain is intensified upon pretreatment of sections with LHRH. Pretreated sections processed with solid phase immunoabsorbed LHRH are unstained. Analogues of LHRH deficient in the C-terminal glycine amide inhibit staining, while analogues deficient in the N-terminal pyroglutamic acid have no effect. It is concluded that the adrenal contains receptors for a ligand resembling LHRH in receptor and immunoreactivity. The possibility is considered that the ligand may be an inhibitor of pineal origin.     

Human placental receptors for luteinizing hormone releasing hormone

The GTPase activity of the tubulin-colchicine complex has been studied at different tubulin-colchicine concentrations. The specific activity was found to decrease at low concentrations. Several hypothesis accounting for this observation have been discarded, and the activation via collisions between two molecules of tubulin has been considered as a possible model explaining the origin and observed concentration dependence of the GTPase activity. The activation of tubulin-colchicine by unliganded tubulin or tubulin-podophyllotoxin has been investigated within this model which emphasizes the connection between some specific tubulin-tubulin interactions and the conformation of the exchangeable nucleotide site on tubulin.     

Changes in prolactin levels caused by luteinizing hormone releasing hormone

The acute effects of luteinizing hormone releasing hormone (LHRH) on the release of prolactin (PRL) were investigated in 12 normal cycling women and 42 women with various menstrual disorders. LHRH (100 micrograms) was bolusly injected intramuscularly and PRL levels were measured immediately before the injection and at 30 minutes and 60 minutes after the injection. LHRH elicited an increase of more than 25% in PRL levels in 15 cases (27.8%) at both 30 minutes and 60 minutes after the injection, whereas PRL levels were decreased by more than 25% in 7 cases (13.0%). The PRL response to LHRH seemed to be related to basal PRL levels. Especially when the PRL concentration was 20 ng/ml or more, LHRH decreased PRL levels in 7 cases out of 16. On the other hand, LHRH increased PRL levels in the majority of cases with a PRL concentration less than 20 ng/ml. In conclusion, the LHRH injection occasionally alters PRL levels in either a positive or negative manner, depending upon the basal PRL levels.     

On the existence and separation of the follicle stimulating hormone releasing hormone from the luteinizing hormone releasing hormone.

Porcine hypothalamic fragments were extracted by 2M AcOH at 4°C, and the extractives were subsequently processed in the presence of one protease inhibitor and one anti-oxidant. Gel filtration was performed on Bio-Gel P-2, and supplementary [³H]-LHRH and [¹⁴C]- 3H]-LHRH, and was differentiated from [¹⁴C]- 相似文献   

Effects of luteinizing hormone releasing hormone on gonadotrophins in the hamster

The changes in serum gonadotrophins in male hamsters following one injection of 15 μg luteinizing hormone releasing hormone (LHRH) (Group A) were compared with those following the last injection of LHRH in animals receiving an injection approximately every 12 hr for 4 days (Group B) or 12 days (Group C). Peak follicle stimulating hormone (FSH) levels (ng/ml) were 1776±218 (Group A), 2904±346 (Group B), and 4336±449 (Group C). Peak luteinizing hormone (LH) values (ng/ml) were 1352±80 (Group A), 410±12 (Group B), and 498±53 (Group C). Serum FSH:LH ratios, calculated from the concentrations measured 16 hr after the last LHRH injections, were higher in Groups B and C than in Group A. Similar injections of LHRH (100 ng or 15 μg/injection) for 6 days elevated the serum FSH:LH ratio in intact males. Five such LHRH injections (100 ng/injection) blunted the rise in serum LH in orchidectomized hamsters. Direct effects of LHRH on gonadotrophin secretory dynamics or altered brain-pituitary-testicular interactions may alter the ratio of FSH to LH in the hamster.     

Effective antagonists of luteinizing hormone releasing hormone modified at position one

Summary The amino acid, D-2-naphthylalanine, has been used by many investigators as a substituent for position one of antagonists of LHRH. We have newly designed substituents for position one in which the carboxy groups of 2-naphthoic acid, 3-quinoline- and 2-quinoxaline-carboxylic acids are linked to the five amino acids, DAla, DThr, DNVal, DSer, and Gly. The substituents in positions 2–10 were DpClPhe², DPal³, Ser⁴, PicLys⁵, DPicLys⁶, Leu⁷, ILys⁸, Pro⁹, DAlaNH₂ ¹⁰.Remarkably, DThr, acylated on the amino group by 3-quinolinecarboxylic acid or by 3-quinoxalinecarboxylic acid, and introduced into position one of a relatively potent antagonist, gave a new class of antagonists of LHRH, which released as little histamine as yet recorded, and yet possessed reasonable antiovulatory activity and greatly improved solubility.These structure-activity results advance the basic knowledge of understanding the structural features of such decapeptides which cause antiovulatory activity and histamine release.Abbreviations ILys N -isopropyllysine; - 1-Nal 3-(1-naphthyl)alanine - 2-Nal 3-(2-naphthyl)alanine - Nap 2-naphthoic acids - NicLys N -nicotinoyllysine; - Pal 3-(3-pyridyl)alanine - pClPhe 3-(4-chlorophenyl)alanine - PicLys N -picolinoyllysine - c-PzACAla cis-3-(4-pyrazinylcarbonylaminocyclohexyl) alanine - 3-Qal 3-(3-quinolyl)alanine - Qui 3-quinolinecarboxylic acid - Qux 2-quinoxalinecarboxylic acid     

Isolation and structural characterization of chicken hypothalamic luteinizing hormone releasing hormone

Studies on partially purified chicken hypothalamic luteinizing hormone releasing hormone (LHRH) utilizing chromatography, radioimmunoassay with region-specific antisera, enzymic inactivation, and chemical modification established that the peptide is structurally different from mammalian hypothalamic LHRH. These studies demonstrated that arginine in position 8 is substituted by a neutral amino acid. On the basis of conformational criteria and evolutionary probability of amino acid interchange for arginine, the most likely substitution was glutamine. We therefore synthesized [Gln8]-LHRH and established that it had identical chromatographic, immunologic, and biological properties to the natural chicken peptide. In concurrent studies, purification of 17 micrograms of an LHRH from 249,000 chicken hypothalami was achieved using acetic acid extraction, immuno-affinity chromatography, and cation exchange and reverse phase high performance liquid chromatography. Amino acid composition and sequence analyses confirmed the structure of this form of chicken LHRH as pGlu-His-Trp-Ser-Tyr-Gly-Leu-Gln-Pro-Gly-NH2.     

The structural features of effective antagonists of the luteinizing hormone releasing hormone

Summary The structure-activity data of 6 years on 395 analogs of the luteinizing hormone releasing hormone (LHRH) have been studied to determine effective substituents for the ten positions for maximal antiovulatory activity and minimal histamine release. The numbers of substituents studied in the ten positions are as follows: (41)¹-(12)²-(12)³-(5)⁴-(47)⁵-(52)⁶-(16)⁷-(18)⁸-(4)⁹-(8)¹⁰. In position 1, DNal and DQal were effective with the former being more frequently the better substituent. DpClPhe was uniquely effective in position 2. Positions 3 and 4 are very sensitive to change. D3Pal in position 3 and Ser in position 4 of LHRH were in the best antagonists. PicLys and cPzACAla were the most successful residues in position 5 with cPzACAla being the better substituent. Position 6 was the most flexible and many substituents were effective; particularly DPicLys. Leu⁷ was most often present in the best antagonists. In position 8, Arg was effective for both antiovulatory activity and histamine release; ILys was effective for potency and lesser histamine release. Pro⁹ of LHRH was retained. DAlaNH₂ ¹⁰ was in the best antagonists.Abbreviations AABLys N -(4-acetylaminobenzoyl)lysine - AALys N -anisinoyl-lysine - AAPhe 3-(4-acetylaminophenyl)lysine - Abu 2-aminobutyric acid - ACLys N -(6-aminocaproyl)lysine - ACyh 1-aminocyclohexanecarboxylic acid - ACyp 1-aminocyclopentanecarboxylic acid - Aile alloisoleucine - AnGlu 4-(4-methoxy-phenylcarbamoyl)-2-aminobutyric acid - 2ANic 2-aminonicotinic acid - 6ANic 6-aminonicotinic acid - APic 6-aminopicolinic acid - APh 4-aminobenzoic acid - APhe 4-aminophynylalanine - APz 3-amino-2-pyrazinecarboxylic acid - Aze azetidine-2-carboxylic acid - Bim 5-benzimidazolecarboxylic acid - BzLys N -benzoyllysine - Cit citrulline - Cl₂Phe 3-(3,4-dichlorphenyl)alanine - cPzACAla cis-3-(4-pyrazinylcarbonylaminocyclohexyl)alnine - cPmACAla cis-3-[4-(4-pyrimidylcarbonyl)aminocyclohexyl]alanine - Dbf 3-(2-dibenzofuranyl)alanine - DMGLys N -(N,N-dimethylglycyl)lysine - Dpo N -(4,6-dimethyl-2-pyrimidyl)-ornithine - F₂Ala 3,3-difluoroalanine - hNal 4-(2-naphthyl)-2-aminobutyric acid - HOBLys N -(4-hydroxybenzoyl)lysine - hpClPhe 4-(4-chlorophenyl)-2-amino-butyric acid - Hse homoserine, 2-amino-4-hydroxybutanoic acid - ICapLys N -(6-isopropylaminocaproyl)lysine - ILys N -isopropyllysine - Ind indoline-2-carboxylic acid - INicLys N -isonicotinoyllysine - IOrn N -isopropylornithine - Me₃Arg N^G,N^G,N^G-trimethylarginine - Me₂Lys N ,N -dimethyllysine - MNal 3-[(6-methyl)-2-naphtyl]alanine - MNicLys N -(6-methylpicolinoyl)lysine - MPicLys N -(6-methylpicolinoyl)lysine - MOB 4-methoxybenzoyl - MpClPhe N-methyl-3-(4-chlorphenyl)lysine - MPZGlu glutamic acid,-4-methylpiperazine - Nal 3-(2-naphthyl)alanine - Nap 2-naphthoic acid - NicLys N -nicotinoyllysine - NO₂B 4-nitrobenzoyl - NO₂Phe 3-(4-nitrophenyl)alanine - oClPhe 3-(2-chlorphenyl)alanine - Opt O-phenyl-tyrosine - Pal 3-(3-pyridyl)alanine - 2Pal 3-(2-pyridyl)alanine - 2PALys N -(3-pyridylacetyl)lysine - pCapLys N -(6-picolinoylaminocaproyl)lysine - pClPhe 3-(4-chlorophenyl)alanine - pFPhe 3-(4-fluorophenyl)-alanine - Pic picolinic acid - PicLys N -picolinoyllysine - Pip piperidine-2-car-boxylic acid - PmcLys N -(4-pyrimidylcarbonyl)lysine - Ptf 3-(4-trifluromethyl phenyl)alanine - Pz pyrazinecarboxylic acid - PzAla 3-pyrazinylalanine - PzAPhe 3-(4-pyrazinylcarbonylaminophenyl)alanine - Qal 3-(3-quinolyl)alanine - Qnd-Lys N -quinaldoyllysine - Qui 3-quinolinecarboxylic acid - Qux 2-quinoxalinecarboxylic acid - Tic 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid - TinGly 2-thienylglycine - tNACAla trans-3-(4-nicotinoylaminocyclohexyl)-alanine - tPACAla trans-3-(4-picolinoylaminocyclohexyl)alanine     

Cellular characteristics of immunolabeled luteinizing hormone releasing hormone (LHRH) neurons

This study utilized the preembedding immunocytochemical technique in order to identify LHRH-containing neurons in rat brain and define their ultrastructural characteristics. LHRH-containing neurons in the vertical limb of the diagonal band of Broca, medial septum, triangular nucleus of the septum and other regions were studied by taking ultrathin serial sections. These neurons had scant cytoplasm surrounding a centrally-located, spheroid, euchromatic nucleus. Neurosecretory granules were evenly distributed throughout the cell, but many tended to lie directly under the plasmalemma. The cytoplasm was organized in such a way that the most extensive portion of the rough endoplasmic reticulum was polar opposite to areas having high concentrations of Golgi complex, lysosome-like bodies, smooth endoplasmic reticulum and ribosomes. The perikarya had no axosomatic synapses but functional interaction via unspecialized appositions to the plasmalemma cannot be discounted. Many of the perikarya bore at least one cilium. Processes from immunonegative cells were occasionally observed to penetrate the cytoplasm of the LHRH perikaryon or its processes. At their points of origin, dendrites were found to be broadened processes containing many elements common to the cytoplasm: ribosomes, smooth endoplasmic reticulum, cristal and lamellar mitochondria, neurotubules, and an occasional alveolate caveola. Infrequently, some of the LHRH axons were partially myelinated. This method of studying serial-sectioned immunocytochemically-identified cells is suggested as a means of describing the cellular and subcellular characteristics of other specific peptide-containing cells.     

Circular dichroism study of the solution conformation of luteinizing hormone releasing hormone.

A systematic investigation has been made into the circular dichroic behavior of luteinizing hormone releasing hormone and its peptide fragments and deletion analogues. The results are interpreted to mean that the hormone exists in solution as an ensemble of conformers with different sensitivities to temperature and solvent composition. The far-ultraviolet circular dichroic spectra exhibited by the hormone under different experimental conditions can be simulated satisfactorily by the weighted addition of the spectra of its aliphatic- and aromatic-containing halves. However, the structure of the hormone is not simply the sum of its halves, since some conformational feature of the intact molecule perturbs the near-ultraviolet circular dichroism of its aromatic residues.     

Novel ligands for the affinity labelling of luteinizing hormone releasing hormone receptors.

A number of novel luteinizing hormone releasing hormone (LHRH) analogues incorporating biotin together with potential covalent attachment sites have been synthesized. Those based on the des-Gly10-[D-Lys6]-LHRH ethylamide peptide backbone resulted in the most useful characteristics of binding to the LHRH receptor in rat anterior pituitary gland membranes. Of these, des-Gly10-[biotinyl-aminoethylglycyl-D-Lys6]-LHRH ethylamide (XBAL) gave the best specific: non-specific binding ratio, with 44 +/- 6% (+/- S.E.M.) of total binding being specific with a Kd of 131 +/- 16 pM (+/- S.E.M., n = 4) as determined by Scatchard analysis. Two methods have been used to covalently crosslink these analogues with the LHRH receptor; photoaffinity labelling and the use of homobifunctional N-hydroxysuccinimide ester crosslinkers. The photoaffinity analogues gave poor specific: non-specific binding ratios. Of the chemical crosslinkers tested, ethylene glycolbis(succinimidylsuccinate) (EGS) was found to be the most efficient at covalently linking the 125I-XBAL bound to the LHRH receptor site. At an EGS concentration of 5 mM, 23 +/- 3% (+/- S.E.M.) of the specific binding of 125I-XBAL was covalently crosslinked.     

Rapid assay for in vitro degradation of luteinizing hormone releasing hormone

A radiochemical method for measuring luteinizing hormone releasing hormone (LHRH) degrading enzymatic activity in vitro was developed using LHRH labeled at the N-terminal 5-pyrrolidone-2-carboxylic acid (<Glu) residue. The intact labeled peptide is separated from the labeled fragments formed by cleavage by a cation-exchange batchwise procedure. The assay reflects the degradation of LHRH specifically in terms of inactivation of hormonal activity, is more rapid than a radioimmunoassay, is independent of LHRH concentration, and is not influenced by high protein concentrations. It can be used for studying the degradation of LHRH by subcellular fractions and enzymes. With this assay a highly active enzymatic degradation system was detected in the rat ovary, a recently discovered target organ for LHRH.     

Identification of luteinizing hormone releasing hormone-like immunoactivity in ovine cotyledons

Luteinizing hormone releasing hormone (LHRH)-like immunoactivity has been identified in cotyledonary extracts prepared from pregnant ewes. This activity displayed similar physico-chemical properties as synthetic LHRH, as determined by reverse-phase HPLC and size-exclusion HPLC. Under reverse-phase conditions, cotyledonary LHRH-like immunoactivity displayed a retention time (10.5 +/- 0.1 min) which was not significantly different from that of synthetic LHRH. When subjected to size-exclusion HPLC, cotyledonary LHRH-like immunoactivity eluted in fractions which corresponded to a molecular weight range of 1100-1200 Da, which was not significantly different from the elution profile observed for synthetic LHRH. The cotyledonary tissue content of LHRH-like immunoactivity averaged 94 +/- 24 pg/mg (n = 6). The results of this study demonstrate the presence of LHRH-like immunoactivity in ovine cotyledons. Although placental synthesis of LHRH-like immunoactive material has been demonstrated in other species, it remains to be established whether this activity, demonstrated in ovine placenta, is the consequence of de novo placental synthesis or represents uptake from the maternal (and/or fetal) circulation.