Your search keyword '"Macdonald GJ"' showing total 16 results

1. Partial restoration of lutropin activity by an intersubunit disulfide bond: implications for structure/function studies.

Author

Einstein M, Lin W, MacDonald GJ, and Moyle WR

Subjects

Animals, COS Cells, Chlorocebus aethiops, Chorionic Gonadotropin, beta Subunit, Human chemistry, Chorionic Gonadotropin, beta Subunit, Human genetics, Cystine, Follicle Stimulating Hormone metabolism, Glycoprotein Hormones, alpha Subunit chemistry, Glycoprotein Hormones, alpha Subunit genetics, Humans, Protein Structure, Secondary, Structure-Activity Relationship, Chorionic Gonadotropin, beta Subunit, Human metabolism, Disulfides metabolism, Glycoprotein Hormones, alpha Subunit metabolism, Luteinizing Hormone metabolism

Abstract

Gonadal function is controlled by lutropins and follitropins, heterodimeric cystine knot proteins that have nearly identical alpha-subunits. These heterodimeric proteins are stabilized by a portion of the hormone-specific beta-subunit termed the "seatbelt" that is wrapped around alpha-subunit loop 2 (alpha 2). Here we show that replacing human chorionic gonadotropin (hCG) alpha 2 residue Lys51 with cysteine or alanine nearly abolished its lutropin activity, an observation that implies that alpha Lys51 has a key role in hormone activity. The activity of the heterodimer containing alpha K51C, but not that containing alpha K51A, was increased substantially when beta-subunit seatbelt residue beta Asp99 was converted to cysteine. As had been reported by others, heterodimers containing alpha K51C and beta D99C were crosslinked by a disulfide. The finding that an intersubunit disulfide restored some of the activity lost by replacing alpha Lys51 suggests that this residue is not crucial for receptor binding or signaling and also that hCG and related hormones may be particularly sensitive to mutations that alter interactions between their subunits. We propose the unique structures of hCG and related family members may permit some subunit movement in the heterodimer, making it difficult to deduce key residues involved in receptor contacts simply by correlating the activities of hormone analogs with their amino acid sequences.

Published

2001

2. The groove between the alpha- and beta-subunits of hormones with lutropin (LH) activity appears to contact the LH receptor, and its conformation is changed during hormone binding.

Author

Cosowsky L, Rao SN, Macdonald GJ, Papkoff H, Campbell RK, and Moyle WR

Subjects

Amino Acid Sequence, Animals, Base Sequence, Binding Sites, Chorionic Gonadotropin chemistry, Chorionic Gonadotropin genetics, Chorionic Gonadotropin metabolism, Conserved Sequence, DNA Primers genetics, Epitope Mapping, Follicle Stimulating Hormone chemistry, Follicle Stimulating Hormone genetics, Follicle Stimulating Hormone metabolism, Humans, Luteinizing Hormone genetics, Models, Molecular, Molecular Sequence Data, Protein Conformation, Protein Folding, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Luteinizing Hormone chemistry, Luteinizing Hormone metabolism, Receptors, LH metabolism

Abstract

Gonadotropins are heterodimeric glycoprotein hormones that control vertebrate fertility through their actions on gonadal lutropin (luteinizing hormone, LH) and follitropin (follicle-stimulating hormone, FSH) receptors. The beta-subunits of these hormones control receptor binding specificity; however, the region of the beta-subunit that contacts the receptor has not been identified. By a process of elimination we show this contact to be the portions of beta-subunit loops one and three found in a hormone groove created by the juxtaposition of the alpha- and beta-subunits. Most other regions of the beta-subunit can be recognized by antibodies that bind to human chorionic hormone (hCG)-receptor complexes or replaced without disrupting hormone function. Using a series of bovine LH/hCG and human FSH/hCG beta-subunit chimeras we identified key hCG beta-subunit residues in the epitopes of two antibodies that bind to hCG-receptor complexes. These epitopes include the surfaces of beta-subunit loops one and three near residue 74 on the outside of the hormone groove and parts of the C-terminal end of the "seat belt" that holds the two subunits together. The antibody that recognized residue 74 bound to receptor complexes containing most mammalian lutropins better than to the free hormones, an indication that the outside surface of the beta-subunit groove is altered during hormone binding. This region of the beta-subunit is furthest from the alpha-subunit and is recognized equally well in the free beta-subunit and in the heterodimer. Thus, the receptor associated increase in antibody binding appears due to an interaction of this portion of the beta-subunit with the receptor and not to an effect of the receptor on the relative positions of the alpha- and beta-subunits. Unlike most previous studies designed to identify portions of the beta-subunit likely to contact the LH receptor, this indirect approach provides data that are more easily interpreted because it does not rely on the use of mutations that disrupt hormone function. The approach described here should be valuable for studying the receptor interactions of other complex ligands.

Published

1995

3. Luteolysis is linked to luteinizing hormone-induced depletion of adenosine triphosphate in vivo.

Author

Soodak LK, MacDonald GJ, and Behrman HR

Subjects

Adenosine Diphosphate metabolism, Adenosine Monophosphate metabolism, Animals, Corpus Luteum cytology, Corpus Luteum drug effects, Female, Guanosine Triphosphate metabolism, Hypophysectomy, Kinetics, Ovary drug effects, Rats, Rats, Inbred Strains, Adenosine Triphosphate metabolism, Corpus Luteum metabolism, Luteinizing Hormone pharmacology, Ovary metabolism

Abstract

An elevation of ATP levels in luteal cells markedly enhances their response to gonadotropin. In contrast, depletion of ATP in all cells leads to a series of interrelated events that produces irreversible cell injury. Since the corpus luteum has a transient existence, functional regression and involution of this gland play a fundamental role in the regulation of reproduction. The objective of the present studies was to evaluate whether the luteal ATP content may be regulated in an endocrine fashion and whether luteolysis may be linked to depletion of ATP in the corpus luteum in vivo. The present studies show that removal of the pituitary, maintenance of luteal function in hypophysectomized rats with PRL, or acute treatment with prostaglandin F2 alpha had no effect on luteal ATP levels. However, LH produced a rapid and marked decrease in adenine nucleotide levels in both intact and hypophysectomized PRL-replaced rats, whereas GTP levels were unaffected. In pituitary-intact rats, this same effect of LH occurred within 5 min, was maximal (40% depletion) within 30 min, and was sustained for many hours. Depletion of ATP by LH was dose dependent and evident with low doses of LH. In addition, a decrease in luteal ATP levels was seen during functional luteolysis in the rat, which was directly related to a rise in the serum levels of LH, but not FSH. In contrast, LH had no effect on ATP depletion in isolated cells prepared from the total luteinized ovary, or in enriched preparations of luteal cells. Thus, the depletion of ATP by LH in vivo appears to be mediated by intraovarian agents of unknown nature. We suggest that the rise in LH levels that follows functional luteolysis, due to reduced negative feedback by progesterone, produces a rapid decrease in luteal ATP levels which induces irreversible cell damage and, ultimately, involution of the corpus luteum. This effect would, presumably, be exacerbated as LH levels rise to maximum at ovulation or until LH receptors become down-regulated.

Published

1988

4. Maintenance of pregnancy in the rat in the absence of LH.

Author

MacDonald GJ

Subjects

Animals, Antibodies, Antigen-Antibody Reactions, Embryo Implantation drug effects, Estradiol pharmacology, Female, Fetal Resorption etiology, Hypophysectomy, Luteinizing Hormone immunology, Pituitary Gland physiology, Rats, Luteinizing Hormone pharmacology, Pregnancy drug effects, Pregnancy Maintenance drug effects

Published

1978

5. Transport and selective utilization of adenosine as a prosubstrate for luteinizing hormone-sensitive adenylate cyclase in the luteal cell.

Author

Behrman HR, Ohkawa R, Preston SL, and MacDonald GJ

Subjects

Animals, Biological Transport drug effects, Cyclic AMP metabolism, Dipyridamole pharmacology, Female, Hypophysectomy, Rats, Rats, Inbred Strains, Adenosine metabolism, Adenylyl Cyclases metabolism, Corpus Luteum enzymology, Luteal Cells enzymology, Luteinizing Hormone pharmacology

Abstract

The objective of the present studies was to examine adenosine uptake in the rat luteal cell, to characterize the cellular products after uptake, and to assess the role of adenosine transport and conversion to cAMP in amplification of LH-stimulated cAMP accumulation. Adenosine uptake showed an apparent Km of 7.3 +/- 0.6 microM, and a maximum velocity of 2.2 +/- 1.4 pmol/min X 10(5) cells at 24 C; uptake was temperature dependent (Q10 = approximately 3) and inhibited by dipyridamole (IC50 = 7 microM). Radiolabeled adenosine uptake was inhibited by AMP (IC50 = 14 microM), ATP (IC50 = 16 microM), guanosine (IC50 = 20 microM), inosine (IC50 = 22 microM), ADP (IC50 = 26 microM), and theophylline (IC50 = 5 mM); no inhibition by adenine, hypoxanthine, xanthine, prostaglandin F2 alpha (PGF2 alpha), PGE2, or LH was seen. Cellular products of radiolabeled adenosine uptake were found primarily in the trichloroacetic acid-soluble fraction (88%), and 90% of the radioactivity in this fraction comigrated with adenine nucleotides on electrophoresis; time-dependent incorporation of radioactivity into RNA, DNA, and protein was also seen. Adenosine transport did not appear to be related to the functional state of the luteal cell; for example, no change in the characteristics of uptake was seen in cells obtained from hypophysectomized animals or in cells incubated directly with PGF2 alpha or LH. Adenosine increased cell ATP levels in a dose-dependent manner in parallel with amplification of LH-stimulated cAMP accumulation. A substantial proportion of the total cAMP produced by the cells was derived from extracellular adenosine (40-90%). This response was directly related to the concentration of adenosine, and LH increased the magnitude of cAMP derived from adenosine by about 2-fold. Based on the present studies, adenosine uptake in the luteal cell appears to occur by a dipyridamole-sensitive, phosphorylation-dependent transport system which is independent of pituitary hormones or PG regulation. Moreover, amplification of LH-dependent cAMP accumulation by adenosine appears to be primarily a mass effect due chiefly to utilization of extracellular adenosine by the cell as a prosubstrate for conversion into cAMP by adenylate cyclase.

Published

1983

6. Effect of hypophysectomy, prolactin, and prostaglandin F2 alpha on gonadotropin binding in vivo and in vitro in the corpus luteum.

Author

Behrman HR, Grinwich DL, Hichens M, and MacDonald GJ

Subjects

Animals, Chorionic Gonadotropin metabolism, Corpus Luteum drug effects, Female, In Vitro Techniques, Kinetics, Prolactin metabolism, Rats, Receptors, Cell Surface drug effects, Corpus Luteum metabolism, Hypophysectomy, Luteinizing Hormone metabolism, Prolactin pharmacology, Prostaglandins F pharmacology, Receptors, Cell Surface metabolism

Published

1978

7. Initiation of blastocyst implantation by luteinizing hormone.

Author

Macdonald GJ, Armstrong DT, and Greep RO

Subjects

Animals, Estradiol, Estrogens physiology, Female, Hypophysectomy, Ovary physiology, Pituitary Gland transplantation, Pregnancy, Progesterone, Prolactin, Rats, Transplantation, Autologous, Embryo Implantation, Luteinizing Hormone pharmacology, Pregnancy, Animal

Published

1967

8. Involvement of luteinizing hormone as a luteotropin in the golden hamster.

Author

Raj HG, Macdonald GJ, and Greep RO

Subjects

Animals, Female, Fetal Death etiology, Follicle Stimulating Hormone pharmacology, Hypophysectomy, Luteinizing Hormone antagonists & inhibitors, Luteinizing Hormone pharmacology, Pituitary Gland physiology, Pregnancy, Prolactin pharmacology, Uterine Hemorrhage etiology, Corpus Luteum physiology, Cricetinae physiology, Luteinizing Hormone physiology

Published

1974

9. Prolactin-induced morphological luteal regression unaffected by LH.

Author

Macdonald GJ and Greep RO

Subjects

Animals, Corpus Luteum drug effects, Female, Hypophysectomy, Organ Size, Ovary anatomy & histology, Rats, Corpus Luteum physiology, Luteinizing Hormone pharmacology, Prolactin pharmacology

Published

1969

10. Ability of luteinizing hormone (LH) to acutely increase serum progesterone levels during the secretory phase of the rhesus menstrual cycle.

Author

Macdonald GJ and Greep RO

Subjects

Animals, Female, Follicle Stimulating Hormone administration & dosage, Follicle Stimulating Hormone pharmacology, Haplorhini physiology, Immune Sera, Kinetics, Luteinizing Hormone administration & dosage, Macaca, Menstruation, Progesterone metabolism, Prolactin pharmacology, Rabbits immunology, Time Factors, Luteinizing Hormone pharmacology, Progesterone blood

Published

1972

11. Stimulation of estrogen secretion from normal rat corpora lutea by luteinizing hormone.

Author

Macdonald GJ, Armstrong DT, and Greep RO

Subjects

Adrenal Glands, Animals, Estradiol pharmacology, Estrus, Female, Hypophysectomy, Organ Size, Ovary, Pituitary Gland transplantation, Pregnancy, Rats, Transplantation, Autologous, Transplantation, Homologous, Uterus, Vagina anatomy & histology, Corpus Luteum drug effects, Corpus Luteum physiology, Estrogens metabolism, Luteinizing Hormone pharmacology

Published

1966

12. Role of endogenous primate LH in maintaining corpus luteum function in the monkey.

Author

Moudgal NR, Macdonald GJ, and Greep RO

Subjects

Animals, Antigen-Antibody Complex, Binding Sites, Chorionic Gonadotropin, Corpus Luteum drug effects, Corpus Luteum metabolism, Cross Reactions, Female, Goats, Haplorhini, Immune Sera pharmacology, Immunodiffusion, Iodine Isotopes, Macaca, Ovulation drug effects, Progesterone metabolism, Protein Binding, Rabbits, Radioimmunoassay, Corpus Luteum physiology, Luteinizing Hormone physiology

Published

1972

13. Influence of various doses of LH on fetal survival in hypophysectomized rats.

Author

Yoshinaga K, Macdonald GJ, and Greep RO

Subjects

Animals, Corpus Luteum physiology, Estrogens metabolism, Female, Hypophysectomy, Luteinizing Hormone administration & dosage, Pregnancy, Progesterone metabolism, Pseudopregnancy, Rats, Stimulation, Chemical, Fetal Death, Luteinizing Hormone pharmacology, Pregnancy, Animal drug effects

Published

1972

14. Ovarian function and progestin content in response to gonadotrophins.

Author

Macdonald GJ

Subjects

Animals, Cholesterol analysis, Estrogens metabolism, Estrus, Female, Hypophysectomy, Ovary analysis, Pregnancy, Pregnanes analysis, Rats, Sterols analysis, Uterus physiology, Vaginal Smears, Luteinizing Hormone pharmacology, Ovary drug effects, Progesterone analysis, Prolactin pharmacology

Published

1969

15. Inability of LH administered in a delay vehicle to maintain luteal function.

Author

Macdonald GJ and Greep RO

Subjects

Animals, Corpus Luteum drug effects, Delayed-Action Preparations, Female, Hypophysectomy, Leukocytes, Luteinizing Hormone physiology, Pregnancy, Pregnancy, Animal, Rats, Vaginal Smears, Corpus Luteum metabolism, Luteinizing Hormone administration & dosage, Pharmaceutical Vehicles, Progesterone metabolism

Published

1970

16. Bioimmunoassay (BIA): A Sandwich Immunoassay Scheme Employing Monoclonal Antibodies and Hormone Receptors to Quantify Analytes

Author

Armstrong Eg, William R. Moyle, Anderson Dm, and Macdonald Gj

Subjects

Pharmacology, Analyte, biology, medicine.drug_class, Chemistry, Radioimmunoassay, Antibodies, Monoclonal, Receptors, Cell Surface, Luteinizing Hormone, Receptors, LH, Ligands, Monoclonal antibody, Chorionic Gonadotropin, Molecular biology, Epitope, Rats, Antigen, Hormone receptor, medicine, biology.protein, Radioligand, Animals, Female, Antibody, Receptor

Abstract

When some antigens bind to receptors, a portion of the antigen remains exposed and can be recognized by labeled monoclonal antibodies. By measuring the amount of antibody bound to the antigen-receptor complex, one can quantify the amount of antigen that is present. Since this assay procedure depends on simultaneous receptor recognition of a biologically active site and antibody recognition of a distal epitope on the analyte, we call it a bioimmunoassay. Bioimmunoassays have many of the advantages of radioligand receptor assays (RRA) used to quantify biological activity and, depending on the choice of antibodies employed, may be more specific than RRA. In addition, since they are sandwich assays, they are usually more sensitive than RRA. Bioimmunoassays can be performed in several different modes and in the case described here we used a radiolabeled antibody to detect hormone-receptor complexes. Hence we term this example a bio-immunoradiometric assay or BIO-IRMA. We illustrate the properties of various assay procedures using a monoclonal antibody to the beta subunit of hCG which recognizes an epitope common to all other mammalian LH/hCG-like gonadotropins and which is capable of detecting 10 pg of hCG standard. In principle, this assay can be applied to any material capable of binding to a receptor, enzyme, etc. which can also be recognized by an antibody. Since it is a sandwich type of assay, it is subject to the same advantages and limitations of other sandwich assays except that it can be used to discriminate some biologically active and inactive analytes. Monoclonal antibodies which are prepared from spleen cells of animals immunized with antigen-receptor complexes and selected for their ability to bind antigen-receptor complexes should prove most useful for bioimmunoassay procedures.

Published

1988