The Experts below are selected from a list of 63 Experts worldwide ranked by ideXlab platform
Gareth G Lavery - One of the best experts on this subject based on the ideXlab platform.
-
hexose 6 phosphate dehydrogenase h6pd and Corticosteroid Metabolism
Molecular and Cellular Endocrinology, 2007Co-Authors: Perrin C White, Daniela Rogoff, Randy D Mcmillan, Gareth G LaveryAbstract:Cortisone or (in rodents) 11-dehydrocorticosterone are reduced to cortisol or corticosterone, respectively, by the oxo-reductase activity of 11β-hydroxysteroid dehydrogenase type 1 (11-HSD1). This requires NADPH, generated by hexose-6-phosphate dehydrogenase (H6PD), a component of the pentose phosphate pathway. H6PD is located along with 11-HSD1 in the lumen of the endoplasmic reticulum (ER). Increasing or decreasing expression levels of H6PD in cultured cells has corresponding effects on the reductase activity of 11-HSD1. Mice carrying a targeted mutation in H6PD have drastically decreased 11-HSD1 oxo-reductase activity, but their 11-dehydrogenase activity is increased. They have many phenotypic features in common with mice carrying a mutation of 11-HSD1 itself. Polymorphisms in both H6PD and 11-HSD1 were originally identified in patients with apparent cortisone reductase deficiency (who have signs of hyperandrogenism and decreased urinary excretion of cortisol versus cortisone metabolites). However, these polymorphisms do not have detectable biochemical or physiologic effects when prospectively ascertained.
Eugene D Albrecht - One of the best experts on this subject based on the ideXlab platform.
-
central integrative role of oestrogen in modulating the communication between the placenta and fetus that results in primate fetal placental development
Placenta, 1999Co-Authors: Eugene D Albrecht, Gerald J PepeAbstract:Abstract This review summarizes the experimental evidence supporting the concept that oestrogen has a central integrative role in modulating the communication that occurs between the placenta and the fetus which results in primate fetal–placental development. Thus oestrogen, acting within placental trophoblasts, regulates the functional differentiation of syncytiotrophoblasts, manifested as an upregulation of key components of the progesterone biosynthetic pathway and the 11β-hydroxysteroid dehydrogenase (11β-HSD)-1 and -2 enzymes controlling cortisol–cortisone interconversion. The increase in 11β-HSD expression results in the switch in the qualitative and quantitative patterns of transplacental Corticosteroid Metabolism that induces maturation of the primate fetal hypothalamic pituitary adrenocortical axis. The studies outlined in this review, therefore, provide new insight into the role that oestrogen plays during the course of primate pregnancy and demonstrate that an oestrogen-dependent signalling system exists in utero that coordinates the placental and fetal dialogue critical to development of the placenta and endocrine systems underlying neonatal self-sufficiency.
-
developmental increase in expression of the messenger ribonucleic acid and protein levels of 11beta hydroxysteroid dehydrogenase types 1 and 2 in the baboon placenta
Endocrinology, 1996Co-Authors: Gerald J Pepe, J S Babischkin, Marcia G Burch, Maria G Leavitt, Eugene D AlbrechtAbstract:Cortisol-cortisone interconversion is catalyzed by the NADP/NADPH-dependent oxido-reductase, 11beta-hydroxysteroid dehydrogenase-1 (11betaHSD-1) and the NAD-dependent oxidase, 11betaHSD-2. Because of the importance of placental Corticosteroid Metabolism in dictating the amount of cortisol arriving in the fetus to regulate fetal pituitary-adrenocortical function, the present study determined whether there was a developmental change in the expression of 11betaHSD-1 and/or -2 in placental syncytiotrophoblast, the site of maternal:fetal exchange. A syncytiotrophoblast-enriched (>95%) cell fraction was isolated from baboon placentas obtained at early (day 60), mid (day 100), and late (day 165) gestation (term = day 184), and 11betaHSD-1 and -2 messenger RNA (mRNA) and protein levels were determined by Northern and Western blots. The levels (mean +/- SE) of the single 1.6-kilobase (kb) mRNA for 11betaHSD-1, expressed as a ratio to beta-actin, increased (P < 0.05) between early (0.36 +/- 0.16; n = 4) and mid (0.95 +/- 0.21; n = 11) gestation and further increased (P < 0.05) by late gestation (1.82 +/- 0.29; n = 13). Similarly, the levels of the single 1.9-kb mRNA for 11betaHSD-2 in late gestation (2.46 +/- 0.35; n = 8) were greater (P < 0.05) than respective values at mid (1.36 +/- 0.22; n = 8) and early (0.64; n = 2) gestation. The levels of 11betaHSD-1 (arbitrary densitometric units), detected as a dominant band of 34 kDa, were greater (P < 0.05) in late gestation (2.6 +/- 0.2; n = 4) than at early (1.2 +/- 0.1; n = 4) or mid (1.9 +/- 0.3; n = 4) gestation. In contrast, 11betaHSD-2 was not detected by Western blot in syncytiotrophoblast isolated by collagenase dispersion. However, immunocytochemistry revealed that 11betaHSD-2 was present in and localized to the syncytiotrophoblast layer of the baboon placenta and that expression in late gestation (n = 4) appeared to exceed that in placentas of early (n = 4) and mid (n = 4) gestation. These results indicate that both 11betaHSD-1 and 11betaHSD-2 were expressed in syncytiotrophoblasts of the baboon placenta and that the mRNA and protein levels of these two 11betaHSD enzymes increased with advancing gestation. However, because 11betaHSD-2 was not detected in syncytiotrophoblast isolated by collagenase dispersion, we suggest that the 11betaHSD-1 and -2 reside in different membrane fractions of the syncytiotrophoblast. Consequently, the estrogen-regulated change in transplacental cortisol Metabolism with advancing gestation may result in a developmental change in the expression and location of the two 11betaHSD enzymes controlling cortisol-cortisone Metabolism and transfer into the fetus, resulting in activation of the fetal pituitary adrenocortical system.
-
actions of placental and fetal adrenal steroid hormones in primate pregnancy
Endocrine Reviews, 1995Co-Authors: Gerald J Pepe, Eugene D AlbrechtAbstract:It is clear that steroid hormones of placental and fetal adrenal origin have critically important roles in regulating key physiological events essential to the maintenance of pregnancy and development of the fetus for extrauterine life. Thus, progesterone has suppressive actions on lymphocyte proliferation and activity and on the immune system to prevent rejection of the developing fetus and placenta (see Fig. 9). Progesterone also suppresses the calcium-calmodulin-MLCK system and thus activity of uterine smooth muscle, thereby promoting myometrial quiescence to ensure the maintenance of pregnancy. Estrogen enhances uteroplacental blood flow and possibly placental neovascularization to provide optimal gas exchange and the nutrients required for the rapidly developing fetus and placenta. In turn, estrogen has specific stimulatory effects on the receptor-mediated uptake of LDL by, and P-450scc activity within, syncytiotrophoblasts, thus promoting the biosynthesis of progesterone. Moreover, there is an estrogen-dependent developmental regulation of expression of the LDL receptor and NAD-dependent 11 beta-HSD in the placenta, processes reflecting functional/biochemical differentiation of the trophoblast cells with advancing gestation. The increase in 11 beta-HSD causes a change in transplacental Corticosteroid Metabolism, which results in activation of the HPAA in the fetus. As a result of this cascade of events, there is an increase in expression of pituitary POMC/ACTH and key enzymes, e.g. 3 beta-HSD and P-450 17 alpha-hydroxylase, important for de novo cortisol formation by, and consequently maturation of, the fetal adrenal gland. In turn, cortisol has well defined actions on surfactant biosynthesis and consequently fetal lung maturation, as well as effects on placental CRH/POMC release, which may be important to the initiation of labor. At midgestation, estrogen also selectively feeds back on the fetal adrenal to suppress DHA and maintain physiologically normal levels of estrogen. Preparation of the breast for lactation and nourishment of the newborn appears to involve a multifactorial system of regulation that includes estrogen. It is apparent, therefore, that autocrine/paracrine, as well as endocrine, systems of regulation are operative within the fetoplacental unit during primate pregnancy. A major goal of this review has been to illustrate the critically close functional communication existing between the developing placenta and fetus in the biosynthesis and the actions of steroid hormones during primate pregnancy. The functional interaction of the human fetal adrenal and placenta with respect to the biosynthesis of estrogen was demonstrated many years ago. However, the recent studies presented in this review show that the endocrine interaction between the fetus and placenta is more extensive, involving complex physiological regulatory mechanisms. Thus, as illustrated in Fig. 9, estrogen, acting via its receptor within the placenta and other reproductive tissues, orchestrates the dynamic interchange between the placenta and fetus responsible for the developmental regulation of the biosynthesis of the various steroid and peptide hormones and their receptors necessary for the maintenance of pregnancy and development of a live newborn. It would appear, therefore, that the immediate and long range challenges in this area of reproductive endocrinology are to employ in vitro molecular and in vivo experimental approaches simultaneously to elucidate the nature of these complex interactions and define the cellular and molecular mechanisms underlying these important regulatory events.
Gerald J Pepe - One of the best experts on this subject based on the ideXlab platform.
-
central integrative role of oestrogen in modulating the communication between the placenta and fetus that results in primate fetal placental development
Placenta, 1999Co-Authors: Eugene D Albrecht, Gerald J PepeAbstract:Abstract This review summarizes the experimental evidence supporting the concept that oestrogen has a central integrative role in modulating the communication that occurs between the placenta and the fetus which results in primate fetal–placental development. Thus oestrogen, acting within placental trophoblasts, regulates the functional differentiation of syncytiotrophoblasts, manifested as an upregulation of key components of the progesterone biosynthetic pathway and the 11β-hydroxysteroid dehydrogenase (11β-HSD)-1 and -2 enzymes controlling cortisol–cortisone interconversion. The increase in 11β-HSD expression results in the switch in the qualitative and quantitative patterns of transplacental Corticosteroid Metabolism that induces maturation of the primate fetal hypothalamic pituitary adrenocortical axis. The studies outlined in this review, therefore, provide new insight into the role that oestrogen plays during the course of primate pregnancy and demonstrate that an oestrogen-dependent signalling system exists in utero that coordinates the placental and fetal dialogue critical to development of the placenta and endocrine systems underlying neonatal self-sufficiency.
-
developmental increase in expression of the messenger ribonucleic acid and protein levels of 11beta hydroxysteroid dehydrogenase types 1 and 2 in the baboon placenta
Endocrinology, 1996Co-Authors: Gerald J Pepe, J S Babischkin, Marcia G Burch, Maria G Leavitt, Eugene D AlbrechtAbstract:Cortisol-cortisone interconversion is catalyzed by the NADP/NADPH-dependent oxido-reductase, 11beta-hydroxysteroid dehydrogenase-1 (11betaHSD-1) and the NAD-dependent oxidase, 11betaHSD-2. Because of the importance of placental Corticosteroid Metabolism in dictating the amount of cortisol arriving in the fetus to regulate fetal pituitary-adrenocortical function, the present study determined whether there was a developmental change in the expression of 11betaHSD-1 and/or -2 in placental syncytiotrophoblast, the site of maternal:fetal exchange. A syncytiotrophoblast-enriched (>95%) cell fraction was isolated from baboon placentas obtained at early (day 60), mid (day 100), and late (day 165) gestation (term = day 184), and 11betaHSD-1 and -2 messenger RNA (mRNA) and protein levels were determined by Northern and Western blots. The levels (mean +/- SE) of the single 1.6-kilobase (kb) mRNA for 11betaHSD-1, expressed as a ratio to beta-actin, increased (P < 0.05) between early (0.36 +/- 0.16; n = 4) and mid (0.95 +/- 0.21; n = 11) gestation and further increased (P < 0.05) by late gestation (1.82 +/- 0.29; n = 13). Similarly, the levels of the single 1.9-kb mRNA for 11betaHSD-2 in late gestation (2.46 +/- 0.35; n = 8) were greater (P < 0.05) than respective values at mid (1.36 +/- 0.22; n = 8) and early (0.64; n = 2) gestation. The levels of 11betaHSD-1 (arbitrary densitometric units), detected as a dominant band of 34 kDa, were greater (P < 0.05) in late gestation (2.6 +/- 0.2; n = 4) than at early (1.2 +/- 0.1; n = 4) or mid (1.9 +/- 0.3; n = 4) gestation. In contrast, 11betaHSD-2 was not detected by Western blot in syncytiotrophoblast isolated by collagenase dispersion. However, immunocytochemistry revealed that 11betaHSD-2 was present in and localized to the syncytiotrophoblast layer of the baboon placenta and that expression in late gestation (n = 4) appeared to exceed that in placentas of early (n = 4) and mid (n = 4) gestation. These results indicate that both 11betaHSD-1 and 11betaHSD-2 were expressed in syncytiotrophoblasts of the baboon placenta and that the mRNA and protein levels of these two 11betaHSD enzymes increased with advancing gestation. However, because 11betaHSD-2 was not detected in syncytiotrophoblast isolated by collagenase dispersion, we suggest that the 11betaHSD-1 and -2 reside in different membrane fractions of the syncytiotrophoblast. Consequently, the estrogen-regulated change in transplacental cortisol Metabolism with advancing gestation may result in a developmental change in the expression and location of the two 11betaHSD enzymes controlling cortisol-cortisone Metabolism and transfer into the fetus, resulting in activation of the fetal pituitary adrenocortical system.
-
actions of placental and fetal adrenal steroid hormones in primate pregnancy
Endocrine Reviews, 1995Co-Authors: Gerald J Pepe, Eugene D AlbrechtAbstract:It is clear that steroid hormones of placental and fetal adrenal origin have critically important roles in regulating key physiological events essential to the maintenance of pregnancy and development of the fetus for extrauterine life. Thus, progesterone has suppressive actions on lymphocyte proliferation and activity and on the immune system to prevent rejection of the developing fetus and placenta (see Fig. 9). Progesterone also suppresses the calcium-calmodulin-MLCK system and thus activity of uterine smooth muscle, thereby promoting myometrial quiescence to ensure the maintenance of pregnancy. Estrogen enhances uteroplacental blood flow and possibly placental neovascularization to provide optimal gas exchange and the nutrients required for the rapidly developing fetus and placenta. In turn, estrogen has specific stimulatory effects on the receptor-mediated uptake of LDL by, and P-450scc activity within, syncytiotrophoblasts, thus promoting the biosynthesis of progesterone. Moreover, there is an estrogen-dependent developmental regulation of expression of the LDL receptor and NAD-dependent 11 beta-HSD in the placenta, processes reflecting functional/biochemical differentiation of the trophoblast cells with advancing gestation. The increase in 11 beta-HSD causes a change in transplacental Corticosteroid Metabolism, which results in activation of the HPAA in the fetus. As a result of this cascade of events, there is an increase in expression of pituitary POMC/ACTH and key enzymes, e.g. 3 beta-HSD and P-450 17 alpha-hydroxylase, important for de novo cortisol formation by, and consequently maturation of, the fetal adrenal gland. In turn, cortisol has well defined actions on surfactant biosynthesis and consequently fetal lung maturation, as well as effects on placental CRH/POMC release, which may be important to the initiation of labor. At midgestation, estrogen also selectively feeds back on the fetal adrenal to suppress DHA and maintain physiologically normal levels of estrogen. Preparation of the breast for lactation and nourishment of the newborn appears to involve a multifactorial system of regulation that includes estrogen. It is apparent, therefore, that autocrine/paracrine, as well as endocrine, systems of regulation are operative within the fetoplacental unit during primate pregnancy. A major goal of this review has been to illustrate the critically close functional communication existing between the developing placenta and fetus in the biosynthesis and the actions of steroid hormones during primate pregnancy. The functional interaction of the human fetal adrenal and placenta with respect to the biosynthesis of estrogen was demonstrated many years ago. However, the recent studies presented in this review show that the endocrine interaction between the fetus and placenta is more extensive, involving complex physiological regulatory mechanisms. Thus, as illustrated in Fig. 9, estrogen, acting via its receptor within the placenta and other reproductive tissues, orchestrates the dynamic interchange between the placenta and fetus responsible for the developmental regulation of the biosynthesis of the various steroid and peptide hormones and their receptors necessary for the maintenance of pregnancy and development of a live newborn. It would appear, therefore, that the immediate and long range challenges in this area of reproductive endocrinology are to employ in vitro molecular and in vivo experimental approaches simultaneously to elucidate the nature of these complex interactions and define the cellular and molecular mechanisms underlying these important regulatory events.
Keigo Yasuda - One of the best experts on this subject based on the ideXlab platform.
-
altered Corticosteroid Metabolism differentially affects pituitary corticotropin response
American Journal of Physiology-endocrinology and Metabolism, 2002Co-Authors: Junko Hanafusa, Tomoatsu Mune, Tetsuya Tanahashi, Yukinori Isomura, Tetsuya Suwa, Mako Isaji, Hisashi Daido, Hiroyuki Morita, Masanori Murayama, Keigo YasudaAbstract:To evaluate the effects of altered Corticosteroid Metabolism on the hypothalamic-pituitary-adrenal axis, we examined rats treated with glycyrrhizic acid (G rats) or rifampicin (R rats) for 7 days. ...
Bernard Keavney - One of the best experts on this subject based on the ideXlab platform.
-
genotype at the p554l variant of the hexose 6 phosphate dehydrogenase gene is associated with carotid intima medial thickness
PLOS ONE, 2011Co-Authors: Thahira Rahman, Elizabeth A Walker, Bongani M Mayosi, Darroch Hall, Peter Avery, John M Connell, Hugh Watkins, Paul M Stewart, Bernard KeavneyAbstract:OBJECTIVE: The combined thickness of the intima and media of the carotid artery (carotid intima-medial thickness, CIMT) is associated with cardiovascular disease and stroke. Previous studies indicate that carotid intima-medial thickness is a significantly heritable phenotype, but the responsible genes are largely unknown. Hexose-6 phosphate dehydrogenase (H6PDH) is a microsomal enzyme whose activity regulates Corticosteroid Metabolism in the liver and adipose tissue; variability in measures of Corticosteroid Metabolism within the normal range have been associated with risk factors for cardiovascular disease. We performed a genetic association study in 854 members of 224 families to assess the relationship between polymorphisms in the gene coding for hexose-6 phosphate dehydrogenase (H6PD) and carotid intima-medial thickness. METHODS: Families were ascertained via a hypertensive proband. CIMT was measured using B-mode ultrasound. Single nucleotide polymorphisms (SNPs) tagging common variation in the H6PD gene were genotyped. Association was assessed following adjustment for significant covariates including "classical" cardiovascular risk factors. Functional studies to determine the effect of particular SNPs on H6PDH were performed. RESULTS: There was evidence of association between the single nucleotide polymorphism rs17368528 in exon five of the H6PD gene, which encodes an amino-acid change from proline to leucine in the H6PDH protein, and mean carotid intima-medial thickness (p?=?0.00065). Genotype was associated with a 5% (or 0.04 mm) higher mean carotid intima-medial thickness measurement per allele, and determined 2% of the population variability in the phenotype. CONCLUSIONS: Our results suggest a novel role for the H6PD gene in atherosclerosis susceptibility.
