Effects of growth hormone overexpression and growth hormone resistance on neuroendocrine and reproductive functions in transgenic and knock-out mice

Transgenic mice overexpressing growth hormone (GH) exhibit alterations in the function of the hypothalamic-pituitary-gonadal (HPG) axis and the H-P-adrenal axis. Alterations in the turnover of hypothalamic neurotransmitters, in plasma hormone levels, and in regulation of their release are associated with reproductive deficits, particularly in females. Results reported after publication of our minireview on this subject provided evidence that GH-transgenic mice have increased binding of GH to GH binding proteins in plasma, are hyperinsulinemic and insulin resistant, and have major alterations in energy budgets with increased allocation to growth. Reduced life span and fertility of these animals may be related to insufficient allocation of energy to reproduction and maintenance. Growth hormone resistance induced by transgenic expression of an antagonistic bGH analog or by targeted disruption (knock-out, KO) of the GH receptor (GH-R) gene leads to dramatic suppression of plasma levels of insulin-like growth factor-1 (IGF-1), and dwarf phenotype due to reduced growth and increased adiposity. In both models of GH resistance, there are marked reproductive deficits in females, decline of breeding performance of males, and alterations in the function of the HPG axis. In GH-R-KO females, puberty is delayed, and litter size is reduced. Fetal weights are reduced whereas placental weights are increased, and the weight of newborn pups is reduced despite an increase in the length of gestation. In GH-R-KO males, copulatory behavior and fertility are reduced, plasma PRL is elevated, and responses to luteinizing hormone releasing hormone (LHRH) in vivo and to LH in vitro are suppressed. However, reproductive deficits in GH-R-KO mice are very mild when compared to those described previously in IGF-KO animals. Apparently, the amounts of IGF-1 that may be produced locally in the absence of GH stimulation are sufficient for sexual maturation and fertility in both sexes, whereas quantitative deficits in reproductive function reflect absence of GH-dependent IGF-1 production and other consequences of eliminating GH signaling. The reproduction phenotype of the GH-R-KO mice is also mild when compared to dwarf mice that lack GH, prolactin (PRL), and thyroid stimulating hormone (TSH). This is presumably related to the presence of redundant mechanisms in the stimulatory control of the gonads by the pituitary and the ability of animals capable of producing PRL and TSH to compensate partially for the absence of GH signaling.     

Haploinsufficiency of the follicle-stimulating hormone receptor accelerates oocyte loss inducing early reproductive senescence and biological aging in mice

Female mice that are null for the FSH-receptor (FSH-R) gene are estrogen deficient, acyclic, and sterile. However, the heterozygous (+/-) mice initially have reduced fertility and stop breeding by 7-9 mo. The purpose of this study was to understand the basis of reduced fertility in mice with haploinsufficiency of the FSH-R. Heterozygous females were compared to +/+ females at 3, 7, and 12 mo of age. By 7 mo most of the +/- females were acyclic and <50% delivered pups. The wild-type females were normal in these respects. None of the 1-yr-old +/- females gave viable offspring (73% in +/+). Many degenerative changes, including atresia and apoptosis, and profound loss of oocytes, were apparent in +/- mice by 7 mo. The 1-yr-old +/- ovary had very few follicles and consisted mostly of fibroid tissue and cysts. Our data support the hypothesis that reproductive deficits in +/- FSH-R mice occur because of accelerated oocyte loss due to increased cell death in the ovary. These events contribute to early reproductive senescence and biological aging in mice. Thus FSH-R status is an important determinant of ovarian aging and all phenomena that arise from subsequent estrogen deficiency and other aberrations.     

Early obesity and age-related mimicry of metabolic syndrome in female mice with sex hormonal imbalances

Objective: To investigate the relationship of early obesity to metabolic syndrome during sex hormonal imbalances in mutant female mice at different ages. Research Methods and Procedures: Hormonal imbalances, accumulation and nature of adipose tissue, food intake, glucose tolerance, and expression of candidate genes and markers of inflammation were studied by comparing wild‐type, null, and haploinsufficient follitropin receptor knockout female mice at different ages. Results: Follitropin receptor deletion in mice produced null females that are infertile and haploinsufficient mice that undergo accelerated biological aging. Both types of mutants with sex hormonal imbalances have central obesity without hyperphagia, but circulating leptin is elevated. Adipocyte hyperplasia and hypertrophy is attributed to elevated peroxisome proliferator‐activated receptor γ expression. Adiponectin protein levels increase in fat tissue and plasma. Only mutants but not controls acquire age‐dependent decline in glucose tolerance with high insulin and altered pancreatic β cells. Changes in inflammation markers, decreased muscle insulin receptor phosphorylation, and increase of the enzyme protein tyrosine phosphatase 1B indicate insulin resistance. Discussion: In this animal model, the chronological appearance of early obesity induced by hormonal imbalances culminates in characteristics that are attributable to metabolic syndrome, including cardiovascular abnormalities. Dissection of the depot‐specific alterations and defining molecular interrelationships could help in developing targeted remedies and resolving complications and controversies related to health benefits and adversities of current hormone replacement therapy.     

Interrelation between NO and H2O2 formation and their role in the regulation of ion homeostasis of cells

The review deals with some problems of formation, utilization and functioning two of the most important and the lest cytotoxic active oxidative metabolites--NO and H2O2. The interrelation of NO and H2O2 cellular metabolism is reviewed. There are literature data regarding NO and H2O2 significance in the cellular signalling transduction and tissues paracrine regulation. The peculiar attention is dedicated to NO and H2O2 significance in the smooth muscle cells ion homeostasis regulation particularly in the uterus. As well there are the own author's data evidencing about the composite and ambiguous concentration-dependent physiological action of these metabolites. Varying in level in the cells NO and H2O2 may have a cyclic character similar to the oscillations of some other signaling molecules concentrations, evidently playing an important role in the mechanisms of cellular signal transduction and in the paracrine system.     

Reduced levels of thyroid hormones, insulin, and glucose, and lower body core temperature in the growth hormone receptor/binding protein knockout mouse

The mechanisms that are responsible for the extension of lifespan in the mouse with targeted disruption (knockout [KO]) of the growth hormone (GH) receptor/binding protein (GHR-KO) are unknown. However, in the long-living Ames dwarf mouse, blood glucose and body core temperature (Tco) are consistently lower than in normal mice. In addition, insulin levels are reduced and corticosterone levels are elevated in male dwarfs. These functional alterations, similar to those seen in animals under caloric restriction, have not been proven to be causally related to the extension of lifespan, but they do provide some insight into what traits may be necessary for long life. Therefore, to investigate which of these parameters are similarly affected in two genetically unrelated, yet similarly long-living mouse models, we measured Tco, thyroid hormones (triiodothyronine [T3] and thyroxine [T4]), and insulin, in addition to morning and afternoon levels of glucose and corticosterone, in young adult male and/or female GHR-KO mice and their normal siblings. Tco in GHR-KO mice was numerically reduced throughout the 24-hr period; however, these differences were only significant 4 hr prior to lights-off (14:00 hr), immediately after lights-off (18:00 hr), and during the 3 hr preceding lights on (03:00 to 06:00 hr). GHR-KO mice had significantly reduced levels of T3 and T4, while the ratio of these hormones was similar to that in normal mice. Insulin levels in GHR-KO mice were lower than in normal mice; levels in male GHR-KO mice were below the detectable limits of the assay used. Glucose levels in GHR-KO mice (male and females) were lower than in normal mice in measurements taken in both morning and afternoon; however, these differences arose from consistent reductions in males, as morning glucose levels in GHR-KO females were similar to those of normal mice. Corticosterone levels measured in blood plasma collected under basal (nonstressed) conditions showed sex-related alterations. Basal corticosterone levels in female GHR-KO mice were similar to normal females, while those in male GHR-KO mice were higher than in normal males in the afternoon. Corticosterone levels in stressed GHR-KO females were similar to those measured in stressed normal females. These data show that the long-living GHR-KO mouse shares a reduction in glucose, insulin, thyroid hormones, and Tco with the Ames dwarf mouse. Reductions in these parameters may be important to the underlying mechanisms of delayed aging in these animals.     

Mechanisms of Ca2+ transport to the cytoplasm of muscle cells, role of protons and active nitrogen (oxygen) metabolites in these processes

Separate pictures of transmission mechanisms of Ca(2+)-signal are discussed, and first of all in the muscle cells. Literary and own data about possible interrelation of Ca2+ and H+ metabolism are analysed. Supposition about the important role of H+ on the first stages of activating the muscle cells is expressed. The role of active nitrogen and oxygen metabolites are discussed.