Effect of protracted estrogen administration on the thyroid of Ames dwarf mice

The effect of protracted estrogen administration on estrogen receptor expression and cellular composition of the thyroid was examined in genetically thyrotropin (TSH)-deficient female Ames dwarf mice (df/df) to reveal whether estrogen might act independently from TSH. inducing changes in thyroid morphology and function. To evaluate such changes, the thyroid from four estrogen-implanted Ames dwarf mice, four sham-implanted Ames dwarf mice and four sham-implanted normal littermate mice were investigated histologically, immunohistochemically and morphometrically. Our morphologic study demonstrated significant differences in the colloid areas of normal and dwarf mice (P<0.001). The correlation observed between this parameter and body weights (r=0.610, P<0.05) and thyroid weights (r=0.729, P<0.01) suggests that the decrease in the colloid areas is not a result of abnormal folliculogenesis but is in direct correlation with the small thyroid and body size of dwarf mice. Although two types of estrogen receptors are known to exist in the present study, only the alpha (ERalpha) variant was found in the thyroid. ERalpha immunoreactivity was detected in the nuclei of parafollicular cells but not of the follicular epithelium. No significant differences were reported in ER expression between estrogen-implanted dwarf mice and sham-implanted dwarf mice, suggesting that estrogen receptor expression in the thyroid is independent of circulating estrogen levels. In spite of the absence of ERalpha in follicular cells, protracted estrogen administration affected mainly the follicular cells. Our results suggest that when TSH is absent estrogens may exert a negative feedback on the activity of follicular cells.     

Estimation of thyroid gland activity in the Snell dwarf mouse by ultrastructural observation of the thyroid gland, measurement of plasma thyroxine concentration and thyroid hormone binding capacity

An ultrastructural study of the thyroid gland of the Snell dwarf mouse showed cellular activity to be very low. Follicle cell diameters were significantly lower than in controls whilst the nucleocytoplasmic ratio was significantly higher. The observed cellular activity of the thyroid cells was associated with circulating levels of thyroxine which were found to be significantly lower than in controls. Measurement of the free thyroxine index showed very little free hormone available for tissue uptake. No differences in thyroid function due to age or sex in the dwarf mice were seen. Possible endocrine imbalances contributing to the low thyroid activity in the Snell dwarf mouse are discussed.     

A novel hypothyroid dwarfism due to the missense mutation Arg479Cys of the thyroid peroxidase gene in the mouse

Recently, we found a novel dwarf mutation in an ICR closed colony. This mutation was governed by a single autosomal recessive gene. In novel dwarf mice, plasma levels of the thyroid hormones, T3 and T4, were reduced; however, TSH was elevated. Their thyroid glands showed a diffuse goiter exhibiting colloid deficiency and abnormal follicle epithelium. The dwarfism was improved by adding thyroid hormone in the diet. Gene mapping revealed that the dwarf mutation was closely linked to the thyroid peroxidase (Tpo) gene on chromosome 12. Sequencing of the Tpo gene of the dwarf mice demonstrated a C to T substitution at position 1508 causing an amino acid change from arginine (Arg) to cysteine (Cys) at codon 479 (Arg479Cys). Western blotting revealed that TPO protein of the dwarf mice was detected in a microsomal fraction of thyroid tissue, but peroxidase activity was not detected. These findings suggested that the dwarf mutation caused a primary congenital hypothyroidism by TPO deficiency, resulting in a defect of thyroid hormone synthesis.     

Fine-structural and immunohistochemical study of anterior pituitary cells of Snell dwarf mice

Summary Snell dwarf mice display remarkable retardation of growth after birth and are known to lack prolactin (PRL), thyroid stimulating hormone (TSH) and growth hormone (GH). The aim of this study was to determine the reason for these hormonal deficiencies. We examined the fine structure of the gland and its immunohistochemical staining pattern with respect to antisera raised against PRL, TSH, GH, adrenocorticotrophic hormone (ACTH) and luteinizing hormone (LH). The gland of control mice reacted immunohistochemically against all antisera used, whereas only ACTH-producing cells (ACTH cells) and LH-producing cells (LH cells) were distinguished in the dwarf mice. ACTH cells in dwarf mice varied in cell shape, although they were similar in size to those of controls. The distribution of secretory granules in the cytoplasm varied from cell to cell. LH cells in the dwarf mice showed immature features, having poorly developed rough endoplasmic reticulum and Golgi apparatus. The cells were about half the size of controls, and secretory granules were smaller. In dwarf mice, non-granulated cells were encountered in addition to granulated ACTH and LH cells. Some of them formed small clusters, characteristic cell junctions being found between the cells; they thus appeared to be follicular cells. The above results suggest that hormone deficiency in Snell dwarf mice is a result of a defect in the hormoneproducing cells in the gland.     

Hereditary pituitary dwarfism in mice affects skeletal and cardiac myosin isozyme transitions differently

The dwarf mutation in mice interferes with the development of those anterior pituitary cells responsible for production of thyroid stimulating hormone, growth hormone, and prolactin. Myosin isozyme transitions in both cardiac and skeletal muscle were also found to be affected in this mutant. Electrophoresis of native myosins demonstrated that the fetal (V3) to adult (V1) ventricular cardiac isozyme transition was completely blocked in dwarf mice; in contrast, the neonatal to adult fast myosin transition in hind limb skeletal muscle was slowed but not totally inhibited. The persistence of neonatal myosin heavy chain for up to 55-75 d after birth in dwarf mice, as compared with 16 d in normal mice, was directly demonstrated by polypeptide and immunopolypeptide mapping. Morphological examination of 18-36-d-old dwarf skeletal muscles by optical and electron microscopy revealed a relative immaturity, but no signs of gross pathology were evident. Immunocytochemical analysis showed that the abnormal persistence of neonatal myosin occurs in most of the fibers. Multiple injections of thyroxine restored a normal isozyme complement to both cardiac and skeletal muscles within 11-15 d. Therefore, the effects of the dwarf mutation on myosin isozymes can be explained by the lack of thyroid hormone in these animals. Because the synthesis of growth hormone is not stimulated by thyroid hormone in dwarf mice as it would be in normal animals, these results demonstrate that thyroid hormone promotes myosin isozyme transitions independent of growth hormone production.     

Evidence that Ames dwarf mice age differently from their normal siblings in behavioral and learning and memory parameters

There is strong evidence supporting the deleterious effects of aging on learning and memory and behavioral parameters in normal mice. However, little is known about the Ames dwarf mouse, which has a Prop-1 gene mutation resulting in deficiencies in growth hormone, thyroid-stimulating hormone, and prolactin. These mice are much smaller and live significantly longer than their normal siblings. Using the elevated plus-maze, locomotor activity meters, and an inhibitory avoidance learning task, the present study compared Ames dwarf mice to their normal siblings. Results showed that Ames dwarf mice did not experience an age-related decline in locomotor activity when compared to their young counterparts. Furthermore, old dwarf mice did not differ from the young groups in inhibitory avoidance retention, while old normal animals performed more poorly than both young groups on this test. Elevated plus-maze behavior did not differ in the old normal versus dwarf groups, but the old groups did differ from the young. Results indicate that both old groups experienced a significant decline in anxiety with age. Taken together, these results indicate that multiple hormone deficiencies resulting from a lack of primary pituitary function have beneficial effects on cognitive function and locomotor behavior in advanced age. In fact, the Ames dwarf mouse may provide a model for studies of delayed mental as well as physical aging.     

VCAM‐1 upregulation accompanies muscle remodeling following resistance‐type exercise in Snell dwarf (Pit1dw/dw) mice

Snell dwarf mice (Pit1^dw/dw) exhibit deficiencies in growth hormone, prolactin, and thyroid stimulating hormone. Besides being an experimental model of hypopituitarism, these mice are long‐lived (>40% lifespan extension) and utilized as a model of slowed/delayed aging. Whether this longevity is accompanied by a compromised quality of life in terms of muscular performance has not yet been characterized. In this study, we investigated nontrained and trained muscles 1 month following a general validated resistance‐type exercise protocol in 3‐month‐old Snell dwarf mice and control littermates. Nontrained Snell dwarf gastrocnemius muscles exhibited a 1.3‐fold greater muscle mass to body weight ratio than control values although muscle quality, maximum isometric torque normalized to muscle mass, and fatigue recovery were compromised. For control mice, training increased isometric torque (17%) without altering muscle mass. For Snell dwarf mice, isometric torque was unaltered by training despite decreased muscle mass that rendered muscle mass to body weight ratio comparable to control values. Muscle quality and fatigue recovery improved twofold and threefold, respectively, for Snell dwarf mice. This accompanied a fourfold increase in levels of vascular cell adhesion molecule‐1 (VCAM‐1), a mediator of progenitor cell recruitment, and muscle remodeling in the form of increased number of central nuclei, additional muscle fibers per unit area, and altered fiber type distribution. These results reveal a trade‐off between muscle quality and longevity in the context of anterior pituitary hormone deficiency and that resistance‐type training can diminish this trade‐off by improving muscle quality concomitant with VCAM‐1 upregulation and muscle remodeling.     

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.     

Thyroid hormone and growth: relationships with growth hormone effects and regulation

For some years, research in the field of growth endocrinology has been mainly focused on growth hormone (GH). However, it appears that GH does not always control growth rate. For instance, it does not clearly influence intra-uterine growth: moreover, although the results of GRF or GH administration appear convincing in rats, pigs or heifers, this is not the case in chickens and lambs. In addition, GH does not always clearly stimulate somatomedin production, particularly diring food restriction and fetal life, and in hypothyroid animals or sex-linked dwarf chickens. In such situations, this phenomenon is associated with a reduced T3 production, suggesting a significant influence of thyroid function on GH action, and more generally, on body growth. In fact, numerous data demonstrate that thyroid hormone is strongly involved in the regulation of body growth. In species with low maturity at birth, such as the rat. T4 and T3 affect postnatal growth eleven days earlier than the appearance of GH influence. In contrast to GH, thyroid hormone significantly influences fetal growth in sheep. Moreover, the body growth rate is clearly stimulated by T3 in dwarf animals. In addition to its complex metabolic effects involved in the general mechanisms of body growth, thyroid hormone stimulates the production of growth factors, particularly EGF and NGF. Moreover, it affects GH and somatomedin production and also their tissue activity. All these results strongly suggest that it would be difficult to study GH regulation and physiological effects without taking thyroid function into account.     

Effect of MPTP on Dopamine Metabolism in Ames Dwarf Mice

Hypopituitary dwarf mice exhibit a heightened antioxidative capacity and live extensively longer than age-matched controls. Importantly, dwarf mice resist peripheral oxidative stress induced by paraquat, and behaviorally, they maintain cognitive function and locomotor activity at levels above those observed in old wild-type animals. We assessed monoaminergic neurotransmitters in nigrostriatal tract and cerebellum after the administration of the dopaminergic neurotoxin, MPTP. There was no significant change in mitochondrial monoamine oxidase (MAO)-B and total MAO activity in the substantia nigra and nucleus caudatus putamen of wild-type and dwarf mice. Coenzymes Q-9 and Q-10 were present in similar quantities, as were dopamine, norepinephrine, and serotonin levels in the cerebellum and nigrostriatal tract. MPTP set off tremor, hind limb abduction, and straub tail behavior and induced significant dopamine depletion in the striatum of both dwarf and normal mice. This study shows that the MAO activity and the coenzyme content of dwarf mice are similar to those of their wild-type controls and hence susceptible to MPTP-induced toxicity.     

Immunologic disparity in the hypopituitary dwarf mouse.

The Snell-Bagg hypopituitary dwarf mouse has been shown to be deficient in growth hormone, thyroxine, and prolactin. There are reports indicating that in addition to these neuroendocrine abnormalities, development of immune competence is also severely impaired in these animals. However, other studies indicate that the immunologic potential of these mice does not differ from their heterozygous littermate controls. Our data show that dwarf mice weaned at 21 days of age and killed at that time, or 7 days later, have reduced numbers of cells in both the spleen and thymus and the mitogen responsiveness of these cells is impaired. However, if mice weaned on day 21 are analyzed at 32 days of age or the mice are weaned at day 30 and analyzed 7 days later the ability to respond to mitogenic stimulation does not differ from controls. Further experiments show that dwarf mice weaned at 30 days of age have a normal complement of V-beta TCR as evidenced by immunofluorescence analysis as well as a primary antibody response to SRBC equivalent to that observed in normal littermates. Immunofluorescence analysis of CD4 and CD8 expression on thymocytes obtained from dwarf mice shows a distinct pattern dependent on the time of weaning and time of analysis. Initial analysis of thymocytes from dwarf mice weaned and killed at 21 days of age do not differ from controls. However, cells from dwarf mice weaned on day 21 and killed on day 28 are markedly different with a loss of immature CD4+/CD8+ cells and a corresponding increase in CD4+ and CD8+ mature thymocytes. In contrast, the phenotype of thymocytes obtained from dwarf mice weaned at 30 days of age and killed on day 37 did not differ from normal littermates. Collectively these studies indicate that hypopituitary dwarf mice lag behind their heterozygous littermates with respect to development of immunocompetence but normal immune responsiveness does develop by 32 days of age when the mice are weaned on day 21.     

Apoptosis of granulosa cells and female infertility in achondroplastic mice expressing mutant fibroblast growth factor receptor 3G374R

Fibroblast growth factors play an important role in the control of ovarian folliculogenesis, but the complete repertoire of ovarian receptors which can transduce the fibroblast growth factor signals and their precise localization in the ovary have not yet been characterized. The most common form of inherited human dwarfism results from a point mutation in the transmembrane region of fibroblast growth factor receptor 3. A mouse model for achondroplasia was generated by introducing the human mutation (glycine 380-arginine) into the mouse fibroblast growth factor receptor 3 (G374R) by a "knock-in" approach using gene targeting leading to a constitutively active receptor. This resulted in the development of dwarf mice that share many features with human achondroplasia. Here we report that female (fibroblast growth factor receptor 3 G374R) dwarf mice become infertile. While no significant changes were observed in the anatomical and histological appearance of ovaries of 3-wk-old dwarf mice, a dramatic difference was observed in ovaries of 3-month-old mice. The normal ovary consists mainly of healthy corpora lutea and follicles at different stages of development, whereas the ovaries of the dwarf mice remain small and contain mainly follicles with a progressive apoptosis in the granulosa cells, and no corpora lutea could be observed. The levels of LH, FSH, and progesterone were lower by 72.3%, 38.0%, and 40.0%, respectively, in the blood of the dwarf mice compared with normal mice, and the total bioactivity of pituitary FSH and LH was lower by 65.6% and 79.6%, respectively, in the dwarf mice compared with normal mice. However treatment with PMSG and human CG of the dwarf mice led to rapid follicular development and formation of corpora lutea. Interestingly, the expression of the tumor suppressor gene p53 was increased dramatically in ovaries of the dwarf mice. The presence of the fibroblast growth factor receptor 3 cellular receptors in both normal and dwarf animals was demonstrated by Western blot and immunostaining. However, the distribution of the fibroblast growth factor receptors in the two strains shows significant differences. In the normal ovaries fibroblast growth factor receptor 3 was homogeneously distributed on the cell membrane of the granulosa cells and was absent in theca as well as corpora lutea cells, whereas in dwarf mice ovaries it was highly clustered on granulosa cells and very often appears in endocytic vesicles. Aged oocytes were more frequently observed in preantral follicles of ovaries of the dwarf mice. Nevertheless, oocytes isolated from antral follicles resume their meiotic division at a high percentage, similar to oocytes obtained from normal ovaries. The results imply fibroblast growth factor receptor 3 involvement in the control of follicular development through regulation of granulosa cell growth and differentiation, and that unovulation in the dwarf mice could be overcome in part by administration of exogenous gonadotropins. Moreover, it is suggested that the infertile phenotype is partially due to defects in the pituitary-gonadal axis.     

Enlargement of interscapular brown adipose tissue in growth hormone antagonist transgenic and in growth hormone receptor gene-disrupted dwarf mice

Growth hormone (GH) acts on adipose tissue by accelerating fat expenditure, preventing triglyceride accumulation, and facilitating lipid mobilization. To investigate whether GH is involved in the development and metabolism of interscapular brown adipose tissue (BAT), a site of nonshivering thermogenesis, we employed three lines of transgenic mice. Two of the lines are dwarf due to expression of a GH antagonist (GHA) or disruption of the GH receptor/binding-protein gene. A third mouse line is giant due to overexpression of a bovine GH (bGH) transgene. We have found that the body weights of those animals are proportional to their body lengths at 10 weeks of age. However, GHA dwarf mice tend to catch up with the nontransgenic (NT) littermates in body weight but not in body length at 52 weeks of age. The increase of body mass index (BMI) for GHA mice accelerates rapidly relative to controls as a function of age. We have also observed that BAT in both dwarf mouse lines but not in giant mice is enlarged in contrast to nontransgenic littermates. This enlargement occurs as a function of age. Northern analysis suggests that BAT can be a GH-responsive tissue because GHR/BP mRNAs were found there. Finally, the level of uncoupling protein-1 (UCP1) RNA was found to be higher in dwarf mice and lower in giant animals relative to controls, suggesting that GH-mediated signaling may negatively regulate UCP1 gene expression in BAT.     

Long‐lived hypopituitary Ames dwarf mice are resistant to the detrimental effects of high‐fat diet on metabolic function and energy expenditure

Growth hormone (GH) signaling stimulates the production of IGF‐1; however, increased GH signaling may induce insulin resistance and can reduce life expectancy in both mice and humans. Interestingly, disruption of GH signaling by reducing plasma GH levels significantly improves health span and extends lifespan in mice, as observed in Ames dwarf mice. In addition, these mice have increased adiposity, yet are more insulin sensitive compared to control mice. Metabolic stressors such as high‐fat diet (HFD) promote obesity and may alter longevity through the GH signaling pathway. Therefore, our objective was to investigate the effects of a HFD (metabolic stressor) on genetic mechanisms that regulate metabolism during aging. We show that Ames dwarf mice fed HFD for 12 weeks had an increase in subcutaneous and visceral adiposity as a result of diet‐induced obesity, yet are more insulin sensitive and have higher levels of adiponectin compared to control mice fed HFD. Furthermore, energy expenditure was higher in Ames dwarf mice fed HFD than in control mice fed HFD. Additionally, we show that transplant of epididymal white adipose tissue (eWAT) from Ames dwarf mice fed HFD into control mice fed HFD improves their insulin sensitivity. We conclude that Ames dwarf mice are resistant to the detrimental metabolic effects of HFD and that visceral adipose tissue of Ames dwarf mice improves insulin sensitivity in control mice fed HFD.     

Augmented autophagy pathways and MTOR modulation in fibroblasts from long-lived mutant mice

Fibroblasts from long-lived pituitary dwarf mutants, including Snell dwarf, Ames dwarf and the growth hormone receptor knockout (GHRKO) mice, are resistant in culture to multiple forms of lethal stress. We found that fibroblasts from Snell dwarf and GHRKO mice are more susceptible than control cells to autophagy induced by amino acid withdrawal or by oxidative stress. We also found evidence for lower MTOR function in dwarf cells under conditions that induce autophagy, consistent with the evidence that increased autophagy requires lower TOR activity. Our results provide new hints about the connections between autophagy and aging in long-lived mutants with alterations in GH-IGF1 levels, and suggest a role for hyperactive autophagy in the resistance of cells from these mice to lethal stresses.     

Compensatory hypertrophy in radiothyroidectomized dwarf rats.

The aim of the study was to clarify whether growth hormone and thyroid hormones play a role in compensatory organ hypertrophy. Radiothyroidectomized dwarf rats with serious disorder of growth hormone production due to the loss of thyroid function were used in the experiments. As regards growth hormone production these animals may be considered as having been "hypophysectomized". The loss of thyroid function and growth hormone deficiency did not affect the degree of compensatory hypertrophy of the kidney, the adrenal and the gonad. The observation indicates that the hormones under study are not of decisive importance in the mechanism of compensatory organ enlargement. Further investigations are needed to clarify whether organ enlargement in the hypometabolic rat occurring at the level observed in the controls is associated with enhanced function.     

Altered oxidative stress response of the long-lived Snell dwarf mouse

Several single gene mutations in mice that increase the murine life span have been identified, including the Pit-1 mutation which results in the Snell dwarf (Pit1(dw/dw)), however, the biological mechanism of this life-span extension is still unclear. Based on studies that show oxidative stress plays an important role in the aging process, we hypothesized that the increased longevity seen in Snell dwarf mice may result from a resistance to oxidative stress. We report that Snell dwarf mice respond to oxidative stress induced by 3-NPA differently than their wild type littermates. This altered response results in diminished activation of the MEK-ERK kinase cascade and virtually no phosphorylation of c-Jun at Ser63 in dwarf mice after 3-NPA treatment, despite a robust phosphorylation of Ser63 in wild type mice. We propose that this altered management of oxidative stress in dwarf mice is partially responsible for the increased longevity in Snell dwarf mice.     

Normal thyroid structure and function in rhophilin 2-deficient mice

Rhophilin 2 is a Rho GTPase binding protein initially isolated by differential screening of a chronically thyrotropin (TSH)-stimulated dog thyroid cDNA library. In thyroid cell culture, expression of rhophilin 2 mRNA and protein is enhanced following TSH stimulation of the cyclic AMP (cAMP) transduction cascade. Yeast two-hybrid screening and coimmunoprecipitation have revealed that the GTP-bound form of RhoB and components of the cytoskeleton are protein partners of rhophilin 2. These results led us to suggest that rhophilin 2 could play an important role downstream of RhoB in the control of endocytosis during the thyroid secretory process which follows stimulation of the TSH/cAMP pathway. To validate this hypothesis, we generated rhophilin 2-deficient mice and analyzed their thyroid structure and function. Mice lacking rhophilin 2 develop normally, have normal life spans, and are fertile. They have no visible goiter and no obvious clinical signs of hyper- or hypothyroidism. The morphology of thyroid cells and follicles in these mice were normal, as were the different biological tests performed to investigate thyroid function. Our results indicate that rhophilin 2 does not play an essential role in thyroid physiology.     

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.