Insulin-like growth factor-1 receptor immunoreactive cells are selectively maintained in the paraventricular hypothalamus of calorically restricted mice.

The mammalian lifespan is dramatically extended by both caloric restriction (CR) and insulin-like growth factor-1 (IGF-1) suppression. Both interventions involve neuroendocrine alterations directed by the hypothalamus. Yet, it remains unclear whether CR exerts its affects by altering central IGF-1 sensitivity. With this question in mind, we investigated the influence of CR and normal aging on hypothalamic IGF-1 sensitivity, by measuring the changes in IGF-1 receptor (IGF-1R) populations. Taking IGF-1 receptor (IGF-1R) immunoreactivity as an index of sensitivity to IGF-1, we counted IGF-1R immunoreactive and non-immunoreactive cells in the paraventricular nucleus (PVN) of Young-ad libitum fed (Young-Al, 6 weeks old), Old-ad libitum fed (Old-Al, 22 months old), and old calorically restricted (Old-CR, 22 months old) female B6D2F1 mice. An automated imaging microscopy system (AIMS) was used to generate cell counts for each cross-section of PVN hypothalamus. Ad libitum fed mice show a 37% reduction in IGF-1R immunoreactive cells and a 12% reduction in the total cell population of the PVN with aging. In comparison, caloric-restricted mice show a 33% reduction in IGF-1R immunoreactive cells and a notable 24% decrease in the total cell population with aging. This selective maintenance of IGF-1R expressing cells coupled with the simultaneous loss of non-immunoreactive cells, results in a higher percentage of IGF-1R immunoreactive cells in the PVNs of CR mice. Thus, the decline in the percentage of IGF-1 sensitive cells in the PVN with age is attenuated by CR.

Age-dependent loss of insulin-like growth factor-1 receptor immunoreactive cells in the supraoptic hypothalamus is reduced in calorically restricted mice.

Both life-long caloric restriction (CR) and the suppression of insulin-like growth factor-1 (IGF-1) signaling reliably extend the mammalian lifespan. The neuroendocrine system, regulated by the hypothalamus, remains the most convincing site of action for both these modes of life extension. Yet, determining whether CR actions are mediated by the modulation of neuroendocrine IGF-1 signaling remains unclear. Of the hypothalamic nuclei that express the IGF-1 receptor (IGF-1R), the cells of the supraoptic nucleus (SON) display some of the most robust IGF-1R expression. Taking IGF-1R immunoreactivity as an index of sensitivity to IGF-1, we counted IGF-1R immunoreactive and non-immunoreactive cells in the SON of young-ad-libitum fed (young-Al, 6 weeks), old-ad-libitum fed (Old-Al, 22 months), and old-calorie-restricted (Old-CR, 22 months) female B6D2F1 mice. An automated imaging microscopy system (AIMS) was used to generate cell counts for each section of supraoptic hypothalamus. Results show that while the total number of cells in the SON of ad-libitum fed mice does not change significantly with aging, a significant reduction in IGF-1R immunoreactive cells does occur in ad-libitum fed mice with aging. In contrast to this, calorie restricted mice show both a decline in the total number of cells and IGF-1R immunoreactive cells in the SON with age, but with the decrease in the latter being notably attenuated when compared to the degree of loss seen in ad-libitum fed mice. Thus, while CR induces greater loss in the total number of cells in the SON with age, it reduces the degree of age-dependent loss seen in IGF-1R expressing cells. As a result, when compared to Old-AL mice, the SON of Old-CR mice displays a greater proportion of IGF-1R cells and thus possibly enhanced IGF-1 sensitivity with aging.

Protective action of 17beta-estradiol and tamoxifen on glutamate toxicity in glial cells.

Estrogens influence differentiation, growth and function of neurons, but less is known of their effects on glia. In our experiments reported here, the ovarian steroid, 17beta-estradiol, and the "designer", non-steroidal estrogen, tamoxifen, effectively protected C-6 glioma 2B clone cells from the cytotoxicity of the excitatory neurotransmitter, glutamate. Exposure of these cells to 10-20 mM glutamate induced 61-78% cell death. Pre-treatment of the cells with 0.01 mM estradiol or with 2 microM tamoxifen significantly reduced the glutamate-induced cell death, estradiol being the most effective in this regard. Estradiol- or tamoxifen-treated cells that had survived glutamate damage appeared more mature than controls. Thus, estrogens often used in therapy (estradiol as replacement after menopause and tamoxifen for treatment/prevention of breast cancer) may significantly protect glial cells against glutamate toxicity and stimulate cell differentiation.

Estrogens influence growth, maturation, and amyloid beta-peptide production in neuroblastoma cells and in a beta-APP transfected kidney 293 cell line.

During development in vivo and in vitro, estrogens: a) increase brain excitability, particularly in limbic structures; b) are responsible for the maturation and cyclicity of limbic-hypothalamic interrelations; c) enhance myelinogenesis; and d) may act with NGF to stimulate neurite formation. In senescence, estrogen administration would improve memory in postmenopausal women. The absence or low levels of estrogens after menopause would increase prevalence of Alzheimer's dementia (AD) more in women than men, irrespective of age or ethnicity. In the present study, addition of 17-beta estradiol to cultured human neuroblastoma cells affected growth slightly, but stimulated cell maturation as shown by increased tyrosine hydroxylase activity. The extracellular deposition in brain tissue and around blood vessels of the amyloid beta-peptide (A beta), a 4.3 kD fragment of the larger integral membrane protein, beta-amyloid precursor protein (beta-APP), is considered an important characteristic of AD. We investigated whether 17-beta estradiol may influence the formation of the A beta (thus the abnormal accumulation of amyloid proteins) in neuroblastoma cells and in a beta-APP transfected human kidney 293 cell line. Two doses of 17 beta-estradiol were added to the cultures of both cell lines. Cells were grown until confluence, metabolically labeled with 35S-methionine, immunoprecipitated with the rabbit antiserum R1282, gel electrophoresed and autoradiographed in order to compare levels of A beta under the different estradiol concentrations. While in neuroblastoma cells, levels of A beta were only slightly reduced after estradiol and a dose-effect relationship with the hormone could not be demonstrated, in the 293 cells, A beta band intensity decreased as concentration of estradiol increased. These data support the role of estrogen in normal and abnormal brain metabolism and suggest potential hormonal interventions which may reduce or prevent the formation of amyloid deposits occur in AD.

Effect of growth factors on the in vitro growth and differentiation of early and late passage C6 glioma cells.

The effect of different hormones and growth factors was assayed on the in vitro growth and enzymatic activities of 2',3'-cyclic nucleotide 3'phosphohydrolase (CNP) and glutamine synthetase (GS) of rat glioma C6 cells at two different passages in culture. Young cultures (passage 26), mainly oligodendrocytic, and older cultures (passage 134), predominantly astrocytic, were treated with 10 microM dexamethasone, 20 ng/ml transforming growth factor alpha (TGF alpha), 10 ng/ml insulin, 20 ng/ml platelet-derived growth factor (PDGF), and 20 ng/ml, epidermal growth factor (EGF) in serum-free chemically defined media. In vitro growth rate was measured in terms of DNA content, by a fluorometric method of diaminobenzoic acid, and rate of DNA synthesis by 3H-thymidine incorporation. CNP activity (marker for in vitro oligodendrocytes) and GS activity (marker for astrocytes) were determined spectrophotometrically. Dexamethasone reversibly and significantly inhibited growth of C6 glioma in early and late passages. PDGF and insulin promoted in vitro growth only in late passage but not in early passage cells, whereas EGF and TGF alpha did not significantly affect growth. An increase in CNP activity was observed in early passage cells under the effect of PDGF and insulin. The increase in GS activity induced by insulin and dexamethasone suggests a differentiating role for these factors in C6 glioma cells. These results further present the C6 glioma cell line as a useful model for studies on glial cell properties and responsiveness in culture and support its use in experimental aging in vitro.

Education, homeostasis, and longevity.

The effects of education in lengthening life expectancy and reducing disability and disease in old age are examined for neural and hormonal correlates. Hormones and local factors influencing growth, in regulating neural cell death, proliferation, and differentiation, support the view of a "brain reserve capacity" built up during early learning years and capable of affording a protective action (increased threshold to damage) against the losses of normal and abnormal aging. Observation from studies on the effects of estrogen, dexamethasone, and a number of local factors on growth and differentiation of human neuroblastoma cells and of glial cells are supportive of a role for these factors in maintenance of homeostasis at an advanced age. Continuing education and learning is proposed as an effective means to promote longevity and improve life in old age.

Disuse and aging: same problem, different outcomes.

Many of the changes that accompany physical inactivity coincide with those that occur during aging. These changes are generally grouped under the term of 'disuse' (or "lack of use" or "inappropriately modulated stimulation"). Studies of long-term space travel have revealed that weightlessness in space also induces changes resembling those of aging and physical inactivity. The relationship between disuse (due to bed rest, insufficient exercise, or lack of gravity) and aging has some definite practical implications. As life expectancy is lenghtened in all populations worldwide, the number of elderly with varying degrees of disability leading to reduced physical activity also increases. Changes induced by bed rest as a consequence of disease may also be superimposed on aging changes and further diminish physiologic reserves and accelerate pathology. Therefore, the study of disuse, irrespective of its etiology, may serve as a model for understanding not only some of the functional changes induced by lack of activity and/or gravity but also some of the disabilities of old age. Indeed, a better understanding of disuse phenomena will make it possible to establish programs of prevention and rehabilitation that will ameliorate both disuse and aging deficits.

Enhancement of seminiferous tubular growth and spermatogenesis in testes of rats recovering from early hypothyroidism: a quantitative study.

Testicular weight and DNA content were markedly reduced (63 and 69%) in weanling Long-Evans rat pups rendered hypothyroid from birth by administration of propylthiouracil (PTU), a reversible goitrogen. These growth deficits worsened to > 80% by continuing hypothyroidism beyond weaning, to days 50 and 90. Recovery of thyroid function, brought about by discontinuing PTU at weaning, resulted in a paradoxical stimulation of testis growth, amounting to increased weight (40%), DNA content (60%) and size by 90 days, compared to age-matched controls. In the 25-day or older hypothyroid rats, testicular structure was immature and spermatogenesis markedly delayed, as evident by closed lumen and significantly reduced diameter of seminiferous tubules (38%), thickness of germinal layer (70%), and number of primary spermatocytes (86%), compared to control. Hypothyroidism did not alter the number of tubules per testis cross section. In the 90-day recovery rats, numbers of seminiferous tubules were unchanged but tubular diameter was significantly (20%) larger than in controls and spermatogenesis appeared very active as indicated by significantly increased germinal layer thickness (22%) and total number and density of primary spermatocytes (55% and 40%). The results show that although postnatal hypothyroidism is deleterious for testicular growth and spermatogenesis, recovery from this condition leads to enhanced seminiferous tubular growth and spermatogenesis.

Alterations in the growth and protein content of human neuroblastoma cells in vitro induced by thyroid hormones, stress and ageing.

The effects of the thyroid hormone triiodothyronine (T3), nerve growth factor (NGF) and stress (exposure to heat or aluminum sulfate) on growth, development and ageing of human neuroblastoma cells were studied in vitro. Differentiation of cells using retinoic acid and NGF inhibits cell growth and proliferation; simultaneously, it promotes acquisition of neuronal phenotype, down-regulation of T3 receptors, and an increase in catecholaminergic tyrosine hydroxylase activity and microtubule assembly. The actions of T3 on neuronal differentiation resemble those of NGF and suggest the existence of NGF-T3 interactions. Exposure to stress inhibits cell growth and proliferation, increases immunoreactivity to the microtubule-assembling protein tau (which occurs in paired filaments of neurofibrillary tangles in the aged human brain), and facilitates formation of tau-ubiquitin complexes (which also occur in the aged brain). Stress does not prevent the inhibition of cell proliferation by high doses of T3; however, T3 doses that are equivalent to physiological levels reduce stress-induced inhibition of growth. Previous studies have shown that stress may also induce in these cells facsimile lesions of normal and abnormal ageing, such as accumulation of lipofuscin pigments, formation of paired helical filaments and increased immunoreactivity to tau, beta-amyloid proteins, and ubiquitin. These lesions may represent cellular and molecular manifestations of increased vulnerability and susceptibility to genetic and extrinsic factors (e.g. hormones and environmental influences) with ageing. It is proposed that neuroblastoma cells may serve as a model to study mechanisms of neuronal ageing and to identify agents and conditions capable of preventing, delaying or reducing metabolic abnormalities leading to age-associated disorders.

Tau-ubiquitin protein conjugates in a human cell line.

The microtubule-associated protein tau, and the cytoplasmic protein ubiquitin, are constituents of pathological neurofibrillary tangles found in Alzheimer's disease. In order to see if there is any physiological relationship between these proteins in a functioning human system, human neuroblastoma (LAN-5) cells were grown in vitro and differentiated to a neuronal phenotype. Cell extracts were analyzed by SDS-PAGE, immunoblot, and immunoprecipitation techniques. The colocalization of ubiquitin and tau immunoreactivity was noted in 12- and 35-kDa bands, predominantly located in a cell membrane fraction. The bands were also isolated by immunoprecipitation with the Alz-50 antibody and then identified with a ubiquitin antiserum. These findings show a relationship between tau and ubiquitin in a human neural cell line. This interaction suggests that tau may normally be degraded by an ubiquitin-dependent mechanism and alterations in it may contribute to the formation of neuro-fibrillary pathology.

Effects of aluminum on tau proteins in human neuroblastoma cells.

The presence of the trivalent metallic cations, aluminum and boron, in the culture medium of differentiated human LAN-5 neuroblastoma cells results in increased amounts of specific isomers of microtubule-associated tau proteins. The cells were differentiated to a neuronal phenotype by the addition of retinoic acid. Six-day exposures of the differentiated cells to a 1-mM dose of aluminum or boron yielded increases in tau protein immunoreactivity to the monoclonal antibodies Tau-1 and Alz-50. Significant increases in immunoreactivity were seen at treatment levels of aluminum down to 100 microM. The increases in tau proteins were independent from increases in levels of total cell protein. Control cultures treated with the divalent cations zinc and iron showed no increases in levels of tau proteins.

Characterization of nuclear T3 receptors in human neuroblastoma cells SH-SY5Y: effect of differentiation with sodium butyrate and nerve growth factor.

Nuclear receptors for the thyroid hormone triiodothyronine (T3) have been identified in vivo in brain tissues and in vitro in mouse and rat neuroblastoma and glioma cells. The present study characterizes nuclear T3 receptors in human neuroblastoma SH-SY5Y cells and compares their level before and after differentiation. Undifferentiated cells, grown in DME/HAM F-12 medium supplemented with 10% fetal calf serum, show an abundant single type of nuclear receptor, indicated by a straight Scatchard plot, with a Kd of 0.11 nmol/l. After treatment with sodium butyrate (0.5 mM for 4 days) or NGF (2 nM for 6 days), the cells showed neuronal-like patterns (extension of neurites, slowing of growth, increased tyrosine hydroxylase activity), with a decrease in the number of nuclear T3 receptors. As sodium butyrate and NGF treatments differentiate neuroblastoma SH-SY5Y cells, these data suggest a down-regulation of T3 receptors with cell maturation.

Effects of serotonin on tyrosine hydroxylase and tau protein in a human neuroblastoma cell line.

The direct effects of the neurotransmitter serotonin on the catecholaminergic enzyme, tyrosine hydroxylase and the microtubule-associated tau protein were studied in a human neuroblastoma cell line. Undifferentiated LAN-5 cells, cultured in serum supplemented basal medium, or cells induced to differentiate by 6 day exposure to 10 uM retinoic acid were treated for 48 hr with 50 nM and 50 uM serotonin. In undifferentiated cells, serotonin treatment (50 uM) decreased both tyrosine hydroxylase activity and a 50 kD cytoplasmic fraction tau protein while 50 nM serotonin treatment caused this 50 kD protein to increase in the cytoplasmic fraction but decrease in the membrane fraction. While basal tyrosine hydroxylase activity increased in differentiated vs. undifferentiated cells, serotonin treatment had no effect on the enzyme or tau in differentiated LAN-5. This study shows serotonin to have direct effects on the biochemistry and cytoskeleton of undifferentiated cultured human neuroblastoma.

The aging process.

The intricate cause of the aging process in humans and animals, at present a matter of intense speculation, has given rise to many theories. Despite its uncertain cause, aging constitutes the most significant and universal problem confronting physicians today. Age-related physiologic deterioration and age-associated diseases are of immense concern to physicians because of the "old-age boom" anticipated in the first part of the twenty-first century. Biomedical research achievements in the twentieth century have permitted more persons to approach the fixed upper limit of the human lifespan. We discuss the functional decline of the aging heart and the underlying mechanisms of that decline; quantitative and qualitative changes in the immune system; and normal aging of the human brain contrasted to the brain changes seen in Alzheimer disease. With our growing geriatric population, we greatly need to increase our understanding of both the causes of human aging and the goals of gerontology and geriatrics and to expand research into the significant problem of Alzheimer disease.

Thyroid hormones and nervous system development.

Regulation by hormones of nervous system development is well recognized in humans, laboratory animals and cultured nerve cells. Thyroxine (T4) and triiodothyronine (T3), the major thyroid hormones, act on brain development and maturation by binding to T3 nuclear receptors. T3 responsive genes have been identified with the T3 receptor as a superfamily of genes including cortisol and estrogens, necessary for adaptation and survival. Less defined are T3 and T4 actions on the peripheral nervous system. In chromaffin cells explanted from the adrenal of immature rats, T3 induces the enzyme tyrosine hydroxylase, involved in catecholamine synthesis. This action is similar but, so far, apparently independent from Nerve Growth Factor promotion of sympathetic and chromaffin cell growth. Mechanisms based on nuclear binding depend on multiple receptors functionally diversified; their selectivity of action over a wide range of early and late developmental patterns is an attractive hypothesis to be further explored.

Early responses of skeletal muscle in recovery from hypothyroidism.

Postnatal growth of skeletal muscle (m. gastrocnemius) was compared in rats under euthyroid, hypothyroid and hypothyroid-rehabilitated conditions. In normal (euthyroid) animals, gastrocnemius muscle grows significantly in terms of weight (150 x) from birth to the young adult and, in terms of total contractile myofibril protein (15 x) and myosin ATPase activity (10 x) between days 25 and 90. Rats made hypothyroid (with 0.1% w/v propylthiouracil, PTU) from birth show reduced growth. At 25 days (weaning), compared with euthyroid, muscle weight is only 25% of normal, and a similar reduction is found in total DNA, RNA, protein, myofibril protein, and myosin ATPase activity. These deficits, already significant by day 10, are more marked by day 50 due to the near arrest of growth. Hypothyroid rats allowed to recover by PTU withdrawal after day 25 (rehabilitated) undergo marked compensatory muscle growth. By day 90, muscle weight and protein content increase 50 x, DNA 7 x and RNA 17 x. Over this period, total myofibrillar protein and myosin ATPase increase 20-40 x, but are still below those of 90-day controls, suggesting that the severe growth retardation had not yet been fully compensated. Early thyroid deficiency drastically reduces the normal age-related growth of skeletal muscle and severely retards the development of contractile elements, affecting muscle hypertrophy (protein content) more than cell proliferation (DNA content). Rehabilitation compensates to a major degree for this growth retardation. These results underline the key role of thyroid hormones in regulating development and maturation of skeletal muscle throughout the preweaning and postweaning phases of growth.

Histology and survival in age-delayed low-tryptophan-fed rats.

Diets containing tryptophan in concentrations 30 and 40 percent of those fed to controls from weaning to 24-30 months or more, can delay aging in Long-Evans female rats. Mortality among low-tryptophan-fed rats was greater in the juvenile period, but substantially less than controls at late ages. Histological biomarkers of aging were also delayed after tryptophan restriction in some organs (liver, heart, uterus, ovary, adrenal and spleen) but not in others (kidney, lung, aorta). Brain serotonin levels were low in tryptophan-deficient rats but showed remarkable capacity for rehabilitation. Effects on early and late mortality and brain levels of serotonin were proportional to the severity of the restriction.

Effects of thyroid hormone on light/dark melatonin synthesis and release by young and maturing rat pineal glands in vitro.

Synthesis and release of melatonin were studied in pineal explants from 14- (young) and 60-day-old ('maturing') male Long-Evans rats with or without added thyroid hormone, triiodothyronine (T3), at or near physiological levels and under light and dark conditions. Incubation for 6 hr (1200-1800) was in a synthetic medium; melatonin was measured by radioimmunoassay (RIA). In light, T3 increased melatonin levels in pineal and medium of cultures from either young or maturing animals. In dark, T3 decreased melatonin levels in the pineals of either age, but was without significant effect on levels in the medium. Since it is known from other work that 14-day-old rat pineal glands do not yet have a complete sympathetic innervation system, it is here doubly evident that T3 can modulate directly pineal synthesis and release of melatonin, and may not depend upon a mature sympathetic innervation. Light in the studied conditions was permissive from the stimulatory action of T3 on pineal synthesis and release of melatonin in vitro.

Regulation of glucocorticoid receptors in the kidney of immature and mature male rats.

1. Specific binding of [3H]dexamethasone to cytosol and the activation of bound hormone-receptor complexes were studied in the kidney of immature (3-week) and mature (26-week) Long-Evans male rats. 2. The concentration of specific binding sites was significantly higher (25%) in the kidney of immature rats as compared with mature, while dissociation constants (Kd) remain unaltered at both ages. 3. Heat activation (25 degrees C for 45 min) significantly enhanced the binding of [3H]dexamethasone-receptor complexes to DNA-cellulose and purified nuclei at both ages to the same extent. Cross-mixing experiments (i.e. binding of activated cytosol from mature rats to nuclei of immature and vice versa) gave similar results to the non-mixed groups. 4. Ca2+ activation (0 degree C for 45 min with 20 mM Ca2+) also enhanced the nuclear and DNA-cellulose binding at both ages but to a greater magnitude in immature rats. 5. Differences in the number of specific binding sites and some of the physicochemical properties of kidney glucocorticoid receptors presented here between immature and mature rats may underlie the functional changes in tissue response with age.