Margarita Pérez-Martín

An antagonist of estrogen receptors blocks the induction of adult neurogenesis by insulin-like growth factor-I in the dentate gyrus of adult female rat

Interdependence between estradiol and insulin‐like growth factor‐I has been documented for different neural events, including neuronal differentiation, synaptic plasticity, neuroendocrine regulation and neuroprotection. In the present study we have assessed whether both factors interact in the regulation of neurogenesis in the adult rat dentate gyrus. Wistar albino female rats were bilaterally ovariectomized and treated with estradiol, insulin‐like growth factor‐I and/or the estrogen receptor antagonist ICI 182,780. Estradiol was administered in a subcutaneous silastic capsule. Insulin‐like growth factor‐I and ICI 182,780 were delivered in the lateral cerebral ventricle. Animals received six daily injections of 5‐bromo‐2‐deoxyuridine and were killed 24 h after the last injection. The total number of 5‐bromo‐2‐deoxyuridine‐positive neurons was significantly increased in animals treated with insulin‐like growth factor‐I, compared with rats treated with vehicles, while rats treated with both insulin‐like growth factor‐I and estradiol showed a higher number of 5‐bromo‐2‐deoxyuridine‐positive neurons than rats treated with insulin‐like growth factor‐I or estradiol alone. The antiestrogen ICI 182,780 blocked the effect of insulin‐like growth factor‐I on the number of 5‐bromo‐2‐deoxyuridine neurons with independence of whether the animals were treated or not with estradiol. These findings suggest that estrogen receptors are involved in the induction of adult neurogenesis by insulin‐like growth factor‐I in the dentate gyrus, and that estradiol and insulin‐like growth factor‐I have a cooperative interaction to promote neurogenesis. The interaction between insulin‐like growth factor‐I and estradiol may participate in changes in the rate of neurogenesis during different endocrine and physiological conditions, and may be related to the decline in neurogenesis with ageing.

IGF‐I stimulates neurogenesis in the hypothalamus of adult rats

In the brain of adult rats neurogenesis persists in the subventricular zone of the lateral ventricles and in the dentate gyrus of the hippocampus. By contrast, low proliferative activity was observed in the hypothalamus. We report here that, after intracerebroventricular treatment with insulin‐like growth factor I (IGF‐I), cell proliferation significantly increased in both the periventricular and the parenchymal zones of the whole hypothalamus. Neurons, astrocytes, tanycytes, microglia and endothelial cells of the local vessels were stained with the proliferative marker 5‐bromo‐2′‐deoxyuridine (BrdU) in response to IGF‐I. Conversely, we never observed BrdU‐positive ciliated cubic ependymal cells. Proliferation was intense in the subventricular area of a distinct zone of the mid third ventricle wall limited dorsally by ciliated cubic ependyma and ventrally by tanycytic ependyma. In this area, we saw a characteristic cluster of proliferating cells. This zone of the ventricular wall displayed three cell layers: ciliated ependyma, subependyma and underlying tanycytes. After IGF‐I treatment, proliferating cells were seen in the subependyma and in the layer of tanycytes. In the subependyma, proliferating glial fibrillary acidic protein‐positive astrocytes contacted the ventricle by an apical process bearing a single cilium and there were many labyrinthine extensions of the periventricular basement membranes. Both features are typical of neurogenic niches in other brain zones, suggesting that the central overlapping zone of the rat hypothalamic wall could be considered a neurogenic niche in response to IGF‐I.

Steroidogenic acute regulatory protein in the rat brain: cellular distribution, developmental regulation and overexpression after injury.

The central nervous system synthesizes steroids which regulate the development and function of neurons and glia and have neuroprotective properties. The first step in this process involves the delivery of free cholesterol to the inner mitochondrial membrane where it can be converted into pregnenolone. This delivery is mediated by steroidogenic acute regulatory protein (StAR). Here, we present a detailed analysis of the distribution of StAR expression in neurons and glia, in the developing, adult and aged male rat brain. Immunohistochemical analysis revealed that StAR is widely distributed throughout the brain, although in each brain area it is restricted to very specific neuronal and astroglial populations. In most regions expressing StAR, immunoreactivity appeared at P10 and the levels of expression then either increased or remained constant until adulthood. In 2‐year‐old rat brains, StAR immunoreactivity was increased compared to young adults. StAR was expressed in the subventricular zone of the adult brain, in proliferating cells which incorporate BrdU as well as in germinal layers in the developing brain. These findings indicate that StAR expression is developmentally regulated and that StAR may play some function in regulating cell proliferation in the brain. Furthermore, StAR mRNA and protein levels were acutely and transiently increased in the hippocampus following excitotoxic brain injury induced by the administration of kainic acid. This raises the possibility that the up‐regulation of StAR expression and the subsequent modifications in steroidogenesis may be part of the mechanisms used by the brain to cope with neurodegeneration.

Early motherhood in rats is associated with a modification of hippocampal function

The transition to motherhood results in a number of hormonal, neurological and behavioral changes necessary to ensure offspring survival. However, little attention has been paid to changes not directly linked to reproductive function in the early mother. In this study, we demonstrate that spatial performances during the learning phase were impaired after the delivery in rats, while spatial retention ability was improved 2 weeks later. In addition, we also report that early motherhood reduced the cell proliferation in the dentate gyrus of the hippocampus without inducing a decrease in the newborn cells 2 weeks later. The decrease of estradiol levels and high levels of glucocorticoids after delivery could in part explain the changes in the hippocampal function. In summary, our findings suggest that early postpartum period is associated with a modification of hippocampal function. This may reflect a homeostatic form of hippocampal plasticity in response to the onset of the maternal experience.

Insulin-like growth factor 1 reduces age-related disorders induced by prenatal stress in female rats

Stress during the prenatal period can induce permanent abnormalities in adult life such as increased anxiety-like behavior and hyperactivity of hypothalamo-pituitary-adrenal (HPA) axis system. The present study was designed to investigate whether prenatal stress could induce spatial learning impairment in aged female rats. Furthermore, since it has been recently reported that insulin-like growth factor 1 (IGF-1) attenuates spatial learning deficits in aged rats and promotes neurogenesis in the hippocampus, we assessed the impact of a chronic infusion of IGF-1 on age-related disorders. Our results show that females stressed during prenatal life exhibit learning impairments in the water maze task. Chronic IGF-1 treatment restores their spatial abilities, reduces their HPA axis dysfunction and increases plasma estradiol levels. Parallel to these effects, chronic IGF-1 up-regulates neural proliferation in the dentate gyrus of the hippocampus. These findings support the hypothesis of an early programming of the vulnerability to some neurological diseases during senescence and reinforce the potential therapeutic interest of IGF-1 during brain aging.

Growth hormone prevents neuronal loss in the aged rat hippocampus

Decline of growth hormone (GH) with aging is associated to memory and cognitive alterations. In this study, the number of neurons in the hilus of the dentate gyrus has been assessed in male and female Wistar rats at 3, 6, 12, 14, 18, 22 and 24 months of age, using the optical fractionator method. Male rats had more neurons than females at all the ages studied. Significant neuronal loss was observed in both sexes between 22 and 24 months of age. In a second experiment, 22 month-old male and female rats were treated for 10 weeks with 2 mg/kg/day of GH or saline. At 24 months of age, animals treated with GH had more neurons in the hilus than animals treated with saline. These findings indicate that GH is neuroprotective in old animals and that its administration may ameliorate neuronal alterations associated to aging.

Estradiol, insulin-like growth factor-I and brain aging

The decrease in some hormones with aging, such as insulin-like growth factor-I (IGF-I) and estradiol, may have a negative impact on brain function. Estradiol and IGF-I may antagonize the damaging effects of adrenal steroids and other causes of brain deterioration. The signaling of estradiol and IGF-I interact to promote neuroprotection. Estrogen receptor alpha, in an estrogen-dependent process, can physically interact with IGF-I receptor and with the downstream signaling molecules of the phosphotidylinositol 3-kinase (PI3K)/Akt/glycogen synthase kinase 3 (GSK3) pathway. Estradiol and IGF-I have a synergistic effect on the activation of Akt, which in turn decreases the activity of GSK3. This may be one of the mechanisms used by estradiol to promote neuronal survival, since the inhibition of GSK3 is associated to the activation of surviving signaling pathways in neurons. Furthermore, estradiol may control Tau phosphorylation by modulating the interactions of estrogen receptor alpha with GSK3 and beta-catenin, another molecule involved in the regulation of neuronal survival and the reorganization of the cytoskeleton. All these actions may be involved in the neuroprotective effects of the hormone. Possible aging-associated changes in the expression or activity of these signaling molecules may affect estradiol neuroprotective effects. Therefore, it is important to determine whether aging affects the signaling of estradiol and IGF-I in the brain.

Spontaneous congenital hydrocephalus in the mutant mouse hyh. Changes in the ventricular system and the subcommissural organ

The subcommissural organ is an ependymal gland located at the entrance of the cerebral aqueduct. It secretes glycoproteins into the cerebrospinal fluid, where they aggregate to form Reissners fiber. This fiber grows along the aqueduct, fourth ventricle, and central canal. There is evidence that the subcommissural organ is involved in the pathogenesis of congenital hydrocephalus. This organ was investigated in the mutant mouse hyh developing a congenital hydrocephalus. The central nervous system of normal and hydrocephalic hyh mice, 1 to 40 days old, was investigated using antibodies recognizing the subcommissural organ secretory glycoproteins, and by transmission and scanning electron microscopy. At birth, the affected mice displayed open communications between all ventricles, absence of a central canal in the spinal cord, ependymal denudation of the ventricles, stenosis of the rostral end of the aqueduct, and hydrocephalus of the lateral and third ventricles and of the caudal end of the aqueduct. Around the 5th postnatal day, the communication between the caudal aqueduct and fourth ventricle sealed, and hydrocephalus became severe. It is postulated that the hyh mice carry a genetic defect affecting the ependymal cell lineage. The subcommissural organ showed signs of increased secretory activity; it released to the stenosed aqueduct a material that aggregated, but it did not form a Reissners fiber. A large area of the third ventricular wall differentiated into a secretory ependyma synthesizing a material similar to that secreted by the subcommissural organ. It is concluded that the subcommissural organ changes during hydrocephalus; whether these changes preceed hydrocephalus needs to be investigated.

Estradiol and soy extract increase the production of new cells in the dentate gyrus of old rats

In young rodents, estradiol increases cell proliferation in the dentate gyrus of the hippocampus. However, it is unknown if the old brain retains this response to estradiol. Here we assessed the generation of new cells in the dentate gyrus of old rats after administration of estradiol or a soy extract, since soy is used as an alternative to hormonal replacement therapy in postmenopausal women. In a first experiment, 12-month-old animals were ovariectomized and studied at 14, 18 or 22 months of age. The production of new cells, assessed by the incorporation of bromodeoxyuridine (BrdU), was similar in 14- and 18-month-old rats. However, there was a significant reduction in the number of BrdU-immunoreactive cells at 22 months of age. In a second experiment, 22-month-old ovariectomized animals were treated for 10 weeks with a weekly s.c. injection of 150 microg estradiol valerianate or with 60 mg/kg per day soy extract added to the drinking water. Both treatments increased significantly the production of new cells in the dentate gyrus. These findings indicate that the brains of old rats retain the ability to increase the production of new cells in response to estradiol and soy extracts.

Ependymal Denudation, Aqueductal Obliteration and Hydrocephalus after a Single Injection of Neuraminidase into the Lateral Ventricle of Adult Rats

To investigate the role of sialic acid in the ependyma of the rat brain, we injected neuraminidase from Clostriditum perfingens into the lateral ventricle of 86 adult rats that were sacrificed at various time intervals. After administration of 10 µg neuraminidase, ciliated cuboidal ependymal cells of the lateral ventricles, third ventricle, cerebral aqueduct, and the rostral half of the fourth ventricle died and detached. The ependymal regions sealed by tight juntions such as the choroid plexus and the subcommissural organ were not affected. Debris was removed by infiltrating neutrophils and macrophagic cells. At the same time, after ependymal disappearance, the aqueduct was obliterated. In this region, mitoses were evident and cystic ependymal cells were frequent. Hydrocephalus of the lateral and third ventricles was evident 4 days after neuraminidase injection. Gliosis was restricted to the dorsal telencephalic wall of the injected lateral ventricle. It is thought that cleavage of sialic acid from ependymal surface glycoproteins or glycolipids, likely involved in cell adhesion, led to the detaching and death of the ependymal cells. Thereafter, ependymal loss, together with edema, led to fusion of the lateral walls of the cerebral aqueduct and this in turn provoked hydrocephalus of the third and lateral ventricles. This model of experimental hydrocephalus is compared with other models, in particular those of hydrocephalus after viral invasion of the cerebral ventricles.