Maria E. Costa

Transforming growth factor-α gene expression in the hypothalamus is developmentally regulated and linked to sexual maturation

Hypothalamic injury causes female sexual precocity by activating luteinizing hormone-releasing hormone (LHRH) neurons, which control sexual development. Transforming growth factor-alpha (TGF-alpha) has been implicated in this process, but its involvement in normal sexual maturation is unknown. The present study addresses this issue. TGF-alpha mRNA and protein were found mostly in astroglia, in regions of the hypothalamus concerned with LHRH control. Hypothalamic TGF-alpha mRNA levels increased at times when secretion of pituitary gonadotropins--an LHRH-dependent event--was elevated, particularly at the time of puberty. Gonadal steroids involved in the control of LHRH secretion increased TGF-alpha mRNA levels. Blockade of TGF-alpha action in the median eminence, a site of glial-LHRH nerve terminal association, delayed puberty. These results suggest that TGF-alpha of glial origin is a component of the developmental program by which the brain controls mammalian sexual maturation.

Developmental expression of the genes encoding transforming growth factor alpha and its receptor in the hypothalamus of female rhesus macaques.

Studies in female rats have shown that transforming growth factor alpha (TGF alpha) stimulates release of luteinizing hormone-releasing hormone (LHRH), the neuropeptide controlling sexual maturation, and that expression of the TGF alpha gene in the hypothalamus increases during both the initiation of normal puberty and after hypothalamic lesions that induce sexual precocity. Since blockade of epidermal growth factor receptors (EGFR), which mediate TGF alpha actions, delayed the normal timing of puberty, it was postulated that TGF alpha/EGFR contributes to the neuroendocrine process that underlies the initiation of normal female puberty. The present study was undertaken to examine the hypothesis that hypothalamic expression of the TGF alpha gene and its receptor changes in relation to the stage of sexual development in nonhuman primates, and to determine whether these changes are accompanied by corresponding alterations in LHRH gene expression. DNA fragments complementary to the coding regions of the rhesus monkey TGF alpha, EGFR and LHRH genes were cloned by reverse transcription-polymerase chain reaction (RT-PCR), sequenced and used to prepare monkey-specific antisense RNA probes. A quantitative RT-PCR was developed in which the cloned sequences were utilized to prepare RNA standards for the quantitation of tissue mRNA levels. Both TGF alpha and EGFR mRNA levels in the medial basal hypothalamus and preoptic area of female monkeys were elevated during neonatal life (1 week to 6 months of age), when FSH secretion is also high, decreased during juvenile development (8-18 months of age), when secretion of both FSH and LH is low, and markedly increased during the expected time of puberty (30-36 months of age). No such changes were observed in either the cerebellum or the cerebral cortex, two brain regions irrelevant to neuroendocrine reproductive control. In contrast to the pronounced alterations in hypothalamic TGF alpha/EGFR gene expression observed during sexual development, LHRH mRNA levels did not vary significantly during this time. Hybridization histochemistry revealed the presence of both TGF alpha and EGFR mRNAs in cells scattered throughout the hypothalamus, but more predominantly in the median eminence, suprachiasmatic nuclei, optic chiasm and cells along the wall of the third ventricle. These results demonstrate that increases in TGF alpha and EGFR gene expression, specific to the neuroendocrine brain, occur during developmental phases in which gonadotropin output is also elevated--most noticeably at the time of puberty.(ABSTRACT TRUNCATED AT 400 WORDS)

TTF-1, a Homeodomain Gene Required for Diencephalic Morphogenesis, Is Postnatally Expressed in the Neuroendocrine Brain in a Developmentally Regulated and Cell-Specific Fashion

TTF-1 is a member of the Nkx family of homeodomain genes required for morphogenesis of the hypothalamus. Whether TTF-1, or other Nkx genes, contributes to regulating differentiated hypothalamic functions is not known. We now report that postnatal hypothalamic TTF-1 expression is developmentally regulated and associated with the neuroendocrine process of female sexual development. Lesions of the hypothalamus that cause sexual precocity transiently activate neuronal TTF-1 expression near the lesion site. In intact animals, hypothalamic TTF-1 mRNA content also increases transiently, preceding the initiation of puberty. Postnatal expression of the TTF-1 gene was limited to subsets of hypothalamic neurons, including LHRH neurons, which control sexual maturation, and preproenkephalinergic neurons of the lateroventromedial nucleus of the basal hypothalamus, which restrain sexual maturation and facilitate reproductive behavior. TTF-1 mRNA was also detected in astrocytes of the median eminence and ependymal/subependymal cells of the third ventricle, where it colocalized with erbB-2, a receptor involved in facilitating sexual development. TTF-1 binds to and transactivates the erbB-2 and LHRH promoters, but represses transcription of the preproenkephalin gene. The singular increase in hypothalamic TTF-1 gene expression that precedes the initiation of puberty, its highly specific pattern of cellular expression, and its transcriptional actions on genes directly involved in neuroendocrine reproductive regulation suggest that TTF-1 may represent one of the controlling factors that set in motion early events underlying the central activation of mammalian puberty.

Expression of Epidermal Growth Factor Receptor Changes in the Hypothalamus during the Onset of Female Puberty

Recent findings have led to the concept that transforming growth factor alpha (TGF alpha) contributes to the neuroendocrine regulation of female puberty by stimulating the release of luteinizing hormone-releasing hormone (LHRH), the neurohormone controlling sexual development. It was postulated that this effect is mediated by epidermal growth factor receptors (EGFR) and that EGFR may not be located on LHRH neurons, so that TGF alpha-induced LHRH release would require an intermediate cell-to-cell interaction, presumably of glial-neuronal nature. The present study was undertaken to characterize the presence of EGFR in rat hypothalamus and to determine if changes in EGFR gene expression and EGFR protein occur at the time of puberty. RNA blot hybridization demonstrated that the hypothalamus expresses all mRNA species known to encode EGFR. RNase protection assays revealed that alternative splicing of the EGFR primary mRNA transcript occurs in the hypothalamus and produces a predominant transcript encoding the full-length EGFR and a much less abundant, shorter mRNA encoding a truncated, and presumably secreted form of EGFR. EGFR-like immunoreactive material was found in several hypothalamic regions including the organum vasculosum of the lamina terminalis, supraoptic, suprachiasmatic, and paraventricular nuclei, ependymal cells lining the third ventricle, some astrocytes associated with blood vessels, astrocytes of the pial surface, and tanycytes and glial cells of the median eminence (ME). Low levels of EGFR mRNA were detected by hybridization histochemistry in cells of the same areas containing EGFR-like immunoreactivity. Double-immunohistochemistry revealed that even though LHRH neurons are in close proximity to EGFR-positive cells, they do not contain EGFR. In the ME, EGFR-immunonegative LHRH nerve terminals tightly coexist with EGFR-positive cells, presumably tanycytes and glial astrocytes. EGFR mRNA levels measured by quantitative reverse transcription-polymerase chain reaction assay (RT-PCR) in the ME-arcuate nucleus region at the time of puberty decreased in the morning of the first proestrus, i.e., preceding the first preovulatory surge of gonadotropins, and rebounded at the time of the surge. Functional EGFR protein levels, detected by the ability of the receptor to autophosphorylate in response to ligand or divalent antibody-induced activation, changed in a similar manner at the time of puberty. No such changes were observed in the cerebellum, a brain region irrelevant to neuroendocrine reproductive control. These results demonstrate the existence of EGF receptors in the prepubertal female rat hypothalamus and suggest that changes in EGFR gene expression and biologically active EGFR protein contributes to the neuroendocrine process underlying the first preovulatory surge of gonadotropins.(ABSTRACT TRUNCATED AT 250 WORDS)

NELL2, a Neuron-Specific EGF-Like Protein, Is Selectively Expressed in Glutamatergic Neurons and Contributes to the Glutamatergic Control of GnRH Neurons at Puberty

NELL2, a protein containing EGF-like repeats, is almost exclusively expressed in the nervous system. In the mammalian brain, NELL2 expression is mostly neuronal. NELL2 was previously found to be a secreted protein that functions during embryonic development as a neuronal differentiation and survival factor. We now show that the Nell2 gene is selectively expressed in the two major subtypes of glutamatergic neurons described in the postnatal brain: those containing the vesicular glutamate transporter 1 and those expressing vesicular glutamate transporter 2. No Nell2 mRNA is detected in GABAergic neurons. Likewise, GnRH neurons are devoid of NELL2. During prepubertal development of the female rat, Nell2 mRNA abundance increases selectively in the medial basal hypothalamus, reaching maximal values at the end of the juvenile period, to decline at the time of puberty to intermediate levels. Similar, but less pronounced changes are observed in the preoptic area, but they are absent in the cerebral cortex. A well-established glutamatergic function in the neuroendocrine brain is to enhance release of GnRH, the neurohormone controlling sexual development and the time of puberty. In vivo disruption of NELL2 synthesis via intraventricular administration of antisense oligodeoxynucleotides reduced GnRH release from the medial basal hypothalamus and delayed the initiation of female puberty. These results identify NELL2 as a new component of glutamatergic neurons and provide evidence for its physiological involvement in a major, glutamate-dependent, process of neuroendocrine regulation.

Hypothalamic Tumor Necrosis Factor-α Converting Enzyme Mediates Excitatory Amino Acid-Dependent Neuron-to-Glia Signaling in the Neuroendocrine Brain

Glial erbB1 receptors play a significant role in the hypothalamic control of female puberty. Activation of these receptors by transforming growth factor α (TGFα) results in production of prostaglandin E2, which then stimulates luteinizing hormone releasing hormone (LHRH) neurons to secrete LHRH, the neuropeptide controlling sexual development. Glutamatergic neurons set in motion this glia-to-neuron signaling pathway by transactivating erbB1 receptors via coactivation of AMPA receptors (AMPARs) and metabotropic glutamate receptors (mGluRs). Because the metalloproteinase tumor necrosis factor α converting enzyme (TACE) releases TGFα from its transmembrane precursor before TGFα can bind to erbB1 receptors, we sought to determine whether TACE is required for excitatory amino acids to activate the TGFα–erbB1 signaling module in hypothalamic astrocytes, and thus facilitate the advent of puberty. Coactivation of astrocytic AMPARs and mGluRs caused extracellular Ca2+ influx, a Ca2+/protein kinase C-dependent increase in TACE-like activity, and enhanced release of TGFα. Within the hypothalamus, TACE is most abundantly expressed in astrocytes of the median eminence (ME), and its enzymatic activity increases selectively in this region at the time of the first preovulatory surge of gonadotropins. ME explants respond to stimulation of AMPARs and mGluRs with LHRH release, and this response is prevented by blocking TACE activity. In vivo inhibition of TACE activity targeted to the ME delayed the age at first ovulation, indicating that ME-specific changes in TACE activity are required for the normal timing of puberty. These results suggest that TACE is a component of the neuron-to-glia signaling process used by glutamatergic neurons to control female sexual development.

Estrogen-dependent Transcription of the NEL-like 2 (NELL2) Gene and Its Role in Protection from Cell Death

NELL2 (neural tissue-specific epidermal growth factor-like repeat domain-containing protein) is a secreted glycoprotein that is predominantly expressed in neural tissues. We reported previously that NELL2 mRNA abundance in brain is increased by estrogen (E2) treatment and that NELL2 is involved in the E2-dependent organization of a sexually dimorphic nucleus in the preoptic area. In this study we cloned the mouse NELL2 promoter and found it to contain two half-E2 response elements. Electrophoretic mobility shift assays and promoter assays showed that E2 and its receptors (ERα and ERβ) stimulated NELL2 transcription by binding to the two half-E2 response elements. Hippocampal neuroprogenitor HiB5 cells expressing recombinant NELL2 showed increased cell survival under cell death-inducing conditions. Blockade of endogenous synthesis of NELL2 in HiB5 cells abolished the cell survival effect of E2 and resulted in a decrease in phosphorylation of extracellular signal-regulated kinase 1 and 2 (ERK1/2). These data suggest that the NELL2 gene is trans-activated by E2 and contributes to mediating the survival promoting effects of E2 via intracellular signaling pathway of ERK.