The urokinase plasminogen activator receptor (UPAR) is preferentially induced by nerve growth factor in PC12 pheochromocytoma cells and is required for NGF-driven differentiation.

Nerve growth factor (NGF)-driven differentiation of PC12 pheochromocytoma cells is a well studied model used both to identify molecular, biochemical, and physiological correlates of neurotrophin-driven neuronal differentiation and to determine the causal nature of specific events in this differentiation process. Although epidermal growth factor (EGF) elicits many of the same early biochemical and molecular changes in PC12 cells observed in response to NGF, EGF does not induce molecular or morphological differentiation of PC12 cells. The identification of genes whose expression is differentially regulated by NGF versus EGF in PC12 cells has, therefore, been considered a source of potential insight into the molecular specificity of neurotrophin-driven neuronal differentiation. A "second generation" representational difference analysis procedure now identifies the urokinase plasminogen activator receptor (UPAR) as a gene that is much more extensively induced by NGF than by EGF in PC12 cells. Both an antisense oligonucleotide for the UPAR mRNA and an antibody directed against UPAR protein block NGF-induced morphological and biochemical differentiation of PC12 cells; NGF-induced UPAR expression is required for subsequent NGF-driven differentiation.

Purification of human blood clotting factor X by Blue Dextran agarose affinity chromatography.

Blue Dextran 2000 coupled covalently to agarose has been used as an affinity column for the rapid separation of human blood clotting Factor X. Factor X has been isolated with approximately 2000-fold purification from human citrated plasma and shows single-component behavior by sodium dodecyl sulfate gel electrophoresis. Affinity columns prepared with Blue Dextran chromophore (Cibacron blue) derivatized to agarose or Sepharose gave negative results. These studies have shown that Blue Dextran agarose possesses unique biospecific and nonbiospecific properties, both of which are essential to achieve resolution of Factor X from other vitamin K-dependent blood clotting factors.

Neuroanatomical localization of cells containing gonadotropin-releasing hormone messenger ribonucleic acid in the primate brain by in situ hybridization histochemistry.

Using in situ hybridization histochemistry, we have mapped the anatomic localization of perikarya containing mRNA that codes for GnRH and GnRH-associated protein (GAP) in the forebrain of four male macaques, Macaca fascicularis. DNA oligomers, with sequences complementary to either the GnRH or the GAP portion of the mRNA sequence, were synthesized and hybridized to paraformaldehyde fixed, coronal sections of the basal forebrain and hypothalamus. GnRH mRNA was found in the same population of cells as those containing GAP mRNA. GnRH/GAP mRNA-containing cell bodies were observed consistently in the medial septal nucleus, the diagonal band of Broca, the medial preoptic area, supraoptic nucleus, and ventromedial-infundibular region. We detected the presence of GnRH mRNA and GAP mRNA within the same neuroanatomic regions previously shown to include perikarya containing immunoreactive GnRH. The ventromedial-infundibular region and the medial preoptic region contained the greatest number of GnRH/GAP mRNA-containing perikarya (37.0% and 22.5%, respectively). The diagonal band contained 21.0% and the supraoptic nucleus 13.0% of the cells, while the medial septum contained the fewest number (6.7%). This study demonstrates the feasibility of using in situ hybridization as a strategy to study the developmental and steroidal regulation of GnRH gene expression in the nonhuman primate.

Evidence that autoregulation of prolactin production does not occur at the pituitary level.

PRL production in primary cultures of rat pituitary cells was examined for evidence of autoregulation. The kinetics of PRL accumulation in the culture medium were linear (r = 0.993) over a 20-fold range of PRL concentrations (85-1800 ng/ml). The addition of 0.01-1000 ng/ml biologically active ovine PRL for 2 h had no effect on the rate of secretion or the intracellular levels of PRL. The functional integrity of the cells was verified by the demonstration that estradiol (10(-8) M) caused a 3-fold increase in both PRL synthesis and secretion. Ergocryptine (10(-8) M) inhibited PRL secretion by 57% (P less than 0.001), and this response was modulated by pretreatment with estradiol. Increasing concentrations of endogenously secreted PRL did not detectably alter the rate of incorporation of [35S]methionine into cellular PRL in control or ergocryptine-treated cells for up to 8 h. These results indicate that autoregulation of PRL does not operate directly at the level of the pituitary.

The effect of hypophysectomy and growth hormone administration on pre-prosomatostatin messenger ribonucleic acid in the periventricular nucleus of the rat hypothalamus.

Physiological evidence suggests that hypothalamic somatostatin (SS) inhibits pituitary GH release and that GH acts through a short-loop feedback mechanism to stimulate SS secretion. The feedback action of GH could be mediated by an effect on SS synthesis, secretion, or both. We hypothesized that GH acts to regulate the expression of the SS gene and that changes in the level of circulating GH would result in corresponding changes in SS mRNA in cells of the periventricular nucleus (PeN) of the hypothalamus. To test this hypothesis we measured the effect of hypophysectomy (HPX) and HPX with bovine GH (bGH) replacement on SS mRNA signal levels in cells of the PeN of the rat brain. We report that HPX male rats treated with bGH have significantly higher PeN SS mRNA signal than their vehicle-treated controls (P less than 0.05) and that bGH administration to sham-HPX rats results in elevated PeN SS mRNA signal levels compared to those in sham-HPX rats treated with vehicle (P less than 0.05). These observations suggest that GH participates in the regulation of its own secretion by influencing the expression of the SS gene and that one mechanism of short-loop pituitary feedback may involve the modulation of neuropeptide gene expression.

Reduced preprosomatostatin messenger ribonucleic acid in the periventricular nucleus of hypophysectomized rats determined by quantitative in situ hybridization.

Physiological evidence suggests that somatostatin (SS) inhibits the release of GH and TSH from the anterior pituitary and that elements of these two systems may feed back to regulate hypothalamic SS release or synthesis. Hypophysectomy reduces hypothalamic SS content in rats, an effect that may be attributable to a change in SS synthesis, storage, or release. We tested the hypothesis that hypophysectomy would reduce hypothalamic SS synthetic capacity, as reflected by a reduction in SS mRNA levels. Using in situ hybridization and a computerized image analysis system, we measured SS mRNA signal levels over individual cells in the periventricular nucleus of hypophysectomized and intact male rats. SS mRNA signal levels were 45.1% lower in hypophysectomized rats compared to those in intact controls (P less than 0.05). These results demonstrate that SS synthetic capacity in the periventricular nucleus is influenced by the presence of the pituitary, and this system may represent one example of the regulation of central nervous system neuropeptide gene expression by a circulating pituitary hormone.

Testosterone regulates pro-opiomelanocortin gene expression in the primate brain.

Endogenous opioid peptides such as beta-endorphin, derived from proopiomelanocortin (POMC), have been widely implicated as serving an important role in the neuroendocrine regulation of the primate reproductive axis. In both human and nonhuman primates, POMC neurons are thought to mediate, at least in part, the negative feedback action of sex steroids on GnRH. Sex steroids, such as testosterone, are thought to inhibit GnRH secretion by enhancing the inhibitory activity of beta-endorphin; however, the cellular mechanisms by which steroid hormones regulate the activity of POMC neurons in the primate brain are unknown. In this study, we tested the hypothesis that testosterone stimulates POMC gene expression within the primate brain and that this regulation occurs within a specific subset of POMC neurons residing in the arcuate nucleus of the hypothalamus. We used in situ hybridization to compare cellular levels of POMC messenger RNA in intact (n = 4), castrated (n = 4), and castrated/testosterone-treated (n = 4) monkeys. We report that after castration of the male macaque (Macaca fascicularis), cellular POMC messenger RNA levels decline significantly (P less than 0.05) in neurons within the arcuate nucleus and that this decline is prevented by replacement with physiological doses of testosterone. Moreover, we found that this testosterone-dependent modulation of POMC gene expression is restricted to a small fraction of the numerous POMC neurons located within the most anterior region of the arcuate nucleus in the brain of this primate species. These observations provide evidence that sex steroids regulate expression of the POMC gene in the primate brain.

Testosterone regulation of proopiomelanocortin messenger ribonucleic acid in the arcuate nucleus of the male rat.

GnRH regulates the secretion of LH and FSH, which stimulate the secretion of testicular hormones. Acting in a reciprocal fashion, these hormones, including testosterone and inhibin, exert a negative feedback effect on GnRH and gonadotropin secretion. Endogenous opioid peptides (EOPs) have been implicated to play a role in steroid-mediated regulation of gonadotropin secretion. In this context, certain steroid hormones (e.g. testosterone) increase EOP activity and ultimately inhibit GnRH secretion; however, the cellular mechanism by which this occurs is unknown. beta-Endorphin is one of these EOPs, and it is derived from a larger precursor molecule, POMC. We tested the hypothesis that testicular hormones and testosterone, in particular, stimulate POMC gene expression in the arcuate nucleus of the male rat brain. First, we compared POMC mRNA levels between intact and castrated male rats. Adult male rats were killed 4 days (n = 4) and 21 days (n = 5) after castration. Intact animals (sham-operated; n = 6) were used as controls. Using in situ hybridization and a computerized image analysis system, we measured the POMC mRNA content in individual cells of the arcuate nucleus. POMC mRNA signal was significantly lower (P less than 0.0003) in both 4-day (126 +/- 2 grains/cell) and 21-day (117 +/- 5 grains/cell) castrates than in controls (142 +/- 2 grains/cell). In a second experiment we tested whether testosterone would reverse the castration-induced loss of POMC message. Again, we castrated animals and immediately implanted them with either empty (sham; n = 6) or testosterone-containing Silastic implants (n = 5) of a size that would deliver physiological levels of testosterone (3.6 +/- 1.5 ng/ml). We observed that testosterone-treated animals had significantly higher levels of POMC mRNA signal (121.8 +/- 3.8 grains/cell) than sham-treated castrates (111.4 +/- 3.6 grains/cell; P less than 0.03) and that the testosterone-treated castrates had POMC mRNA signal levels indistinguishable from those of intact controls (122.0 +/- 1.1 grains/cell). These observations lend credence to the theory that one mechanism by which testosterone may regulate GnRH secretion is by increasing the synthesis of POMC in the arcuate nucleus.

Synaptotagmin IV: biochemistry, genetics, behavior, and possible links to human psychiatric disease.

We isolated the rat synaptotagmin IV (Syt IV) cDNA in a screen for sequences that are specifically induced in neuronal cells. The Syts are a large family of genes thought to mediate synaptic function. Syt IV is brain-specific, induced in hippocampus by depolarization, and predominantly vesicular. To assess the function role of Syt IV in vivo, we generated Syt IV(-/-) mutant mice. Syt IV (-/-) mice are viable and appear normal, indicating this gene is not essential for survival or gross development. However, Syt IV (-/-) mutants, when compared to wild-type littermates, have deficits in fine motor coordination and hippocampus-dependent memory, suggesting Syt IV has a role in normal brain function. The human Syt IV ortholog maps to a region of chromosome 18 previously associated with the human psychiatric disorders, schizophrenia and bipolar disease. These results suggest that Syt IV is required in certain types of neurons for optimal functionality, that perturbations in the levels of Syt IV can result in memory loss in mice, and that Syt IV alterations may lead to psychiatric disease in humans.

Differential localization of two glutamic acid decarboxylases (GAD65 and GAD67) in adult monkey visual cortex.

Adult monkey primary visual cortex contains a diverse population of stellate neurons that utilize the neurotransmitter gamma aminobutyric acid (GABA). Two glutamic acid decarboxylase (GAD) enzymes that synthesize GABA, GAD65 and GAD67, were localized within these stellate neurons by in situ hybridization of 35S or digoxigenin (DIG) labeled riboprobes. Double labels were done by using 35S GAD67 riboprobe and GABA immunocytochemistry on the same section to verify that the neuronal population identified by immunocytochemistry was the same one studied in the in situ hybridization experiments. We find that GAD65 mRNA and GAD67 mRNA are widely distributed in the cortex, with four bands of heavily labeled neurons in upper layer 2, lower 3, 4C, and 6. GAD67 labeled neurons were more obvious in layer 4C beta, while GAD65 containing neurons were common in layer 1 and white matter. Northern blots and in situ hybridization on sections with both 35S and DIG riboprobes indicate that cortical neurons typically contain more GAD67 mRNA. Cell counts show that 18% of all cortical neurons contain GAD67 mRNA and 13% contain GAD65 mRNA, suggesting that a small population of GABA neurons might lack GAD65. Cell bodies that contain high amounts of GAD65 mRNA are prominent in layers deep 3, 4B, 4C alpha, and 6 and often are the largest cells in their respective layers. Double labels demonstrate that 96% of all GABA+ neurons contain GAD67 mRNA. Neurons heavily labeled for GABA tend to have smaller cell bodies and contain less GAD67 mRNA, while lightly labeled GABA neurons are larger and contain more GAD67 mRNA. These data indicate that most GABA neurons in monkey striate cortex contain both GAD enzymes. Although the differences in GABA content, cell size, laminar distribution, and GAD mRNA concentration suggest different requirements for GAD67 and GAD65 in cortical circuits, our experiments do not reveal what different roles these two enzymes subserve within GABAergic stellate neurons.

Two synaptotagmin genes, Syt1 and Syt4, are differentially regulated in adult brain and during postnatal development following kainic acid-induced seizures.

The synaptotagmins together with other vesicle proteins are thought to be essential for the docking and/or fusion of synaptic vesicles with the plasma membrane that occurs following depolarization and calcium influx in presynatic terminals. Syt4, the fourth identified member of the synaptotagmin family, is inducible in PC12 cells by depolarization and secretagogues, and in limbic regions of the adult rat brain by kainic acid-induced seizures. In the present study, we examined the time course of the seizure-induced changes in the expression of Syt4 and Syt1, both in adult animals and during the postnatal period. Syt4 was transiently induced in several structures of the adult rat brain following seizure activity with peak inductions between 4 and 8 h and overal return to control values by 30 h. No induction was observed following seizure activity in 7-day-old animals. The brain regions most sensitive to increased induction were, in decreasing order of sensitivity, hippocampal pyramidal cells dentate granule cells and piriform cortex pyramidal cells. The brain areas showing the greatest Syt4 stimulation in adults were also the areas in which Syt4 was induced by seizures earlier in development. In contrast, Syt1 mRNA was depressed in adult brains following seizure activity, particularly in the dentate granule cells. Our results suggest that the differential regulation of different synaptotagmin genes following excessive neuronal activity might participate in rapid adaptation of subsequent transmitter release.

Regulation of somatostatin and growth hormone-releasing hormone gene expression in the rat brain.

We have studied the regulation of somatostatin (SS) and growth hormone-releasing hormone (GHRH) gene expression in the brain of the laboratory rat. We report that hypophysectomy in the adult male reduces SS mRNA in cells of the periventricular nucleus (PeN), while GH reverses this effect. We demonstrate that cellular levels of SS mRNA in the PeN are higher in male compared to female animals. We report that castration reduces cellular levels of GHRH mRNA and SS mRNA in the arcuate nucleus and PeN, respectively, and that testosterone reverses this effect through an androgen receptor-dependent mechanism. Finally, we present a theoretical model to explain the generation of the ultradian rhythm in GH secretion, which implicates the reciprocal interaction between GH feedback and the transcriptional regulation of the SS and GHRH genes and the kinetics of these relationships.

Sex differences in vasopressin neurons in the bed nucleus of the stria terminalis by in situ hybridization.

To determine whether a sex difference exists in the biosynthetic capacity of vasopressingergic (AVP) neurons in the bed nucleus of the stria terminalis (BNST), we have used in situ hybridization and quantitative autoradiography to measure propressophysin messenger RNA levels in these cells from adult male and female rats. We have found that significantly more (p less than 0.01) neurons are labeled in male rats than in female rats and that these labeled cells averaged more grains/cell (p less than 0.05) in males than in females. Therefore, the sexual dimorphism of AVP pathways in the BNST and lateral septum recently shown by immunohistochemistry results from a sex difference in the biosynthetic capacity of these AVP neurons.

Singing, but not seizure, induces synaptotagmin IV in zebra finch song circuit nuclei.

Synaptotagmins are a family of proteins that function in membrane fusion events, including synaptic vesicle exocytosis. Within this family, synaptotagmin IV (Syt IV) is unique in being a depolarization-induced immediate early gene (IEG). Experimental perturbation of Syt IV modulates neurotransmitter release in mice, flies, and PC12 cells, and modulates learning in mice. Despite these features, induction of Syt IV expression by a natural behavior has not been previously reported. We used the zebra finch, a songbird species, to investigate Syt IV because song is a naturally learned behavior whose neuroanatomical basis is largely identified. We observed that, similar to rodents, Syt IV is inducible in songbirds. This induction was selective and depended on the nature of neuronal depolarization. Generalized seizures caused by the GABA(A) receptor antagonist, metrazole, induced the IEG, ZENK, in zebra finch brain. However, these same seizures failed to induce Syt IV in song control areas. In contrast, when nontreated birds sang, three song control areas showed striking Syt IV induction. Further, this induction appeared sensitive to the social context in which song was sung. Together, these data suggest that neural activity during singing can drive Syt IV expression within song circuitry whereas generalized seizure activity fails to do so even though song control areas are depolarized. Our findings indicate that, within this neural circuit for a procedurally learned sensorimotor behavior, Syt IV is selective and requires precisely patterned neural activity and/or neuromodulation associated with singing.

Identification of genes preferentially induced by nerve growth factor versus epidermal growth factor in PC12 pheochromocytoma cells by means of representational difference analysis.

Neurotrophins induce neuronal differentiation by binding to a subclass of ligand-stimulated protein tyrosine kinase receptors and activating signal transduction pathways that mediate altered patterns of gene expression. Nerve growth factor (NGF) induced differentiation of PC12 pheochromocytoma cells is one of the major model systems used to study neuronal differentiation in response to neurotrophins. Although epidermal growth factor (EGF) does not induce PC12 cell differentiation, NGF and EGF activate many of the same signal transduction pathways and induce transcription of many of the same genes in PC12 cells. We have now employed cDNA representational difference analysis to identify four genes (activity-regulated cytoskeletal protein, collagenase 1, plasminogen activator inhibitor-1, and VH6/MKP-3) as genes preferentially induced withing 4 hours by NGF in PC12 cells.

Searching for depolarization-induced genes that modulate synaptic plasticity and neurotrophin-induced genes that mediate neuronal differentiation.

We identify and characterize two classes of immediate-early genes: (i) genes, induced by depolarization in neurons, that play a role in depolarization-induced neuronal plasticity and (ii) genes, induced in neuronal precursors by neurotrophins, that play a causal role in neurotrophin-directed neuronal differentiation. We use rat PC12 pheochromocytoma cells to identify (i) genes preferentially induced by [depolarization or forskolin] versus [Nerve Growth Factor (NGF) or Epidermal Growth Factor (EGF)] and (ii) genes preferentially induced by NGF versus EGF. We describe (i) a collection of genes preferentially induced by depolarization/forskolin in PC12 cells and by kainic acid in vivo, and (ii) a collection of genes preferentially induced by NGF. The synaptotagmin IV gene encodes a synaptic vesicle protein whose level is modulated by depolarization. NGF preferentially induces the urokinase-plasminogen activator receptor in PC12 cells. Antisense oligonucleotide and anti-UPAR antibody experiments demonstrate that NGF-induced UPAR expression is required for NGF-driven PC12 cell differentiation.

rTLE3, a newly identified transducin-like enhancer of split, is induced by depolarization in brain.

The transducin-like enhancers of split are a family of mammalian proteins that share sequence homology with the Drosophila protein Groucho. Using representational difference analysis, we isolated the cDNA for a previously unidentified gene, rTLE3 (rat transducin-like enhancer of split 3), as a sequence induced by depolarization and forskolin, but not by neurotrophins or growth factors, in PC12 pheochromocytoma cells. rTLE3 encodes the protein rTLE3, a 764-amino acid orthologue of mouse and human TLE3. R-esp2, the gene encoding the closest related rat protein, is not induced by any of the four treatments in PC12 cells. rTLE3 and R-esp2 have different patterns of expression in the adult rat CNS and other tissues. After systemic administration of kainic acid, rTLE3 is induced specifically in the dentate gyrus of the hippocampus. We propose that members of the transducin-like enhancer of split family of proteins may have distinct functions in the mature CNS, in addition to their functions during development.

The salt-inducible kinase, SIK, is induced by depolarization in brain.

Membrane depolarization of neurons is thought to lead to changes in gene expression that modulate neuronal plasticity. We used representational difference analysis to identify a group of cDNAs that are induced by membrane depolarization or by forskolin, but not by neurotrophins or growth factors, in PC12 pheochromocytoma cells. One of these genes, SIK (salt-inducible kinase), is a member of the sucrose-nonfermenting 1 protein kinase/AMP-activated protein kinase protein kinase family that was also recently identified from the adrenal gland of rats treated with high-salt diets. SIK mRNA is induced up to eightfold in specific regions of the hippocampus and cortex in rats, following systemic kainic acid administration and seizure induction.

Pubertal changes in pro-opiomelanocortin and gonadotropin-releasing hormone gene expression in the brain of the male monkey.

Puberty in the primate is initiated by an amplification of the pulsatile secretion of gonadotropin-releasing hormone (GnRH); however, the factors responsible for this a pubertal activation of GnRH neurons are unknown. We examined whether the biosynthetic capacity of GnRH neurons could be limiting for GnRH secretion in the juvenile monkey by determining whether the prepubertal macaque (Maraca fascicularis) expresses the GnRH gene. Using in situ hybridization for GnRH mRNA, we found no evidence for differences between prepubertal and adult animals in either the cellular level of GnRH mRNAs or the number of GnRH mRNA-containing cells in any area of the brain. These observations suggest that expression of the GnRH gene, at least to the point of messenger mRNA production, is not limiting for puberty onset. beta-Endorphin, derived from its precursor proopiomelanocortin (POMC), has been implicated as an inhibitory neurotransmitter in the control of GnRH secretion. We examined whether expression of the POMC gene changes as a function of sexual maturation by comparing the cellular content of POMC mRNA in the arcuate nucleus between prepubertal and adult male macaques. We report that cellular POMC mRNA levels are significantly higher in the adult than in the juvenile macaque (P < 0.02). We suggest that an increase in POMC biosynthesis may be part of the mechanism whereby a continuous mode of GnRH secretion is shaped into discrete pulses, which in turn initiate puberty in the primate.