Pedro L. Zamorano

Expression and Localization of the Leptin Receptor in Endocrine and Neuroendocrine Tissues of the Rat

The obese gene (ob) product, leptin, has recently been shown to be produced by adipocytes and to circulate in the plasma acting as a hormone to modulate appetite and metabolism. Intriguingly, the ob/ob mutant female mouse, which does not produce an active form of leptin due to a mutation of the ob gene, has been shown to be acyclic and sterile. This sterility can be reversed by treatment with recombinant leptin, but not by diet restriction--suggesting that leptin is required for normal reproductive function. The mechanism(s) whereby leptin modulates reproductive function are unknown; however, it is possible that leptin could directly regulate reproductive tissues. To determine whether endocrine and neuroendocrine tissues could be targets for leptin action, we examined whether these tissues express the leptin receptor mRNA by utilizing reverse-transcription polymerase chain reaction (RT-PCR) analysis in selected tissues from the male and female rat. The results revealed that the leptin receptor mRNA transcript is highly expressed in the ovary, uterus and testis, moderately expressed in the hypothalamus and anterior pituitary, with low to no expression in the adrenal. The RT-PCR results were confirmed by Northern analysis. Furthermore, immortalized GnRH (GT1-7 and NLT) neurons and ovarian granulosa cells were also demonstrated by RT-PCR analysis to express the leptin receptor, suggesting that GnRH neurons and steroid-producing cells of the ovary could be targets for leptin action. Immunohistochemical studies revealed dense immunolocalization of the leptin receptor in the choroid plexus, and interestingly, in the arcuate nucleus/median eminence of the female rat--a key sit in the control of feeding and reproduction. Finally, treatment of the ob/ob mouse with recombinant leptin (0.15 mg/kg/day x 2 weeks) was found to markedly upregulate side chain cleavage and 17 alpha-hydroxylase mRNA levels in the ovary, demonstrating that leptin, acting either through a direct or indirect mechanism, can regulate gene expression in reproductive tissues.

Local sharing as a predominant determinant of synaptic matrix molecular dynamics.

Recent studies suggest that central nervous system synapses can persist for weeks, months, perhaps lifetimes, yet little is known as to how synapses maintain their structural and functional characteristics for so long. As a step toward a better understanding of synaptic maintenance we examined the loss, redistribution, reincorporation, and replenishment dynamics of Synapsin I and ProSAP2/Shank3, prominent presynaptic and postsynaptic matrix molecules, respectively. Fluorescence recovery after photobleaching and photoactivation experiments revealed that both molecules are continuously lost from, redistributed among, and reincorporated into synaptic structures at time-scales of minutes to hours. Exchange rates were not affected by inhibiting protein synthesis or proteasome-mediated protein degradation, were accelerated by stimulation, and greatly exceeded rates of replenishment from somatic sources. These findings indicate that the dynamics of key synaptic matrix molecules may be dominated by local protein exchange and redistribution, whereas protein synthesis and degradation serve to maintain and regulate the sizes of local, shared pools of these proteins.

Piccolo modulation of Synapsin1a dynamics regulates synaptic vesicle exocytosis

Active zones are specialized regions of the presynaptic plasma membrane designed for the efficient and repetitive release of neurotransmitter via synaptic vesicle (SV) exocytosis. Piccolo is a high molecular weight component of the active zone that is hypothesized to participate both in active zone formation and the scaffolding of key molecules involved in SV recycling. In this study, we use interference RNAs to eliminate Piccolo expression from cultured hippocampal neurons to assess its involvement in synapse formation and function. Our data show that Piccolo is not required for glutamatergic synapse formation but does influence presynaptic function by negatively regulating SV exocytosis. Mechanistically, this regulation appears to be calmodulin kinase II–dependent and mediated through the modulation of Synapsin1a dynamics. This function is not shared by the highly homologous protein Bassoon, which indicates that Piccolo has a unique role in coupling the mobilization of SVs in the reserve pool to events within the active zone.

The dynamics of SAP90/PSD-95 recruitment to new synaptic junctions

SAP90/PSD-95 is thought to be a central organizer of the glutamatergic synapse postsynaptic reception apparatus. To assess its potential role during glutamatergic synapse formation, we used GFP-tagged SAP90/PSD-95, time lapse confocal microscopy, and cultured hippocampal neurons to determine its dynamic recruitment into new synaptic junctions. We report that new SAP90/PSD-95 clusters first appeared at new axodendritic contact sites within 20-60 min of contact establishment. SAP90/PSD-95 clustering was rapid, with kinetics that fit a single exponential with a mean time constant of approximately 23 min. Most new SAP90/PSD-95 clusters were found juxtaposed to functional presynaptic boutons as determined by labeling with FM 4-64. No evidence was found for the existence of discrete transport particles similar to those previously reported to mediate presynaptic active zone cytoskeleton assembly. Instead, we found that SAP90/PSD-95 is recruited to nascent synapses from a diffuse dendritic cytoplasmic pool. Our findings show that SAP90/PSD-95 is recruited to nascent synaptic junctions early during the assembly process and indicate that its assimilation is fundamentally different from that of presynaptic active zone components.

Assembly of Active Zone Precursor Vesicles OBLIGATORY TRAFFICKING OF PRESYNAPTIC CYTOMATRIX PROTEINS BASSOON AND PICCOLO VIA A TRANS-GOLGI COMPARTMENT

Neurotransmitter release from presynaptic nerve terminals is restricted to specialized areas of the plasma membrane, so-called active zones. Active zones are characterized by a network of cytoplasmic scaffolding proteins involved in active zone generation and synaptic transmission. To analyze the modes of biogenesis of this cytomatrix, we asked how Bassoon and Piccolo, two prototypic active zone cytomatrix molecules, are delivered to nascent synapses. Although these proteins may be transported via vesicles, little is known about the importance of a vesicular pathway and about molecular determinants of cytomatrix molecule trafficking. We found that Bassoon and Piccolo co-localize with markers of the trans-Golgi network in cultured neurons. Impairing vesicle exit from the Golgi complex, either using brefeldin A, recombinant proteins, or a low temperature block, prevented transport of Bassoon out of the soma. Deleting a newly identified Golgi-binding region of Bassoon impaired subcellular targeting of recombinant Bassoon. Overexpressing this region to specifically block Golgi binding of the endogenous protein reduced the concentration of Bassoon at synapses. These results suggest that, during the period of bulk synaptogenesis, a primordial cytomatrix assembles in a trans-Golgi compartment. They further indicate that transport via Golgi-derived vesicles is essential for delivery of cytomatrix proteins to the synapse. Paradigmatically this establishes Golgi transit as an obligatory step for subcellular trafficking of distinct cytoplasmic scaffolding proteins.

Quantitative RT-PCR for Neuroendocrine Studies

Determination of mRNA levels of specific genes is becoming increasingly important as a measure of gene expression. With the recent advent of RT-PCR, the sensitivity for mRNA determination has been increased dramatically, and this technique is becoming widely used in neuroendocrine studies which involve small tissue samples and/or isolated nuclei. Nevertheless, the exact procedure for reliable quantification of RT-PCR has been widely debated. This minireview attempts to assimilate the available literature on the RT-PCR technique and discuss the various approaches commonly used to obtain quantitative results using the technique. An example from our laboratory of the use of RT-PCR for the measurement of several gene products in the same sample using exogenous internal standards is also provided. Particular attention is paid to the choice of endogenous vs. exogenous internal standards, the length of the transcript of the standard and its relationship to the target sequence being amplified, the amplification pattern of the target gene and internal standard, the reproducibility of the method, and the overall usefulness and suitability of RT-PCR for neuroendocrine studies.

Regulation of leptin gene expression and secretion by steroid hormones

Previous work has shown that 17 beta-estradiol is the primary ovarian signal regulating body weight and adiposity, although its mechanisms of action remain unclear. We hypothesized that 17 beta-estradiol could enhance leptin levels as a mechanism of its anorectic effects. Administration of 5 microg 17 beta-estradiol subcutaneously (s.c.) for 2 days significantly elevated leptin mRNA levels in adipose tissue as compared to vehicle controls (P < 0.003). A time-course administration of estrogen showed increased mRNA levels in adipose tissue between 6 and 12 h after estrogen injection as compared to vehicle controls (P < 0.03). Corresponding to the increased leptin mRNA levels at 6 and 12 h, elevated plasma leptin levels were observed at 12 h after estrogen administration as compared to controls (P < 0.05). Administration of progesterone (1 mg/rat) after estradiol injection did not enhance the elevated leptin mRNA levels in adipose tissue. Serum leptin levels from cycling rats did not differ significantly between metestrous and proestrous animals. In conclusion, the present studies demonstrate that 17 beta-estradiol can regulate leptin gene expression and secretion in the female rat, thus providing a better understanding of the possible anorectic effect of estrogens.

Steroid hormone effects on NMDA receptor binding and NMDA receptor mRNA levels in the hypothalamus and cerebral cortex of the adult rat

Previous work has demonstrated that N-methyl-D-aspartate (NMDA) is capable of stimulating luteinizing hormone release in a variety of species. Interestingly, the ability of NMDA to stimulate luteinizing hormone release is significantly compromised in castrated male and female rats as compared to intact animals. The purpose of the present study was to determine if a difference exists in the number or affinity of NMDA receptors in the hypothalamus of intact or castrated adult male and female rats and whether steroid replacement has any effect on NMDA receptor binding. NMDA receptor mRNA levels were also determined in the respective models. The cerebral cortex was used as a control to check for specificity of any observed differences. The number of NMDA binding sites in the hypothalamus was found to be approximately 25% of that found in the cerebral cortex and the equilibrium association constant was similar in both tissues. In the female rat, neither ovariectomy nor ovariectomy with estrogen pellet replacement or estrogen and progesterone injections altered NMDA receptor binding or the equilibrium association constant in the hypothalamus or cerebral cortex as compared to intact controls. Similar to the case in the female, NMDA receptor binding in the hypothalamus and cerebral cortex of male rats did not change after castration or after treatment with testosterone propionate. Neither ovariectomy nor ovariectomy with estradiol replacement brought about any change in the NMDA receptor mRNA levels in the hypothalamus. However, in the cerebral cortex ovariectomy with estrogen replacement brought about a small but significant increase in NMDA receptor mRNA levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of Ionotropic Glutamate Receptors in Rat Hypothalamus, Pituitary and Immortalized Gonadotropin-Releasing Hormone (GnRH) Neurons (GT1-7 Cells)

Evidence from various sources suggested that the Gonadotropin-Releasing Hormone (GnRH) neuron does not contain glutamate receptors. Northern analysis of the hypothalamus showed the presence of NMDAR1, GluR1, GluR4 and GluR6 mRNA, while the pituitary showed the presence of NMDAR1, GluR1 and GluR6 mRNA. Western blot analysis also showed the presence of NMDAR1 and GluR1 protein. Since there are relatively few GnRH neurons in the hypothalamus, and GT1-7 cells have been considered to be a GnRH neuronal cell line, GT1-7 cells were studied in detail. GT1-7 cells contained NMDAR1 mRNA levels as shown by Northern analysis but did not contain GluR1, GluR4, or GluR6 mRNA. They did not show the presence of NMDAR1 and GluR1 protein by Western analysis. In addition, GT1-7 cells showed no NMDA receptor binding using the competitive inhibitor CGP-39563 and the noncompetitive inhibitor MK-801. Likewise, no binding was detected for kainate receptors. However, a small amount of binding for AMPA receptors was found in GT1-7 cells. GT1-7 cells did not exhibit glutamate toxicity and NMDA failed to elicit inward currents using patch-clamp techniques, although GABA did induce currents in the cells. As a whole, these studies suggest that GT1-7 cells lack or possess only low levels of ionotropic glutamate receptors.

Gamma-Aminobutyric Acid-Opioid Interactions in the Regulation of Gonadotropin Secretion in the Immature Female Rat

Previous studies in the male rat have demonstrated that GABA acting via GABAB receptors can abolish naloxone-induced LH secretion. The purpose of the present study was to determine if an analogous situation exists in the female rat. Naloxone administered to ovariectomized immature rats had no effect on LH release. In contrast, naloxone potently stimulated LH release in estrogen-primed ovariectomized immature rats. Elevation of endogenous brain levels of GABA by administering amino-oxyacetic acid, an inhibitor of GABA catabolism, prevented the naloxone-stimulated release of LH. This effect appeared to be both GABAA and GABAB receptor mediated, since exogenous administration of either muscimol (GABAA agonist) or baclofen (GABAB agonist) prevented the naloxone-induced release of LH. Neither GABA agonist had any effect on LHRH-stimulated LH release in vivo, suggesting that their effect was specific and achieved at the level of the CNS. In contrast to its inhibitory effect on naloxone-stimulated LH and FSH release, muscimol increased basal LH and FSH release in vivo and from hemipituitaries incubated in vitro, while having no effect on LHRH release from mediobasal hypothalamic and preoptic area fragments in vitro. Thus, under conditions of basal LH release, activation of GABAA receptors in the anterior pituitary can actually lead to enhanced LH secretion. Finally, naloxone-stimulated LH release was found to be inhibited by the alpha 1- and alpha 2-adrenergic blockers, prazosin and yohimbine, suggesting that naloxone-stimulated LH release is mediated via catecholamine neurotransmission involving alpha 1- and alpha 2-adrenergic receptor activation.(ABSTRACT TRUNCATED AT 250 WORDS)