A forebrain-retrorubral pathway involved in male sex behavior is GABAergic and activated with mating in gerbils.

The ventral bed nuclei of the stria terminalis (BST) and medial preoptic nucleus (MPN) of gerbils contain cells that regulate male sex behavior via a largely uncrossed pathway to the retrorubral field (RRF). Our goal was to learn more about cells at the pathway source and target. To determine if the pathway uses GABA as its transmitter, we used immunocytochemistry (ICC) to study glutamic acid decarboxlyase(67) (GAD(67)) colocalization with fluoro-gold (FG) in the ventral BST and MPN after applying FG to the RRF. To determine if the pathway is activated with mating, we studied FG-Fos colocalization in the ventral BST of recently mated males. The ventral BST expresses Fos with mating and is the major pathway source. To determine to what extent other GABAergic cells in the ventral BST are activated with mating, we studied Fos colocalization with GAD(67) mRNA visualized by in situ hybridization (ISH). We also looked for GAD(67) mRNA in RRF cells. Almost all ventral BST and MPNm cells projecting to the RRF (95-97%) and most ventral BST cells activated with mating (89%), were GABAergic. GABAergic cells were also seen in the RRF. RRF-projecting cells represented 37% of ventral BST cells activated with mating. Their activation may reflect arousal and anticipation of sexual reward. Among ventral BST cells that project to the RRF, 14% were activated with mating, consistent with how much of this pathway is needed for mating. The activated GABAergic cells that do not project to the RRF may release GABA locally and inhibit ejaculation.

Electrical properties of neocortical neurons in slices from children with intractable epilepsy.

1. The intrinsic electrical properties of human neocortical neurons were studied with current-clamp and single-electrode voltage-clamp techniques in slices obtained from children, aged 3 mo to 15 yr, undergoing surgical treatment of intractable epilepsy. Neocortical samples were classified as most or least abnormal based on clinical data. Recorded neurons were labeled with biocytin for correlation of electrical properties with morphological characteristics and laminar position. All recorded neurons were divided into three cell types--fast-spiking, low-threshold spiking (LTS) and non-LTS cells--on the basis of their electrical characteristics. 2. Fast-spiking cells generated brief, rapidly repolarizing action potentials. Most of these cells showed only weak spike-frequency adaptation. Fast-spiking cells labeled with biocytin were aspiny or sparsely spiny nonpyramidal neurons located in cortical layers 2-4. 3. LTS cells generated Ca(2+)-dependent low-threshold potentials and were the most numerous of the three cell types. Their Na(+)-dependent action potentials were broader than those of fast-spiking cells and showed marked spike-frequency adaptation. The size of low-threshold Ca2+ potentials and currents varied across cells, but they never supported more than two or, occasionally, three fast action potentials. LTS cells were pyramidal neurons located throughout cortical layers 2-6. Unlike the bursting neocortical cells described in lower mammals, LTS neurons in neocortex from children failed to generate bursts of inactivating Na+ action potentials. 4. Non-LTS cells also had relatively broad Na(+)-dependent action potentials and showed spike-frequency adaptation, but they did not generate detectable low-threshold potentials or currents. Non-LTS cells were also pyramidal neurons located throughout layers 2-6. 5. The electrical properties of cells from different age groups (< or = 1, 2-8, and 9-15 yr) and from most-abnormal and least-abnormal tissue samples were compared. A statistically significant trend toward a lower input resistance, a faster membrane time constant, and a decreased spike duration was observed with increasing age. There were no significant differences between the electrical properties of cells from the most-abnormal tissue and cells from the least-abnormal tissue. 6. These data indicate that the intrinsic electrical properties of neocortical neurons from children vary according to cell morphology and change with increasing age, as has been observed in rodent and feline neocortical neurons. No obvious evidence of epileptogenicity was detected in the intrinsic electrical properties of any of the neurons studied.

Whole-cell recordings of spontaneous synaptic currents in medial preoptic neurons from rat hypothalamic slices: mediation by amino acid neurotransmitters.

Whole-cell recordings in hypothalamic slices from immature rats were used to test the hypothesis that inhibitory and excitatory amino acid neurotransmitters mediate fast synaptic currents in the medial preoptic area (MPOA). Bicuculline methiodide reversibly blocked spontaneous inhibitory postsynaptic currents (IPSCs), and 6-cyano-2,3-dihydroxy-7-nitroquinoxaline (CNQX) blocked spontaneous excitatory postsynaptic currents (EPSCs). These competitive antagonists act at gamma-aminobutyric acid (GABA)A and non-N-methyl-D-aspartate (NMDA) glutamate receptors, respectively, thus supporting the hypothesis that these amino acid receptors activate most if not all fast synaptic currents in the MPOA.

Telencephalic connections of the sexually dimorphic area of the gerbil hypothalamus that influence male sexual behavior.

The sexually dimorphic area (SDA) of the gerbil hypothalamus is essential for mating in male gerbils. To determine if it affects mating through its connections with the ventral part of the lateral septal nucleus (LSv), the caudal part of the medial bed nucleus of the stria terminalis (caudal BSTm), or the medial amygdala-amygdalohippocampal area (MA-AHi), these connections were severed. Unilateral cell-body lesions were made in the SDA and in the contralateral LSv, caudal BSTm, or MA-AHi. Controls received the same lesions ipsilaterally. Other gerbils received lesions in the caudal BSTm and contra- or ipsilateral MA-AHi. Only contralateral lesions of the SDA and caudal BSTm severely impaired mating. Because contralateral lesions of the SDA and MA-AHi, or BSTm and MA-AHi, did not mimic this effect, the BSTm neurons that are needed for male sexual behavior through their connections with the SDA do not simply relay information to or from the MA-AHi.

Homogeneity of intracellular electrophysiological properties in different neuronal subtypes in medial preoptic slices containing the sexually dimorphic nucleus of the rat.

The sexually dimorphic nucleus of the preoptic area (SDN-POA) is larger in male than in female rats, the male phenotype requiring the presence of circulating androgens perinatally. These experiments investigated the intracellular electrophysiology and morphology of SDN-POA neurons and compared these properties with those of other medial preoptic area (MPOA) neurons. Biocytin-injected cells in the SDN-POA either had one or two primary dendrites, or they had multipolar dendritic arrays; dendrites were aspiny or sparsely spiny and displayed limited branching. Neurons in other parts of the MPOA were similar morphologically. Regardless of morphology, neurons situated in either the SDN-POA or surrounding MPOA had low-threshold potentials and linear or nearly linear current-voltage relations. In most (73%) cells, stimulation of the dorsal preoptic region evoked a fast excitatory postsynaptic potential followed by a fast inhibitory postsynaptic potential (IPSP). Bicuculline blocked the fast IPSPs, which reversed near the Cl2 equilibrium potential (-71 +/- 5 mV), indicating their mediation by gamma-aminobutyric acid (GABA)A receptors. Neurons in the SDN-POA have electrophysiological properties similar to those of other medial preoptic cells. When compared with the hypothalamic paraventricular nucleus, the MPOA appears relatively homogeneous electrophysiologically. This is despite the morphological variability within this population of neurons and heterogeneities that are also apparent at other levels of analysis. Finally, GABA-mediated, inhibitory synaptic contacts are widespread among medial preoptic neurons, consistent with indications from earlier reports that GABA provides a link in the feedback actions of gonadal steroids on the release of gonadotropic hormones.

Sexually dimorphic cell groups in the medial preoptic area that are essential for male sex behavior and the neural pathways needed for their effects.

The research summarized here shows that the two major cell groups of the sexually dimorphic area (SDA) of the gerbil hypothalamus are essential for male sex behavior. Bilateral cell-body lesions of either the medial or lateral SDA virtually eliminate mating in sexually experienced male gerbils given exogenous testosterone. Similar deficits occur when the SDA is bilaterally disconnected from the retrorubral field (RRF) as a result of unilateral cell-body lesions in the SDA and contralateral RRF. The A8 cells of the RRF do not account for this effect. Bilaterally disconnecting the SDA from the caudomedial part of the bed nucleus of the stria terminalis (caudal BSTm) also eliminates sexual activity. Disconnecting the SDA from the medial amygdala does not mimic this effect. Neither does disconnecting the medial amygdala from the caudal BSTm. Thus, caudal BSTm neurons that are essential for mating via connections with the SDA do not simply relay information from the medial amygdala.

Comparison of three intracellular markers for combined electrophysiological, morphological and immunohistochemical analyses.

Hypothalamic paraventricular and supraoptic neurons were recorded intracellularly in coronal slices and injected with Lucifer yellow, ethidium bromide or biocytin. Electrical properties, morphological staining and neurophysin immunohistochemistry were compared among the 3 markers. Lucifer yellow electrodes had a high resistance and frequently blocked during experiments. Neurons recorded with Lucifer yellow electrodes had low input resistances and low-amplitude, broad spikes. Lucifer yellow labeling in whole mount was highly fluorescent, revealing distal dendrites and axons. Of cells injected with Lucifer yellow, 64% were recovered but were faint after immunohistochemical processing. Recordings with ethidium bromide electrodes were similar to controls, although electrode blockage sometimes occurred. Only somata and proximal dendrites of ethidium bromide-filled neurons were visible in whole-mount. Forty percent of cells injected with ethidium bromide were recovered after immunohistochemical processing; these were invariably faint. Recordings with biocytin-filled electrodes were similar to control recordings. Biocytin-filled, HRP-labeled cells showed distal dendrites and often dendritic spines and axons in 50-75-microns sections. Seventy percent of biocytin-injected cells labeled with fluorescent markers were recovered and remained strongly labeled after immunohistochemical processing. Biocytin had the best electrical and staining properties for combined electrophysiological and anatomical studies.

Immunohistochemical differentiation of electrophysiologically defined neuronal populations in the region of the rat hypothalamic paraventricular nucleus.

Intracellular recording and labeling were combined with neurophysin immunohistochemistry to study neurons in the paraventricular nucleus region of the rat hypothalamus. Neuronal membrane properties were examined in hypothalamic slices, and cells were labeled by injecting biocytin or Lucifer yellow. Slices were then embedded, sectioned, and immunohistochemically processed for neurophysin. Immunoreactivity patterns, and in some cases counterstaining, enabled determinations of the cytoarchitectonic positions of recorded cells to be made. Recorded cells were divided into three types according to their electrophysiological characteristics. The first type lacked low-threshold Ca2+ spikes and displayed linear current-voltage relations, a short time constant, and evidence for an A current. These were relatively large cells that were typically immunoreactive for neurophysin and were situated near other neurophysin-positive neurons. The second type had relatively small low-threshold potentials that did not generate bursts of Na+ spikes. These cells had heterogeneous current-voltage relations and intermediate time constants. They did not label for neurophysin, and most were located in the parvicellular subregion of the paraventricular nucleus. The third type had large low-threshold Ca2- spikes that generated bursts of Na+ spikes, and these cells had nonlinear current-voltage relations and long time constants. These neurons were dorsal or dorsolateral to the paraventricular nucleus and were not immunoreactive for neurophysin. These results indicate that paraventricular magnocellular neurons lack low-threshold potentials, whereas paraventricular parvicellular neurons display low-threshold potentials that generate one or two action potentials. Neurons that fire spike bursts from low-threshold potentials are adjacent to the paraventricular nucleus, confirming earlier reports.

Atrial natriuretic factor concentrations in discrete brain regions, pituitary, cardiac atria and plasma during the estrous cycle in rats.

Peripheral and central atrial natriuretic factor (ANF) concentrations were measured across the rat's estrous cycle. Vaginal smears were obtained from adult Sprague-Dawley rats maintained under controlled illumination (L/D: 14/10, onset 05.00 h). ANF concentrations in plasma, cardiac atria, pituitary and nine microdissected brain regions of females (n = 5-13) were determined by radioimmunoassay during either early proestrus (09.00-11.00 h), late proestrus (17.00-19.00 h), estrus (09.00-11.00 h), early metestrus (09.00-11.00 h) and late metestrus (17.00-19.00 h). Patterns of cyclic ANF immunoreactivity in plasma and atria were inversely related to each other, with plasma levels being significantly elevated during early metestrus when atrial levels were significantly decreased. Statistically significant central fluctuations in ANF levels during the estrous cycle were only found in the hypothalamic periventricular region (hPVA) and in the dorsal raphe (DR). ANF levels declined in both regions after late proestrus. Results indicate a relationship between ANF activity and cyclic patterns of fluid volume regulation and with phasic reproductive hormonal events.

Sexual refractoriness and locomotion effects on brain monoamines in the male rat.

Serotonin (5-HT), 5-hydroxyindolacetic acid (5-HIAA), dopamine (DA), dihydroxyphenylacetic acid (DOPAC), and norepinephrine (NE) concentrations in seven brain regions were compared in sexually refractory, physically active, and inactive male rats. Also examined were 5-HIAA/5-HT and DOPAC/DA concentration ratios. Sexually refractory males were permitted uninterrupted copulation with successive receptive females until they failed to mount or ejaculate in a set period. Physically active males ran in motor-driven activity wheels except during the postejaculatory refractory periods of experimental animals, and inactive males remained alone in testing arenas. Significant group differences were found only in monoamine concentrations in the medial preoptic area (MPOA) and the medial forebrain bundle (MFB). In the MPOA, 5-HT concentration was elevated in sexually refractory males, as was DA in both refractory and active animals. In the MFB, 5-HT concentration was increased in active males. MFB DOPAC levels of sexually refractory rats significantly correlated inversely with their ejaculation totals, as did MFB and dorsal raphe (DR) NE levels. The results suggest that the MPOA is a forebrain target for inhibitory influences on male rat sexual behavior of ascending serotonergic fibers and that increased MFB 5-HT and MPOA DA may be associated with general activity.

Phase I study of aziridinylbenzoquinone (AZQ, NSC 182986) in children with cancer.

Aziridinylbenzoquinone is a quinone compound capable of penetrating the central nervous system. It has demonstrated activity against both intracranial and i.p. murine tumors and human tumor xenographs. We have conducted a Phase I trial of aziridinylbenzoquinone in 60 children with advanced cancer who were refractory to conventional therapy. The drug was given by slow i.v. push on a daily schedule for 5 days every 3 to 4 weeks. The dose range explored included 6 dose levels, ranging from 6 to 12 mg/sq m daily for 5 days in patients with solid tumors and leukemia, and in patients with leukemia, 20, 25, and 30 mg/sq m daily for 5 days. Myelosuppression was the dose-limiting side effect. In patients with solid tumor the highest dose studied was 12 mg/sq m, and the median nadir white blood cell and platelet counts were 0.7 X 10(3) and 6.0 X 10(3)/microliter on Days 17 and 22, respectively. The median recovery day for white blood cells was 39. There may be some evidence of cumulative toxicity with prolonged thrombocytopenia. Other side effects were mild nausea, vomiting, and mucositis. Elevations in liver enzymes and bilirubin were transient and dose dependent, occurring 3 to 4 weeks after drug administration. Of the 34 children with solid tumors, 33 were evaluable for hematopoietic toxicity, 3 were early deaths, and 31 receiving a total of 55 courses were evaluable for therapeutic response. Partial responses lasting 3 weeks to 6 months were seen in the 4 patients with Hodgkin's disease, and in a child with a metastatic spinal cord ependymoma. Fifty-two courses were given to 9 patients with acute lymphocytic leukemia and 17 with acute nonlymphoblastic leukemia. Of the 15 patients with acute nonlymphoblastic leukemia treated at doses greater than or equal to 25 mg/sq m/day for 5 days there was one early death and there were 2 M1 (less than or equal to 5% blasts with normal cellularity), 3 M2A (6 to 15% blasts), and 2 M2B (16 to 39% blasts) bone marrow responses lasting 1 to 3.5 months. Aziridinylbenzoquinone demonstrated activity against acute nonlymphocytic leukemia with maximal tolerated doses of 30 mg/sq m daily for 5 days. Its effect in Hodgkin's disease is encouraging; however, further study will be required to determine its efficacy in central nervous system cancers. Recommended doses for Phase II studies, using daily schedule for 5 days in children with solid tumors, is 9 mg/sq m, and in children with leukemia, it is 25 mg/sq m.