Activation of renal afferent pathways following furosemide treatment. I. Effects Of survival time and renal denervation

Three experiments were performed to determine whether renal afferent pathways were activated by the diuretic drug, furosemide. It was hypothesized that activated neurons of the renal afferent pathway would express the protein product Fos of the c-fos immediate early gene and be identified by immunocytochemical staining for Fos in the cell nucleus. In the first two experiments, rats were injected with either furosemide (5 mg) or vehicle solution (sterile isotonic saline) and sacrificed either 1.75 h (short-survival experiment) or 3.5 h (long-survival experiment) after injection. In both experiments, the furosemide-treated rats had significantly more Fos-positive cell nuclei than vehicle-treated rats in the subfornical organ (SFO), organum vasculosum lamina terminalis (OVLT), supraoptic nuclei (SON), and magnocellular region of the paraventricular nuclei (PVN) - areas previously shown to be activated by hypovolemia or peripheral angiotensin. In the short-survival experiment, the furosemide-treated rats had more Fos-positive cell nuclei in the nucleus of the solitary tract (NTS) and in the dorsal horn of the spinal cord at spinal levels T(11), T(12), and T(13). In contrast, furosemide treatment did not produce more Fos-positive cell nuclei in the NTS and dorsal horn of the spinal cord in the long-survival experiment. These results suggest that the activation of the SFO, OVLT, SON and PVN may be via a different mechanism than that of NTS or spinal cord dorsal horn. Based upon our previous work, we hypothesized that the NTS and spinal cord dorsal horn labeling was due to activation of sympathetic afferents originating in the kidney and labeling in forebrain structures was due to stimulation by angiotensin generated by renal renin release. To test this hypothesis, a third experiment was devised that was identical to the short-survival experiment, except that all rats had bilateral renal denervation surgery 1 week previously. In this experiment, furosemide administration increased the number of Fos-positive cells in the SFO, OVLT, SON and PVN, but not in the caudal thoracic spinal cord or NTS. These results together with the results of first two experiments lend support to our hypothesis that furosemide-induced neuronal activation in the thoracic spinal cord and NTS is due to activation of second- and/or third-order neurons of a renal sympathetic afferent pathway. Furosemide-induced activation in the SFO, OVLT, SON and PVN does not depend on renal innervation. It is hypothesized that activation in these forebrain regions depends on the action of angiotensin II that is generated after furosemide treatment. Our results indicate that both a hormonal pathway and a renal sympathetic afferent pathway conduct information from the kidney to the central nervous system (CNS) after furosemide treatment.

Activation of renal afferent pathways following furosemide treatment. II. Effect Of angiotensin blockade

The goal here and in the accompanying paper was to evaluate the two pathways used by the kidney to provide information to the central nervous system (CNS); e.g., the indirect, hormonal route via activation of the renin-angiotensin system and the direct pathway via activation of sympathetic afferents in the caudal thoracic spinal cord. Here, three experiments were designed to evaluate the actions of angiotensin elicited by subcutaneous injection of furosemide on neural activation of the CNS. The number of neurons immunocytochemically staining for the protein product (Fos) of the c-fos gene was used as an index of neuronal activation. In the first experiment, furosemide injection was preceded by treatment with a dose of Captopril, CAP, (an angiotensin-converting enzyme (ACE) inhibitor) that blocks the peripheral but not the central formation of angiotensin II. In the second experiment, furosemide injection was preceded by treatment with a higher dose of CAP; this dosage blocks the peripheral and central formation of angiotensin II. In the third experiment, furosemide injection was preceded by treatment with Losartan, a competitive receptor antagonist of type I angiotensin II receptors at a dose that would block central and peripheral angiotensin receptors. Control animals in each experiment received injections of vehicle (sterile isotonic saline) instead of furosemide. In each experiment, rats were sacrificed 1.75 h following furosemide or saline injection by transcardial perfusion and tissues were immunocytochemically processed for demonstration of Fos antigen. Rats receiving furosemide plus the low CAP dose showed more Fos-positive cells than control rats in the subfornical organ (SFO), organum vasculosum lamina terminalis (OVLT), supraoptic nucleus (SON), magnocellular region of the paraventricular nucleus, nucleus of the solitary tract (NTS), and caudal thoracic/rostral lumbar spinal cord dorsal horn. Rats receiving furosemide plus Losartan or furosemide plus the higher CAP dose did not show increased Fos immunoreactivity in any of the abovementioned structures relative to their respective control animals. We conclude that the receptor-mediated action of angiotensin II is in some way involved in the activation of the pathway that occurs in the SFO, OVLT, SON, and magnocellular region of the paraventricular nucleus (PVN) in response to furosemide treatment. It is possible that the furosemide-induced activation in the SON and PVN is not due to direct actions of angiotensin II on angiotensin receptors in those structures, but instead occurs synaptically as a result of inputs from the SFO and OVLT, which have themselves been activated directly by angiotensin II. In the accompanying paper, furosemide-induced activation in the NTS and caudal thoracic spinal cord is abolished by prior bilateral renal denervation, meaning that these neurons are likely part of a renal afferent pathway. Here, these structures did not elaborate Fos in animals injected with furosemide plus the high CAP dose or furosemide plus Losartan. Thus, the present results also suggest that the central blockade of the formation of angiotensin II or blockade of the actions of angiotensin II prevents in some way the activation of the renal afferent pathway mediated by the renal nerves (the direct pathway) in response to the actions of furosemide. Therefore, these results suggest that central angiotensin II is somehow involved in "priming" or increasing the sensitivity of the direct renal afferent pathway. Taken together with the accompanying paper, our results indicate that interruption of the direct pathway via renal denervation did not interfere with the elaboration of Fos in the lamina terminalis; in contrast, modification of the humoral renal afferent pathway can affect the sensitivity of the direct pathway. These results may have important implications for pathophysiological changes associated with fluid balance disorders including renal hypertension.

Bovine herpesvirus 5 glycoprotein E is important for neuroinvasiveness and neurovirulence in the olfactory pathway of the rabbit

Glycoprotein E (gE) is important for full virulence potential of the alphaherpesviruses in both natural and laboratory hosts. The gE sequence of the neurovirulent bovine herpesvirus 5 (BHV-5) was determined and compared with that of the nonneurovirulent BHV-1. Alignment of the predicted amino acid sequences of BHV-1 and BHV-5 gE open reading frames showed that they had 72% identity and 77% similarity. To determine the role of gE in the differential neuropathogenesis of BHV-1 and BHV-5, we have constructed BHV-1 and BHV-5 recombinants: gE-deleted BHV-5 (BHV-5gEDelta), BHV-5 expressing BHV-1 gE (BHV-5gE1), and BHV-1 expressing BHV-5 gE (BHV-1gE5). Neurovirulence properties of these recombinant viruses were analyzed using a rabbit seizure model (S. I. Chowdhury et al., J. Comp. Pathol. 117:295-310, 1997) that distinguished wild-type BHV-1 and -5 based on their differential neuropathogenesis. Intranasal inoculation of BHV-5 gEDelta and BHV-5gE1 produced significantly reduced neurological signs that affected only 10% of the infected rabbits. The recombinant BHV-1gE5 did not invade the central nervous system (CNS). Virus isolation and immunohistochemistry data suggest that these recombinants replicate and spread significantly less efficiently in the brain than BHV-5 gE revertant or wild-type BHV-5, which produced severe neurological signs in 70 to 80% rabbits. Taken together, the results of neurological signs, brain lesions, virus isolation, and immunohistochemistry indicate that BHV-5 gE is important for efficient neural spread and neurovirulence within the CNS and could not be replaced by BHV-1 gE. However, BHV-5 gE is not required for initial viral entry into olfactory pathway.

Characterization of the central cell groups regulating the kidney in the rat

Retrograde, transneuronal viral tracing technique combined with neurotransmitter immunohistochemistry was used to identify the type of neurons in spinal cord and brain that project to the rat's kidney. Pseudorabies virus (PRV) injections were made into the left kidney. After an incubation of 4 days postinjection, PRV-infected neurons were located immunocytochemically in the ipsilateral intermediolateral (IML) cell column of the spinal cord and several brainstem cell groups: medullary raphe nuclei, ventromedial medulla (VMM), rostral ventrolateral medulla (RVLM), A5 cell group and the hypothalamic paraventricular nucleus (PVH). In the medulla, serotonin (5-HT)-immunoreactive neurons of the caudal raphe nuclei, substance P (SP)-immunoreactive neurons of the raphe obscurus (ROb) nuclei and tyrosine hydroxylase (TH)-immunoreactive neurons of A5 cells were infected. In the VMM and RVLM, immunoreactive phenylethanolamine-N-methyltransferase (PNMT) neurons were infected. Some PRV-infected neurons in VMM contain 5-HT immunoreactivity. In the hypothalamus, immunoreactive vasopressin (VP) and oxytocin (OT) neurons were infected with PRV. This work indicates that sympathetic outflow to kidney is regulated by different types of neurons and the bulbospinal pathways regulating sympathetic outflow to the kidney are not obviously different from those regulating the other visceral, e.g., adrenal, heart, etc.

Spread of bovine herpesvirus type 5 (BHV-5) in the rabbit brain after intranasal inoculation

Following intranasal inoculation of wild-type BHV-5 in rabbits, we studied the sequential transneuronal passage of the virus in the CNS by immunocytochemistry, histopathology, and virus isolation. At 4 and 6 days postinfection (d.p.i.), rabbits had no or mild neurological signs, and virus was isolated only from the olfactory bulbs. At 8 and 9 d.p.i., infected rabbits had severe neurological signs, and virus could be isolated from multiple regions of the brain segments. In these rabbits, high titers of virus were consistently present in the anterior and posterior cortices, including frontal, piriform/entorhinal, temporal, parietal, and occipital cortices, the hippocampus and the amygdala. Virus was isolated occasionally from the midbrain/diencephalon and pons/medulla. Virus was not isolated from the cerebellum and trigeminal ganglion of rabbits examined from 2-12 d.p.i. Immunocytochemistry revealed virus-specific antigens at 4 d.p.i. within the glomerular layer, external plexiform layer, and mitral cell layer of the main olfactory bulb. At 6 d.p.i., virus-specific antigens were also present within the inner granular layer of the main olfactory bulb. At 8 and 9 d.p.i., widespread BHV-5-specific staining occurred in the areas of the brain connected to the main olfactory bulb, including the frontal/cingulate cortex, anterior olfactory nucleus, lateral olfactory tubercle, piriform/entorhinal cortex, hippocampus, amygdala, dorsal raphe, and locus coeruleus. In the trigeminal ganglion, specific staining was detected within a few neurons at 2,4, 6, 8 d.p.i. However, further spread of the virus along the trigeminal pathway was not evident. These data indicate that BHV-5 replicates and spreads preferentially in the olfactory pathway following intranasal instillation and that this viral spread correlated with the severity of neurological symptoms and histopathological lesions.

The renal afferent pathways in the rat: a pseudorabies virus study

Retrograde tract tracing studies have indicated that dorsal root ganglion cells from T8 to L2 innervate the rat's left kidney. Electrophysiology studies have indicated that putative second-order sympathetic afferents are found in the dorsal horn at spinal segments T10 to L1 in laminae V-VII. Here, the spread of pseudorabies virus through renal sensory pathways was examined following 2-5 days post-infection (PI) and the virus was located immunocytochemically using a rabbit polyclonal antibody. Two days PI, dorsal root ganglion neurons (first-order sympathetic afferents) were infected with PRV. An average of 1.2, 0.8, 2.1 and 4.4% of the infected dorsal root ganglion neurons were contralateral to the injected kidney at spinal segments T10, T11, T12 and T13, respectively. Four days PI, infected neurons were detected within laminae I and II of the dorsal horn of the caudal thoracic and upper lumbar spinal cord segments. The labeling patterns in the spinal cord are consistent with previous work indicating the location of renal sympathetic sensory pathways. The nodose ganglia were labeled starting 4 days PI, suggesting the involvement of parasympathetic sensory pathways. Five days PI, infected neurons were found in the nucleus tractus solitarius. In the present study, it was unclear whether the infected neurons in the nucleus tractus solitarius are part of sympathetic or parasympathetic afferent pathways or represent a convergence of sensory information. Renal denervation prevented the spread of the virus into the dorsal root ganglia and spinal cord. Sectioning the dorsal roots from T10-L3 blocked viral spread into the spinal cord dorsal horn, but did not prevent infection of neurons in dorsal root ganglion nor did it prevent infection of putative preganglionic neurons in the intermediolateral cell column. The present results indicated that renal afferent pathways can be identified after pseudorabies virus infection of the kidney. Our results suggest that renal afferents travel in sympathetic and parasympathetic nerves and that this information may converge at the NTS.

Neuropathology of bovine herpesvirus type 5 (BHV-5) meningo-encephalitis in a rabbit seizure model

The suitability of a rabbit seizure model for studying the neuropathogenesis of bovine herpesvirus type 5 (BHV-5) encephalitis was evaluated. Intranasal administration of BHV-5 (strain TX89) together with intramuscular administration of dexamethasone produced seizures in 70% of rabbits tested and meningo-encephalitis in 100%. Infectious BHV-5 was consistently isolated from the following sites: olfactory bulb; anterior cortex, containing the frontal cortex, olfactory tract and anterior portion of the olfactory cortex; posterior cortex, containing the temporal, parietal, piriform, entorhinal and occipital cortices; amygdala; hippocampus. Less frequently, BHV-5 was isolated from the midbrain and diencephalon, the pons and medulla, the cerebellum, and the trigeminal ganglia. Rabbits similarly infected with the Cooper strain of bovine herpesvirus type 1 showed no neurological signs or meningo-encephalitis, and virus was not recovered from the brain. The brains of BHV-5-infected rabbits showed neuronal degeneration, leptomeningitis, gliosis and perivascular cuffing, predominantly in the olfactory cortex (piriform and entorhinal cortices), amygdala and hippocampus. Mild lymphocytic meningitis was seen in the olfactory bulb and focal lymphocytic infiltration was sometimes present in the medulla and cerebellum. BHV-5, specific antigens and nucleic acids were detected in the olfactory cortex, amygdala and hippocampus by immunohistochemical methods and in-situ hybridization. The results suggested that, after intranasal BHV-5 inoculation, the virus spread to the central nervous system via the olfactory and trigeminal pathways. The olfactory pathway was more susceptible than the trigeminal pathway to neuropathogenic effects.

Effect of the estrous cycle on olfactory bulb response to vaginocervical stimulation in the rat: results from electrophysiology and Fos immunocytochemistry experiments

To determine whether the stage of the estrous cycle modified the response of olfactory bulb neurons to vaginocervical stimulation, (1) vaginocervical stimulation was applied to animals in proestrus-estrus and metestrus-diestrus and the extracellular electrophysiological response of units in the mitral cell layer of the main olfactory bulb was compared, and (2) the effect of vaginocervical or sham stimulation and the effect of the estrous cycle on the number of neurons stained immunocytochemically for Fos in the main and accessory olfactory bulb was examined. Animals in proestrus-estrus had basal firing rates of 21.8 +/- 1.8 spikes per 5 s and vaginocervical stimulation produced an increase in firing rate. In contrast, animals in metestrus-diestrus had a slower basal firing rate (14.3 +/- 2.3 spikes per 5 s) and vaginocervical stimulation produced a decrease in the firing rate. For animals in proestrus-estrus, vaginocervical stimulation increased the number of Fos-stained cells in the granular cell layer of the accessory olfactory bulb, and in the glomerular and in external plexiform layers of the main olfactory bulb. In contrast, the number of Fos-stained cells decreased in the granular cell layer of the main olfactory bulb after stimulation was applied to animals in proestrus-estrus. The number of Fos-stained cells in the granular layer of the accessory olfactory bulb and the granular and glomerular cell layers of the main olfactory bulb was modulated by the estrous cycle. Therefore, olfactory bulb activity, measured both electrophysiologically and by Fos staining, was affected by the estrous cycle and vaginocervical stimulation, and the two variables interacted. It is likely that integration of interoceptive and environmental stimulation is important for the normal expression of sexual behavior in the female rat.

Increased renal interstitial hydrostatic pressure causes c-fos expression in the rat's spinal cord dorsal horn

To describe a sympathetic afferent circuit, interstitial hydrostatic pressure in the left kidney was increased in anesthetized rats for 1.5 h to activate renal mechanoreceptor afferents. Following renal afferent stimulation, the number of immunocytochemically stained cells for the immediate early gene c-fos was increased within the dorsal horn of the spinal cord. Relative to the surgical control procedure, increasing renal interstitial hydrostatic pressure produced more immunocytochemically stained cells per tissue section in laminae I and II of the dorsal horn both ipsilateral and contralateral to the stimulated kidney in the three most caudal thoracic spinal segments. Further, the number of c-fos immunocytochemically stained cells per section in the dorsal horn ipsilateral to the stimulated kidney was 28% greater than the number of stained cells contralateral to it. The staining patterns in the dorsal horns of stimulated and control animals were similar with most labeled cells in laminae I and II. These results indicate that (1) c-fos immunocytochemical staining may be useful for tracing specific sympathetic afferent pathways, (2) sensory pathways affected by increased renal interstitial hydrostatic pressure include spinal neurons located at lower thoracic levels, and (3) some of this sympathetic afferent pathway is located contralateral to the stimulated kidney. Neurons in the contralateral dorsal horn activated by renal stimulation may mediate renorenal reflexes.

Ureteral ligation induces Fos expression in the dorsal horn

To describe a sympathetic afferent circuit, the left ureter was ligated in anesthetized rats for 1.5-2 h followed by immunocytochemical processing to localize expression of either the immediate early gene (IEG) c-fos or Krox-24 in the spinal cord or dorsal root ganglia (DRG). No IEG expression was detected in DRG. Both Fos and Krox-24 expression was found in the dorsal horn. More Fos immunocytochemically stained cells were found in the dorsal horn both ipsi- and and contralateral to the ligated ureter at spinal segments T10-T13 after ureteral than after either sham ligation or anesthesia control procedures. More Fos stained cells were in the dorsal horn ipsilateral to the ligated ureter than on the contralateral side. The Fos staining patterns in the dorsal horn of ligated and sham-ligated animals were similar with most labeled cells in dorsomedial portions of laminae I and II. In contrast, the Fos staining pattern in the dorsal horn in anesthetized animals (unoperated controls) was noticeably different from operated animals with the most Fos cells in the ventrolateral part of laminae I-II. These results indicate that (1) Fos Immunocytochemistry may be useful for tracing sympathetic afferent pathways, (2) the sensory pathway activated by ureteral ligation enters the spinal cord at lower thoracic levels, where renal and upper ureteral afferents are terminating, and (3) some of this sympathetic afferent pathway is located contralateral to the stimulated kidney. Neurons activated by ureteral ligation in the contralateral dorsal horn may mediate reno-renal reflexes.

Nonuniform sympathetic nerve responses to intravenous hypertonic saline infusion

Peripheral hyperosmolality produced by the intravenous infusion of hypertonic saline (HTS) increases mean arterial blood pressure (MAP) in experimental animals. The mechanisms mediating the pressor response have not been fully ascertained, but likely involve vasopressin and/or activation of the sympathetic nervous system. The primary aim of this study was to determine if HTS infusion produces regionally uniform or nonuniform changes in sympathetic nerve discharge (SND). For this purpose we recorded renal, splanchnic and lumbar SND during intravenous HTS infusion (2.5 M NaCl, 10 microliters/100 g BW per min) in chloralose-anesthetized, Sprague-Dawley rats. In rats with intact arterial baroreceptors, HTS infusion significantly increased MAP (17 +/- 2 mmHg) and lumbar SND (29 +/- 13%) but reduced splanchnic (-52 +/- 7%) and renal SND (-33 +/- 8%). After sinoaortic denervation (SAD), HTS infusion significantly increased MAP (28 +/- 6 mmHg) and lumbar SND (27 +/- 9%) and decreased renal SND (-22 +/- 8%). The increase in lumbar SND occurred significantly sooner in SAD compared with baroreceptor-intact rats. In contrast, splanchnic SND remained unchanged from control levels during HTS infusion after SAD. These results demonstrate that HTS infusion produces regionally nonuniform changes in SND, and suggest that the pressor and lumbar sympathoexcitatory responses to HTS infusion are opposed by the arterial baroreceptors.

A constant current source for extracellular microiontophoresis

A sophisticated constant-current source suitable for extracellular microiontophoresis of tract-tracing substances, such as Phaseolus vulgaris leucoagglutinin, Biocytin or Fluoro-Gold, is described. This design uses a flyback switched-mode power supply to generate controllable high-voltage and operational amplifier circuitry to regulate current and provide instrumentation. Design features include a fast rise time, +/- 2000 V supply (stable output in < 250 ms), simultaneous load current and voltage monitoring, and separate pumping and holding current settings. Three features of this constant-current source make it especially useful for extracellular microiontophoresis. First, the output voltage monitor permits one to follow changes in the microelectrode resistance during current injection. Second, the voltage-limit (or out-of-compliance) indicator circuitry will sound an alarm when the iontophoretic pump is unable to generate the desired current, such as when the micropipette is blocked. Third, the high-compliance voltage power supply insures up to +/- 20 microA of current through 100 M omega resistance. This device has proven itself to be a reliable constant-current source for extracellular microiontophoresis in the laboratory.

Direct retinal communication with the peri-amygdaloid area

Retinal projections to the basal forebrain in male Syrian hamsters were examined at the ultrastructural level following bilateral intraocular injections of horseradish peroxidase conjugated to either cholera toxin (CT-HRP) or wheat germ agglutinin (WGA-HRP). Light level microscopic analysis confirmed retinal projections along basal telencephalon, and examination on the electron microscope of individual fibers from the peri-amygdaloid area revealed en passant synaptic profiles. Sections from animals treated with WGA-HRP showed evidence of transsynaptic communication in the form of labeled dendrites in the peri-amygdaloid area. Taken together, these data show that the retina communicates directly with the periamygdaloid area, where photic and chemosensory information may be integrated to modulate reproductive behavior.

Effects of continuous environmental illumination on the albino rat hypothalamo-neurohypophysial system

Continuous environmental illumination or constant light (LL) exposure causes a suppression of daily water intake, and long-term exposure of greater than 19 days produces a hypertrophy of magnocellular neuroendocrine cells (MNCs) in the hypothalamus. These findings led Glantz to hypothesize that LL increases the secretion of vasopressin (VP). We wanted to determine whether LL could trigger morphological changes within the hypothalamo-neurohypophysial system (HNS) seen with other manipulations that result in enhanced hormone release. The posterior pituitary of male albino rats that were exposed to LL for 24 or 48 h were examined ultrastructurally for evidence of enhanced hormone release. In addition, water intake, plasma VP levels, and MNC size within the supraoptic nucleus (SON) were measured. After LL exposure, the posterior pituitary morphology was different, suggesting enhanced hormone release. LL exposure did not affect plasma VP or the size of SON MNCs, but did suppress drinking behavior. These data show that posterior pituitary morphology is affected rapidly by LL exposure. The HNS response to LL exposure may consist of changes within the first 24 h of LL found within the posterior pituitary followed later by hypertrophy of the SON MNCs.

Supraoptic nucleus afferents from the accessory olfactory bulb: evidence from anterograde and retrograde tract tracing in the rat

Our earlier electrophysiological work provided evidence of a direct input to the supraoptic nucleus (SON) from the olfactory bulbs; however, these experiments could not determine if the input originated in the main and/or accessory portions of the olfactory bulb. Here, a connection between the accessory olfactory bulb (AOB) and the SON of the rat was examined using a combination of anatomic techniques. We employed neurophysin immunocytochemistry to delineate the morphological boundaries of the SON and the proximal arborizations of supraoptic dendrites. Accessory olfactory bulb efferents to the SON were studied by injection of wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP) into the AOB. The distribution of retrogradely labeled cells within the AOB was also determined after injection of either rhodamine-labeled latex microspheres (rhodamine beads) or Fluoro-Gold (FG) into the SON. Neurophysin immunocytochemistry revealed that SON dendrites extended beyond the generally accepted boundaries of the nucleus, coursing ventrolaterally along the surface of the periamygdaloid cortex. Anterograde tract tracing with WGA-HRP labeled AOB efferents including a dense plexus of terminals and fibers around the ipsilateral SON along the path of the ventrally projecting dendrites. Injections of retrograde tracers into the SON resulted in rhodamine bead or FG labeling of mitral cells throughout the ipsilateral AOB. Taken together, these anatomic studies suggest a direct projection from the accessory olfactory bulb to the SON of the rat and thus a vomeronasal organ to SON pathway.

Intravenous injection of Evans Blue labels magnocellular neuroendocrine cells of the rat supraoptic nucleus in situ and after dissociation

Previous work has demonstrated that intravenous injection of neuronal tracers, e.g. horseradish peroxidase or Fast Blue, can retrogradely label neurons in brain areas that project outside the blood-brain barrier, e.g. magnocellular neuroendocrine neurons of the hypothalamus. Here we have shown that 24 h after intravenous injection of the fluorescent retrograde tracer Evans Blue, the same population of magnocellular neuroendocrine neurons is labeled in the paraventricular, supraoptic and accessory magnocellular nuclei. Parvicellular neuroendocrine cells in the paraventricular nuclei are also labeled. Most Evans Blue-labeled magnocellular neuroendocrine cells in the supraoptic nucleus could be stained immunocytochemically for neurophysins, suggesting that these neurons continue to produce their peptide hormones after taking up the fluorescent dye. Ultrastructural observation of supraoptic cells retrogradely labeled with Evans Blue shows that 95% of the neurons appeared healthy. There was no ultrastructural evidence of degeneration, hyperstimulation, or interruption of the axoplasmic flow. Labeling the neuroendocrine cells with Evans Blue did not alter the size of magnocellular cells, the animal's fluid balance or ingestive behavior. Following enzymatic/mechanical dissociation of the supraoptic nucleus from animals that had been injected with Evans Blue 24 h previously, phase-bright neurons that often contained fluorescent material were observed, thus identifying these neurons as neuroendocrine. Recording from identified neuroendocrine cells showed that these neurons generated spontaneous or current-evoked overshooting action potentials with an afterhyperpolarization and had negative resting membrane potentials. Action potential broadening, a feature of magnocellular neurons, was observed during bursts of action potentials elicited by depolarizing current injection. Taken together, this work would suggest that Evans Blue is non-toxic at the doses used and that it provides a method to identify single neuroendocrine cells in primary cell cultures made from adult hypothalamus for voltage-clamp recordings.

Retinohypothalamic tract in the female albino rat: a study using horseradish peroxidase conjugated to cholera toxin

There are several anatomically and functionally distinct retinofugal pathways, one of which is the retinohypothalamic tract (RHT). In this study, horseradish peroxidase conjugated to cholera toxin (CT-HRP), a sensitive neural tracer, was employed to describe the RHT in the female albino rat. Following uniocular injection of CT-HRP, both medial and lateral components of the RHT were evident. The medial component swept caudally into and through the suprachiasmatic nucleus (SCN) and dorsally to the subparaventricular zone. Terminal label was seen in the medial preoptic region, peri-SCN area, retrochiasmatic area, periventricular nucleus, anterior and central parts of the anterior hypothalamic area, and the subparaventricular zone. In contrast to the more focused and symmetrical medial component, the lateral component was diffuse with light terminal label in the lateral preoptic region, olfactory tubercle, lateral hypothalamus, supraoptic nucleus, and medial and posteroventral medial amygdaloid nuclei. The striking exception to this diffuse pattern of the lateral component was an extremely dense columnar terminal field over the dorsal border of the supraoptic nucleus. Whereas the intensity of label in terminal fields of the medial component was often similar on the sides ipsilateral and contralateral to the injection, the lateral component was consistently asymmetrical with greater labeling on the side contralateral to the injection. In addition, a light projection arrived at several thalamic nuclei by returning toward the thalamus from the tectal or pretectal areas via stria medullaris, and thus was not a part of the RHT. Implications for circadian as well as noncircadian photobiologic effects are discussed.

Retinofugal projections to the hypothalamus, anterior thalamus and basal forebrain in hamsters

In Part a of the study, the retinal inputs to the hypothalamus, anterior thalamus and basal forebrain of Syrian hamsters were studied using intraocular injections of horseradish peroxidase conjugated to cholera toxin (CT-HRP). In the hypothalamus, the heaviest retinal input was to the suprachiasmatic nucleus (SCN), however, many labeled fibers coursed through the SCN to reach more caudal, periventricular and lateral sites including the anterior and lateral hypothalamus, the paraventricular nucleus (PVN), the subparaventricular zone, the ventromedial nucleus and the pars compacta of the dorsomedial nucleus. Some of these fibers continued dorsally into the zona incerta (ZI). Other fibers emerged from the lateral optic chiasm and traveled either rostro-medially to end in the preoptic area (POA) or further laterally to reach the supraoptic nucleus. A subset of fibers extended laterally from the chiasm to form a well-defined tract which provided input to the pyriform cortex. The extrageniculate retinal input to the thalamus was to the anterior thalamic area (AT) via the stria terminalis. In Part b, injections of rhodamine-labeled latex microspheres were made in three brain areas that contained labeled fibers after intraocular injections of CT-HRP. Injections in the AT, PVN/ZI area and POA consistently produced a small number of labeled retinal ganglion cells, whereas control injections did not. Taken together, these results indicate that many regions of the brain involved in the control of reproductive and regulatory functions receive photic informations via direct retinal inputs. These retinal inputs may play a role in the photoperiodic modulation of physiology and behavior.

Collateral input to the paraventricular and supraoptic nuclei in rat. II. Afferents from the ventral lateral medulla and nucleus tractus solitarius

In the rat, medullary afferents to the hypothalamic magnocellular nuclei mediate the baroreceptor reflexes of vasopressinergic neurons and the cholecystokinin- or gastric distention-induced excitation of oxytocinergic neurons. One strategy that reflexes such as these may use to coordinate the activity of magnocellular neuroendocrine neurons is collateral branching of input. Previous work has shown that the distributions of medullary neurons projecting to the paraventricular and the supraoptic nuclei overlap and that their axons branch. Thus, we hypothesized that single neurons in the ventral lateral medulla and/or the nucleus tractus solitarius would project to both the paraventricular and supraoptic nuclei via collateral branches of their axons. Medullary afferent neurons were retrogradely labeled after injection into the paraventricular and the supraoptic nucleus on one side of the brain with two different fluorescent tracers: Fluoro-Gold or rhodamine-labeled latex microspheres. The topographic distribution of labeled cells in the medulla containing either a single fluorescent tracer or both tracers were plotted. Of these labeled neurons, a small percentage (7%) contained both dyes, suggesting that they send collateral branches to both of the magnocellular neuroendocrine nuclei injected. Single labeled cells were both ipsi- and contralateral to the injected side (53% ipsilateral), but most double-labeled cells were ipsilateral (84%). In rats, areas that project to both the paraventricular and the supraoptic nuclei may act upon both nuclei together. Thus, afferent inputs, in conjunction with the known inter- and intracellular changes that take place within the magnocellular nuclei, may be involved with the coordinated responses throughout magnocellular neuroendocrine system during medullary reflexes, i.e., the baroreceptor-mediated reflexes or the gastric distention reflexes.

Voltage-clamp recordings from identified dissociated neuroendocrine cells of the adult rat supraoptic nucleus

In vitro intracellular recordings of membrane potential obtained from the oxytocin and vasopressin neurons of the mammalian hypothalamo-neurohypophysial system in slices (1-3) and expiants (4, 5) have demonstrated many of the intrinsic properties of these magnocellular neuroendocrine cells (MNCs). Voltage-clamp techniques, which are required to study directly the currents underlying intrinsic or transmitter-evoked potential changes, have been applied to cultured embryonic (6) or neonatal supraoptic neurons (7-9) and have been successfully applied to adult supraoptic neurons in situ in only one laboratory (10, 11). We have modified a technique for dissociation of viable adult guineapig hippocampal neurons (12) to dissociate supraoptic MNCs from adult rats for voltage-clamp studies. MNCs were selectively labelled with a fluorescent dye in vivo so that they could be identified after dissociation and prior to making recordings. These data have been published in abstract form elsewhere (13, 14).

Collateral input to the paraventricular and supraoptic nuclei in rat. I. Afferents from the subfornical organ and the anteroventral third ventricle region

Injections of two fluorescent retrograde tracers were used to investigate the existence of collateral branching of input to the hypothalamic magnocellular neuroendocrine neurons. Injection of one tracer (either Fluoro-Gold or rhodamine-labeled microspheres) into the supraoptic nucleus and the other tracer into the ipsilateral paraventricular nucleus produced labeled neurons within the subfornical organ and the anteroventral third ventricle area. Some labeled cells were found to contain both fluorescent tracers (double-labeled cells), suggesting that they project to both the paraventricular and supraoptic nuclei via branching axons. Most double-labeled cells were found within the subfornical organ. Fewer of these cells were located within the nucleus medianus preopticus, and still fewer were distributed in the organum vasculosum lamina terminalis, the bed nucleus of the stria terminalis, and the medial and the lateral preoptic areas. These data present the first direct evidence that single cells may provide input to more than one magnocellular neuroendocrine nucleus. Hypothetically, hormonal release would require coordinated firing of many magnocellular cells. Thus, the branched input to these neurons may assist in the organization and the timely activation of this system in response to physiological stimuli.

Magnocellular tuberomammillary nucleus input to the supraoptic nucleus in the rat: anatomical and in vitro electrophysiological investigations

Anatomical and electrophysiological methods were used to investigate the existence and role of inputs from the magnocellular tuberomammillary nucleus to the supraoptic nucleus. After injecting either Fluoro-Gold or rhodamine-labeled latex microspheres into the supraoptic nucleus, consistent patterns of retrogradely labeled neurons within the tuberomammillary nucleus were observed. The results indicate that both subdivisions of the supraoptic nucleus, the tuberal and the anterior, receive input from the tuberomammillary nucleus. Injections into the tuberal supraoptic nucleus tended to label more cells in the contralateral tuberomammillary nucleus, while injections into the anterior supraoptic nucleus may label more cells on the ipsilateral side. The in vitro intracellular electrophysiological results support the anatomical findings and extend them in several ways. Some tuberomammillary neurons were found to project to the supraoptic nuclei on both sides of the brain. Intracellular Lucifer Yellow injections into tuberomammillary cells after electrophysiological recording revealed labeled axons that were traceable into the supraoptic nucleus, where apparent varicosities (possible en passant terminals) were seen. Magnocellular tuberomammillary nucleus neurons had characteristic passive and active membrane properties and morphology, similar to histaminergic neurons in this area studied by other workers. Finally, in two of the 21 cases, Lucifer Yellow injection into one neuron revealed dye-coupled pairs of tuberomammillary neurons. Previous work by others has shown that histamine excited cells in the tuberal subdivision of the supraoptic nucleus, stimulating vasopressin release, and that the tuberomammillary nucleus provides histaminergic input to the anterior portion of the supraoptic. The present findings show that the tuberomammillary nucleus supplies input to both subdivisions of the supraoptic nucleus and that this input is provided bilaterally. Taken together with previous work, these data suggest that the tuberomammillary nucleus provides histaminergic input to the supraoptic nucleus and may be involved specifically with vasopressin release.