J. Patrick Card

Anatomical substrates for the central control of sympathetic outflow to interscapular adipose tissue during cold exposure

The thermogenic activity of interscapular brown adipose tissue (IBAT) in response to physiologic stimuli, such as cold exposure, is controlled by its sympathetic innervation. To determine which brain regions might be involved in the regulation of cold‐evoked increases in sympathetic outflow to IBAT, the present study compared central nervous system (CNS) areas activated by cold exposure with brain regions anatomically linked to the sympathetic innervation of IBAT. Immunocytochemical localization of Fos was examined in the brains of rats exposed to 4°C for 4 hours. In a separate group of rats, the neural circuit involved in IBAT control, including the location of sympathetic preganglionic neurons in the spinal cord, was characterized with pseudorabies virus, a retrograde transynaptic tracer. Central noradrenergic and serotonergic groups related to the sympathetic outflow to IBAT also were identified. Localization of viral antigens at different survival times (66–96 hours) revealed infection in circumscribed CNS populations, but only a subset of the regions comprising this circuitry showed cold‐evoked Fos expression. The raphe pallidus and the ventromedial parvicellular subdivision of the paraventricular hypothalamic nucleus (PVH), both infected at early survival times, were the main areas containing sympathetic premotor neurons activated by cold exposure. Major cold‐sensitive areas projecting to spinal interneurons or to regions containing sympathetic premotor neurons, which became infected at intermediate intervals, included lateral hypothalamic, perifornical, and retrochiasmatic areas, anterior and posterior PVH, ventrolateral periaqueductal gray, and Barringtons nucleus. Areas infected later, most likely related to reception of cold‐related signals, comprised the lateral preoptic area, parastrial nucleus, dorsomedial hypothalamic nucleus, lateral parabrachial nucleus, and nucleus of the solitary tract. These interconnected areas, identified by combining functional and retrograde anatomic approaches, likely constitute the central circuitry responsible for the increase in sympathetic outflow to IBAT during cold‐evoked thermogenesis. J. Comp. Neurol. 460:303–326, 2003.

NADPH oxidase immunoreactivity in the mouse brain

Superoxide production via NADPH oxidase has been shown to play a role in neurotoxicity, ischemic stroke, and possibly Parkinsons and Alzheimers diseases. In addition, NADPH oxidase-dependent production of superoxide may be necessary for normal brain functions, including neuronal differentiation and neuronal plasticity. To improve our understanding of NADPH oxidase in the brain, we studied the localization of the various protein components of NADPH oxidase in the central nervous system of the adult mouse using immunohistochemistry. We detected staining for the cytoplasmic NADPH proteins, p40(phox), p47(phox), and p67(phox), as well as the membrane-associated NADPH oxidase proteins, p22(phox) and gp91(phox) in neurons throughout the mouse brain. Staining of each of the NADPH oxidase proteins was observed in neurons in all regions of the neuraxis, with particularly prominent localizations in the hippocampus, cortex, amygdala, striatum, and thalamus. The expression of NADPH oxidase proteins in neurons suggests the possibility that enzymatic production of superoxide by a NADPH oxidase may play a role in both normal neuronal function as well as neurodegeneration in the brain.

Characterization of the central nervous system innervation of the rat spleen using viral transneuronal tracing.

Splenic immune function is modulated by sympathetic innervation, which in turn is controlled by inputs from supraspinal regions. In the present study, the characterization of central circuits involved in the control of splenic function was accomplished by injecting pseudorabies virus (PRV), a retrograde transynaptic tracer, into the spleen and conducting a temporal analysis of the progression of the infection from 60 hours to 110 hours postinoculation. In addition, central noradrenergic cell groups involved in splenic innervation were characterized by dual immunohistochemical detection of dopamine‐β‐hydroxylase and PRV. Infection in the CNS first appeared in the spinal cord. Splenic sympathetic preganglionic neurons, identified in rats injected with Fluoro‐Gold i.p. prior to PRV inoculation of the spleen, were located in T3–T12 bilaterally; numerous infected interneurons were also found in the thoracic spinal cord (T1–T13). Infected neurons in the brain were first observed in the A5 region, ventromedial medulla, rostral ventrolateral medulla, paraventricular hypothalamic nucleus, Barringtons nucleus, and caudal raphe. At intermediate survival times, the number of infected cells increased in previously infected areas, and infected neurons also appeared in lateral hypothalamus, A7 region, locus coeruleus, subcoeruleus region, nucleus of the solitary tract, and C3 cell group. At longer postinoculation intervals, infected neurons were found in additional hypothalamic areas, Edinger‐Westphal nucleus, periaqueductal gray, pedunculopontine tegmental nucleus, caudal ventrolateral medulla, and area postrema. These results demonstrate that the sympathetic outflow to the spleen is controlled by a complex multisynaptic pathway that involves several brainstem and forebrain nuclei. J. Comp. Neurol. 439:1–18, 2001.

Microglial activation precedes dopamine terminal pathology in methamphetamine-induced neurotoxicity

Previous studies have demonstrated methamphetamine (METH)-induced toxicity to dopaminergic and serotonergic axons in rat striatum. Although several studies have identified the nature of reactive astrogliosis in this lesion model, the response of microglia has not been examined in detail. In this investigation, we characterized the temporal relationship of reactive microgliosis to neuropathological alterations of dopaminergic axons in striatum following exposure to methamphetamine. Adult male Sprague-Dawley rats were administered a neurotoxic regimen of methamphetamine and survived 12 h, or 1, 2, 4, and 6 days after treatment. Immunohistochemical methods were used to evaluate reactive changes in microglia throughout the brain of methamphetamine-treated rats, with a particular focus upon striatum. Pronounced morphological changes, indicative of reactive microgliosis, were evident in the brains of all methamphetamine-treated animals and were absent in saline-treated control animals. These included hyperplastic changes in cell morphology that substantially increased the size and staining intensity of reactive microglia. Quantitative analysis of reactive microglial changes in striatum demonstrated that these changes were most robust within the ventrolateral region and were maximal 2 days after methamphetamine administration. Analysis of tissue also revealed that microglial activation preceded the appearance of pathological changes in striatal dopamine fibers. Reactive microgliosis was also observed in extra-striatal regions (somatosensory and piriform cortices, and periaqueductal gray). These data demonstrate a consistent, robust, and selective activation of microglia in response to methamphetamine administration that, at least in striatum, precedes the appearance of morphological indicators of axon pathology. These observations raise the possibility that activated microglia may contribute to methamphetamine-induced neurotoxicity.

Suprachiasmatic pacemaker organization analyzed by viral transynaptic transport

The suprachiasmatic nucleus (SCN) of the hypothalamus, the principal circadian pacemaker, is a paired structure with two subdivisions, a ventral core receiving photic input and a dorsal shell receiving non-photic input. Rhythmicity is thought to be generated by individual SCN neurons which are coupled to achieve synchrony [D.K. Welsh, D.E. Logothetis, M. Meister, S.M. Reppert, Individual neurons dissociated from rat suprachiasmatic nucleus express independently phased circadian firing patterns, Neuron, 14 (1995) 697-706]. Normally, the core and shell, and the nuclei on each side, act in unison to transmit rhythmicity to effector systems. It is not known how coupling between neurons in the two subdivisions, and between the two SCNs, takes place. In the present study, we analyze the intrinsic, commissural, and efferent projections of the SCN using the swine herpesvirus (pseudorabies virus, PRV) as a tool for transynaptic analysis of circuits and small iontophoretic injections of the conventional tracer horseradish peroxidase (HRP) conjugated to fluorescein. We find that the core and shell each project through commissural efferents to homologous contralateral areas. The core projects densely to shell but we find little reciprocal innervation. The two subdivisions project to different hypothalamic areas, with the core projecting to the lateral subparaventricular zone and shell to the dorsomedial hypothalamic nucleus and medial subparaventricular zone. These data are the first demonstration that connections within the SCN, and from the SCN to effector regions, are topographically organized and lend insight into the flow of information through and out of the pacemaker.

Efferent projections of rat rostroventrolateral medulla C1 catecholamine neurons: Implications for the central control of cardiovascular regulation

A replication‐defective lentivirus vector that expresses enhanced green fluorescent protein (EGFP) under the control of a synthetic dopamine‐β‐hydroxylase (DβH) promoter was used to define efferent projections of C1 catecholamine neurons in rat rostral ventrolateral medulla (RVLM). EGFP expression was restricted to C1 neurons and filled their somatodendritic compartments and efferent axons 7–28 days after vector injection. This included the descending projections to thoracic spinal cord and a network in brainstem, midbrain, and diencephalon. In caudal brainstem, restricted terminal fields were present in the dorsal motor vagal complex, A1, raphe pallidus and obscurus, and marginal layer of ventrolateral medulla. Innervation of raphe nuclei was most dense at the level of RVLM, but rostral levels of pallidus were devoid of innervation. A sparse commissural projection to contralateral RVLM was observed, and pericellular arbors were present in the dorsal reticular formation among the projection pathway of catecholamine axons. Rostral brainstem contained a dense innervation of locus coeruleus and the nucleus subcoeruleus. A restricted innervation of the ventrolateral column of the periaqueductal gray distinguished the midbrain. Forebrain labeling was restricted to the diencephalon, where distinctive terminal fields were observed in the paraventricular thalamic nucleus; the lateral hypothalamic area; and the paraventricular, dorsomedial, supraoptic, and median preoptic nuclei of hypothalamus. Projection fibers also coursed through the tuberal hypothalamus into the median eminence. Collectively, these data demonstrate that RVLM C1 neurons modulate the activity of other central cell groups known to participate in the regulation of cardiovascular and autonomic function. J. Comp. Neurol. 499:840–859, 2006.

Experimental Biology 2000 Symposium on Differential Control of Sympathetic Outflow NEUROANATOMICAL SPECIFICITY OF THE CIRCUITS CONTROLLING SYMPATHETIC OUTFLOW TO DIFFERENT TARGETS

1. Despite the emerging framework that central neural pathways controlling the activity of the sympathetic nervous system are capable of producing highly selective responses, the specific neural pathways governing different sympathetic outflows are poorly understood.

Use of pseudorabies virus to delineate multisynaptic circuits in brain: opportunities and limitations

Transsynaptic tracing with live virus is a powerful tool that has been used extensively to analyze central efferents that regulate peripheral targets. More recently, investigators have begun to use this new methodology with central injections to identify circuit anatomy within the brain. Although transsynaptic tracing with peripheral injection of pseudorabies virus has been extensively characterized, several methodological issues related to central application of this tracer have not been addressed. Here, we review the following issues relevant to the use of pseudorabies virus (PRV; Bartha strain) in experiments involving injection of virus into rat brain: (i) factors that determine the zone of viral uptake; (ii) uptake of pseudorabies virus by fibers of passage; (iii) viral invasion of the brain after leakage of virus into the brain ventricles; (iv) considerations for double labeling for PRV with peptides and neurotransmitters; (v) use of PRV with conventional retrograde tracers to anatomically identify relays in a multisynaptic pathway; and (vi) transport of PRV throughout the dendritic tree as a means of identifying inputs to distal dendrites. Collectively, the data demonstrate that PRV provides a powerful means of dissecting the synaptology of CNS circuitry when appropriate controls are incorporated into the experimental design. A set of recipes for various procedures are included at the end of this article.

Numerous GABAergic Afferents to Locus Ceruleus in the Pericerulear Dendritic Zone: Possible Interneuronal Pool

Most nuclei in the CNS are composed of principal neurons that project to other areas and interneurons that serve to integrate information among afferents. The noradrenergic brain nucleus locus ceruleus (LC) has appeared to be an exception to this general rule, because the LC is composed almost entirely of noradrenergic principal neurons. Here, we report that numerous small neurons in the peri-LC region become retrogradely labeled after focal injections of wheat germ agglutinin-apo (inactivated) horseradish peroxidase conjugated to colloidal gold, or pseudorabies virus (PRV), into the nuclear core of the rat LC. A substantial number of these neurons were routinely found within the dendritic field of the LC, in the area surrounding the compact cell-dense region classically defined as LC. Double labeling revealed that a large percentage of these cells stained for GABA. Ultrastructural analyses revealed axodendritic and axosomatic contacts between PRV-labeled afferents and LC neurons labeled with tyrosine hydroxylase immunohistochemistry. In addition, PRV-labeled neurons or axons were immunopositive for GABA in ultrastructural localizations. Analysis of the synaptology of immunopositive profiles demonstrated that these LC afferents in the peri-LC region receive several non-LC synaptic inputs. These results indicate that a population of small GABAergic neurons in the peri-LC dendritic zone may provide interneuronal integration for LC noradrenergic neurons.

NEUROINVASIVENESS OF PSEUDORABIES VIRUS INJECTED INTRACEREBRALLY IS DEPENDENT ON VIRAL CONCENTRATION AND TERMINAL FIELD DENSITY

Pseudorabies virus (PRV), a neurotropic swine α herpesvirus, has been used extensively for transneuronal analysis of multisynaptic circuitry after peripheral injection. In the present analysis, we examined the influence of viral concentration and neuronal architecture on the invasiveness, replication, and transynaptic passage of an attenuated strain of PRV (PRV‐Bartha) injected into rat striatum. Different concentrations of PRV‐Bartha were injected into the striatum at a constant rate of infusion (10 nl/minute), and animals were killed 50 hours later. Viral concentration was manipulated by either altering the volume of the inoculum (100, 50, 20 nl) or by diluting the inoculum within a constant volume of 100 nl. Immunohistochemical localization of infected neurons revealed dramatic differences in the progression of infection that were dependent directly on the concentration of injected virus. In every case, the pattern of infection was consistent with preferential uptake of virions by axon terminals and retrograde transynaptic passage of virus from the injection site. The known topographically organized corticostriatal projections permitted a precise definition of the zone of viral uptake. This analysis demonstrated that the “effective zone of viral uptake” (i.e., the zone within which viral uptake led to productive replication of virus) varied in relation to the concentration of injected virus, with the highest concentration of PRV invading terminals within a 500 μm radius of the canula. Concentration‐dependent changes in the progression of retrograde transynaptic infection also were observed. The highest concentration of virus produced the most extensive infection. The distribution of infected neurons in these cases included those with known afferent projections to striatum as well as those that became infected by retrograde transynaptic infection. Lesser concentrations of PRV‐Bartha produced an increasingly restricted infection of the same circuitry within the same postinoculation interval. It is noteworthy that neurons known to elaborate dense striatal terminal fields were less sensitive to reduction in viral concentration than those giving rise to terminal fields of lesser density. Collectively, the data indicate that the onset of viral replication after intracerebral injection of PRV is directly dependent on virus concentration and terminal field density at the site of virus injection. J. Comp. Neurol. 1999;407:438–452.