Identification of renal sympathetic preganglionic neurons in hamsters using transsynaptic transport of herpes simplex type 1 virus

Alzheimer's disease Braak Stage progressions: reexamined and redefined as Borrelia infection transmission through neural circuits

Brain structure in health is a dynamic energized equation incorporating chemistry, neuronal structure, and circuitry components. The chemistry "piece" is represented by multiple neurotransmitters such as Acetylcholine, Serotonin, and Dopamine. The neuronal structure "piece" incorporates synapses and their connections. And finally circuits of neurons establish "architectural blueprints" of anatomic wiring diagrams of the higher order of brain neuron organizations. In Alzheimer's disease, there are progressive losses in all of these components. Brain structure crumbles. The deterioration in Alzheimer's is ordered, reproducible, and stepwise. Drs. Braak and Braak have described stages in the Alzheimer disease continuum. "Progressions" through Braak Stages benchmark "Regressions" in Cognitive function. Under the microscope, the Stages of Braak commence in brain regions near to the hippocampus, and over time, like a tsunami wave of destruction, overturn healthy brain regions, with neurofibrillary tangle damaged neurons "marching" through the temporal lobe, neocortex and occipital cortex. In effect the destruction ascends from the limbic regions to progressively destroy the higher brain centers. Rabies infection also "begins low and finishes high" in its wave of destruction of brain tissue. Herpes Zoster infections offer the paradigm of clinical latency of infection inside of nerves before the "marching commences". Varicella Zoster virus enters neurons in the pediatric years. Dormant virus remains inside the neurons for 50-80 years, tissue damage late in life (shingles) demonstrates the "march of the infection" down neural pathways (dermatomes) as linear areas of painful blisters loaded with virus from a childhood infection. Amalgamation of Zoster with Rabies models produces a hybrid model to explain all of the Braak Stages of Alzheimer's disease under a new paradigm, namely "Alzheimer's neuroborreliosis" in which latent Borrelia infections ascend neural circuits through the hippocampus to the higher brain centers, creating a trail of neurofibrillary tangle injured neurons in neural circuits of cholinergic neurons by transsynaptic transmission of infection from nerve to nerve.

Heterogeneous requirement of NGF for sympathetic target innervation in vivo

The neurotrophin nerve growth factor (NGF) plays a crucial role in the development of the sympathetic nervous system. In addition to being required for sympathetic neuron survival in vivo and in vitro, NGF has been shown to mediate axon growth in vitro. The role of NGF in sympathetic axon growth in vivo, however, is not clear because of its requirement for survival. This requirement can be circumvented by a concomitant deletion of Bax, a pro-apoptotic Bcl-2 family member, thus allowing an examination of the role of neurotrophins in axon growth independently of their function in cell survival. Here, we analyzed peripheral sympathetic target organ innervation in mice deficient for both NGF and Bax. In neonatal NGF-/-; Bax-/- mice, sympathetic target innervation was absent in certain organs (such as salivary glands), greatly reduced in others (such as heart), somewhat diminished in a few (such as stomach and kidneys), but not significantly different from control in some (such as trachea). At embryonic day 16.5, peripheral target sympathetic innervation was also reduced in NGF-/-; Bax-/- mice, with analogous variability for different organs. Interestingly, in some organs such as the spleen the precise location at which sympathetic axons become NGF-dependent for growth was evident. We thus show that NGF is required for complete peripheral innervation of both paravertebral and prevertebral sympathetic ganglia targets in vivo independently of its requirement for cell survival. Remarkably, target organs vary widely in their individual NGF requirements for sympathetic innervation.

Identification of active thoracic spinal segments responsible for tonic and bursting sympathetic discharge in neonatal rats

The isolated thoracic cord of a neonatal rat in vitro generates tonic sympathetic activities in the splanchnic nerves. This tonic sympathetic nerve discharge (SND) has a prominent quasi-periodic oscillation at approximately 1-2 Hz. Bath application of bicuculline and strychnine, which removes endogenous GABA(A) and glycine receptor activities, transforms the quasi-periodic tonic SND into synchronized bursts (bSND). Picrotoxin, another GABA(A) receptor antagonist, also induces bSND. Serial transections of the thoracic cord (T1-12) were performed to identify the cord segments responsible for these tonic and bursting SNDs. Removal of T1-5 did not affect tonic SND. Nerve-cord preparation with either T6-8 or T10-12 segments could generate a substantial amount of tonic SND that retained comparable oscillating patterns. On the other hand, removal of T1-5 significantly reduced bSND amplitude without affecting its rhythmicity. Either T6-8 or T10-12 segments alone could generate bSND. Mid-point transection of T6-12 at T9 might split bSND rhythmogenesis, leading to the occurrence of bSND that could be attributed to two independent oscillators. Our results demonstrated that three segments within the T6-12 cord were sufficient to generate a rudimentary tonic and bursting SNDs. The thoracic cord segments, however, are dynamically interacting so that a full size bSND could only be produced with the intact thoracic cord.

Modifications to central neural circuitry during heart failure

AIM

During heart failure (HF), excess sodium retention is triggered by increased plasma renin-angiotensin-aldosterone activity and increased basal sympathetic nerve discharge (SND). Enhanced basal SND in the renal nerves plays a role in sodium retention. Therefore, as a hypothetical model for the central sympathetic control pathways that are dysregulated as a consequence of HF, the central neural pathways regulating the sympathetic motor output to the kidney are reviewed in the context of their role during HF.

CONCLUSION

From these findings, a model of the neuroanatomical circuitry that may be affected during HF is constructed.

Successful protection by amantadine hydrochloride against lethal encephalitis caused by a highly neurovirulent recombinant influenza A virus in mice

A mouse model system for a lethal encephalitis due to influenza has been established by stereotaxic microinjection with the recombinant R404BP strain of influenza A virus into the olfactory bulb of C57BL/6 mice. The virus infection spread selectively to neurons in nuclei of the broad areas of the brain parenchyma that have anatomical connections to the olfactory bulb, leading to apoptotic neurodegeneration. The inflammatory reaction at the extended stage of viral infection involved the vascular structures affected by induction of inducible nitric oxide synthase and protein nitration; those were related to the etiology of fatal brain edema. The intraperitoneal administration of amantadine inhibited the viral growth in the brain and saved mice from the lethal encephalitis. The severity of neuronal loss paralleled the time lag between the virus challenge and the start of amantadine treatment. Thus, early pharmacological intervention is essential to minimize neurological deficits due to influenza virus-induced neurodegeneration.

Autonomic dysreflexia in a mouse model of spinal cord injury

Most experimental studies of spinal cord injury have centered on the rat as an experimental model. A shift toward a mouse model has occurred in recent years because of its usefulness as a genetic tool. While many studies have concentrated on motor function and the inflammatory response following spinal cord injury in the mouse, the development of autonomic dysreflexia after injury has yet to be described. Autonomic dysreflexia is a condition in which episodic hypertension develops after injuries above the mid-thoracic segment of the spinal cord. In this study 129Sv mice received a spinal cord transection at the second thoracic segment. The presence of autonomic dysreflexia was assessed 2 weeks later. Blood pressure responses to stimulation were as follows: moderate cutaneous pinch caudal to the injury (35+/-6 mm Hg), tail pinch (25+/-7 mm Hg), and a 0.3 ml balloon distension of the colon (37+/-4 mm Hg). Previous reports have suggested that small diameter primary afferent fiber sprouting after spinal cord injury may be responsible for the development of autonomic dysreflexia. In order to determine whether autonomic dysreflexia in the mouse may be caused by a similar mechanism, the size of the small diameter primary afferent arbor in spinal cord-injured and sham-operated animals was assessed by measuring the area occupied by calcitonin gene-related peptide-immunoreactive fibers. The percentage increase in the area of the small diameter primary afferent arbor in transected over sham-operated spinal cords was 46%, 45% and 80% at spinal segments thoracic T5-8, thoracic T9-12 and thoracic T13-lumbar L2 respectively. This study demonstrates the development of autonomic dysfunction in a mouse model of spinal cord injury that is associated with sprouting of calcitonin gene-related peptide fibers. These results provide strong support for the use of this mouse model of spinal cord injury in the study of autonomic dysreflexia.

Distribution of sympathetic preganglionic neurons innervating the kidney in the rat: PRV transneuronal tracing and serial reconstruction

The organization of spinal motor circuitry to the kidney is not well-characterized and changes in renal innervation have been associated with disease states such as hypertension found in the spontaneously hypertensive rat or renal hypertension. Here, we describe the segmental and intra-segmental organization of the spinal motor circuitry that was resolved after neurotropic viral injection into the kidney and retrograde transneuronal transport to the spinal cord. In the first experiment, the serial reconstruction of infected neurons in the thoracolumbar spinal cord from T8-L1 was performed following injection of pseudorabies virus (PRV, Bartha strain) into either the cranial pole, the caudal pole or both the cranial and caudal poles of the left kidney in male rats. In the second experiment, rats received injections of two different PRV strains that were genetically engineered to express unique reporter molecules; one of the engineered strains was injected into the cranial pole and the other was injected into the caudal pole. Either 3- or 4-day post-infection, the animals were anesthetized and sacrificed by transcardial perfusion. PRV-infected neurons were located by immunocytochemistry against either PRV itself (experiment 1) or the unique marker proteins (experiment 2). After injection of both poles of the kidney, the majority of the infected neurons were found in the ipsilateral intermediolateral cell column (IML) from T10 to T12 with the mode at T11. Infected neurons were found in discrete neuron clusters in the intermediolateral cell column along the longitudinal axis in a repeating pattern of high and low density that has been called "beading". Three observations indicated a topographic distribution of renal sympathetic preganglionic neurons (SPN). First, after injection into either the cranial or caudal poles of the kidney, the mode of infected cells was located in segments T11 and T12, respectively. The one spinal segment shift in the mode suggested a topographic distribution. Second, in spinal segments T8-L1, comparison of the distributions of the neurons innervating each pole of the left kidney revealed an overlap in the distribution, except in the T11 segment. In the T11 segment, the neurons projecting to each pole tended to segregate into separate populations. Third, in rats that received injections of two PRV strains that were genetically engineered to express unique markers into opposite poles of the kidney, a segregation of neurons projecting to the cranial and caudal poles of the kidney was noted again in the T11 spinal segment and the segregation at adjacent spinal levels was obvious. The analysis of the distribution of infected neurons within each spinal cord segment (intra-segmental distribution) revealed three different patterns along the cranial-caudal dimension. In segments T8-T10, >60% of the infected neurons were located in the caudal half of the spinal segment. In segments T12-L1, >60% of the infected neurons were located in the cranial half of the spinal segment. In segment T11, the neurons were more evenly distributed throughout the segment. These intra-segmental distribution patterns were found after both 3- or 4-day survival periods post-infection and were found in most animals. The distribution of clusters of neurons revealed a similar intra-segmental pattern. Thus, as was described previously for the sympathetic postganglionic neurons that innervate the kidney, the present work indicates a topographic organization in the second-order neurons in the renal sympathetic efferent pathway. The physiological significance of this anatomical organization remains to be determined.

Neural circuitry of the kidney: NO-containing neurons

The neurons synthesizing nitric oxide (NO) that are part of the renal sympathetic pathways were located by double-staining for the neuronal isoform of nitric oxide synthase (nNOS) using immunocytochemistry to identify NO-synthesizing neurons and transneuronal tracing following infection of the left kidney with pseudorabies virus (PRV). Following kidney injection with PRV, the animals survived 4-day post-inoculation prior to sacrifice and tissue processing. PRV-infected neurons that double-stained for nNOS were found in the paraventricular hypothalamic nucleus (PVN), the raphe obscurus nucleus (ROb), the ventromedial medulla (VMM), the rostral ventrolateral medulla (rVLM) and the A5 cell group. In the thoracolumbar spinal cord, nNOS neurons co-localized with PRV-infected cells in the dorsal horn in laminae I, III-V ipsilateral to the injected kidney and in lamina X, the intermediolateral cell column, the lateral funiculus, the intercalated nucleus and the central autonomic area. We conclude that NO synthesizing cells may significantly affect renal autonomic pathways in the rat by interacting with the renal sensory and sympathomotor circuitry at multiple sites.

Tracing functionally identified neurones in a multisynaptic pathway in the hamster and rat using herpes simplex virus expressing green fluorescent protein

Using a genetically modified herpes simplex virus encoding green fluorescent protein we sought to establish if this viral modification could be used in transneuronal tracing studies of the sympathetic nervous system. The herpes simplex virus encoding green fluorescent protein was injected into the adrenal medulla of three hamsters and six rats. After a suitable survival period, neurones in the sympathetic intermediolateral cell column of the thoracolumbar spinal cord, rostral ventral medulla and paraventricular nucleus of the hypothalamus were clearly identified by the presence of a green fluorescence in the cytoplasm of the neurones of both species. Thus, herpes simplex virus encoding green fluorescent protein labelled chains of sympathetic neurones in the hamster and rat and therefore has the potential to be used in transneuronal tracing studies of autonomic pathways in these species.

Central nervous system structures labelled from the testis using the transsynaptic viral tracing technique

In the present study, the transneuronal transport of neurotrophic virus technique was used to identify cell groups of the spinal cord and the brain that are transsynaptically connected with the testis. Pseudorabies virus was injected into the testis and after survival times of 3-6 days, the spinal cord and brain were processed immunocytochemically using a polyclonal antibody against the virus. Virus-infected perikarya were detected in the preganglionic neurones of the spinal cord (T10-L1, L5-S1) and in certain cell groups and areas of the brain stem, the hypothalamus and the telencephalon. In the brain stem, the cell groups and areas in which labelled neurones were present included, among others, the nucleus of the solitary tract, the caudal raphe nuclei, the locus coeruleus and the periaqueductal grey of the mesencephalon. In the hypothalamus, virus infected perikarya were observed in the paraventricular nucleus and in certain other cell groups. Telencephalic structures containing labelled neurones included the preoptic area, the bed nucleus of the stria terminalis, the central amygdala and the insular cortex. These data identify a multisynaptic circuit of neurones in the spinal cord and in the brain which may be involved in the control of testicular functions.

Neuroglial activation repertoire in the injured brain: graded response, molecular mechanisms and cues to physiological function

Damage to the central nervous system (CNS) leads to cellular changes not only in the affected neurons but also in adjacent glial cells and endothelia, and frequently, to a recruitment of cells of the immune system. These cellular changes form a graded response which is a consistent feature in almost all forms of brain pathology. It appears to reflect an evolutionarily conserved program which plays an important role in the protection against infectious pathogens and the repair of the injured nervous system. Moreover, recent work in mice that are genetically deficient for different cytokines (MCSF, IL1, IL6, TNFalpha, TGFbeta1) has begun to shed light on the molecular signals that regulate this cellular response. Here we will review this work and the insights it provides about the biological function of the neuroglial activation in the injured brain.

Central control of the cardiovascular and respiratory systems and their interactions in vertebrates

This review explores the fundamental neuranatomical and functional bases for integration of the respiratory and cardiovascular systems in vertebrates and traces their evolution through the vertebrate groups, from primarily water-breathing fish and larval amphibians to facultative air-breathers such as lungfish and some adult amphibians and finally obligate air-breathers among the reptiles, birds, and mammals. A comparative account of respiratory rhythm generation leads to consideration of the changing roles in cardiorespiratory integration for central and peripheral chemoreceptors and mechanoreceptors and their central projections. We review evidence of a developing role in the control of cardiorespiratory interactions for the partial relocation from the dorsal motor nucleus of the vagus into the nucleus ambiguus of vagal preganglionic neurons, and in particular those innervating the heart, and for the existence of a functional topography of specific groups of sympathetic preganglionic neurons in the spinal cord. Finally, we consider the mechanisms generating temporal modulation of heart rate, vasomotor tone, and control of the airways in mammals; cardiorespiratory synchrony in fish; and integration of the cardiorespiratory system during intermittent breathing in amphibians, reptiles, and diving birds. Concluding comments suggest areas for further productive research.

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.

Neuronal labeling in the rat brain and spinal cord from the ovary using viral transneuronal tracing technique

In the present investigations the viral transneuronal labeling method, which is able to reveal hierarchial chains of central nervous system (CNS) neurons, was applied to identify sites in the CNS connected with the ovary and presumably involved in the control of ovarian functions. Pseudorabies virus was injected into the ovaries of rats and a few days later (at various times after the injection) the spinal cord and brain were examined for virus-infected neurons from the ovary. The virus-labeled nerve cells were identified by immunocytochemistry using polyclonal antiviral antibody. Virus-labeled neurons were detected both in the spinal cord and the brain. In the spinal cord such elements were observed in the intermediolateral cell column, in the dorsal horn close to the marginal zone and in the central autonomic nucleus. In the medulla oblongata and pons, neurons of several nuclei and cell groups (area postrema, nucleus of the solitary tract, dorsal vagal complex, nucleus ambiguus, paragigantocellular nucleus, parapyramidal nucleus, A1, A5 and A7 cell groups, caudal raphe nuclei, locus ceruleus, subceruleus nucleus, Barrington's nucleus, Kölliker-Fuse nucleus) were found to be transneuronally labeled. In the mesencephalon, the ventrolateral part of the periaqueductal gray matter contained virus-labeled neurons. In the diencephalon, a very intensive cell body labeling was observed in the hypothalamic paraventricular nucleus and a few virus-infected neurons could be detected in the lateral and dorsal hypothalamus, in the arcuate nucleus, zona incerta, perifornical area and in the anterior hypothalamus. Concerning the telencephalic structures, virus-labeled cells were found in the bed nucleus of the stria terminalis and in the central amygdala nucleus. These findings provide the first neuromorphological evidence for the existence of a multisynaptic neuronal pathway between the ovary and the CNS, and give a detailed account of the structures involved in this pathway.

Analysis of a multi-mutant herpes simplex virus type 1 for gene transfer into sympathetic preganglionic neurons and a comparison to adenovirus vectors

A non-replicating triple-mutant herpes simplex virus (14H delta 3vhsZ) expressing the bacterial marker enzyme beta-galactosidase, was assessed for neurotropism and cytopathic effects as a vector for gene transfer into differentiated phaeochromocytoma 12 cells in vitro and into spinal sympathetic neurons in vivo. In the in vivo study, the 14H delta 3vhsZ was injected into the adrenal gland of hamsters. For comparison, an evaluation of two adenovirus vectors, AdCA17lacZ and AdCA36lacZ, was performed. Infection of the differentiated phaeochromocytoma 12 cells by 14H delta 3vhsZ resulted in intense beta-galactosidase staining in 80-90% of the cells without changes in cell morphology, detected by light microscopy, after a period of four days. No cytoskeletal disruption was detected by immunocytochemistry for the neurofilament protein and no apoptosis was demonstrated by the Hoescht stain for nuclear chromatin in virus-infected cells in comparison to mock-infected control cells. Twoto three days after adrenal inoculation with 14H delta 3vhsZ, beta-galactosidase was detected in 240 preganglionic neurons per hamster (n = 8), a number equal to about 25% of the population of targeted neurons. The beta-galactosidase reaction product extended throughout the normal kite-shaped neuronal somata and extensive dendritic arbour. The number decreased to 120 by five days (n = 3) and to two by eight days (n = 4). This decrease was presumably due to loss of expression of the marker gene and not to cell death because, at eight days, the number of sympathetic pregnanglionic neurons in the nucleus intermediolateralis, pars principalis, that were immunoreactive for the neurotransmitter enzyme choline acetyltransferase, and demonstrated nicotinamide adenine dinucleotide phosphate-diaphorase activity, were the same on the infected left side of the cord as on the uninfected right side. Inflammatory cells surrounded some of the infected neurons at five days but by eight days the infiltrate was reduced. Infection of differentiated phaeochromocytoma 12 cells by AdCA17lacZ and AdCA36lacZ also resulted in marker gene expression in a large proportion of the cells (80-90%) in the absence of cytopathic effects. In contrast, four days after adrenal injection of AdCA17lacZ or AdCA36lacZ (n = 5 for each) only an average of three preganglionic neurons per hamster expressed beta-galactosidase activity, despite clear adrenal infection. AdCA17lacZ and AdCA36lacZ both produced light patches of staining confined to the neuronal soma. These neurons had normal morphology but sometimes were surrounded by an inflammatory infiltrate. In conclusion, the non-replicating herpes simplex virus, 14H delta 3vhsZ, had minimal cytotoxic effects in neurons, in vitro or in vivo, and was efficiently transported from the adrenal gland to infect many sympathoadrenal pregnanglionic neurons. In contrast, very few neurons demonstrated beta-galactosidase activity after injection into the adrenal gland of AdCA17lacZ and AdCA36lacZ. Therefore, 14H delta 3vhsZ is a more suitable vector than either of the adenovirus vectors tested for eliciting short-term changes in preganglionic neuron gene expression.

Identification of lamina V and VII interneurons presynaptic to adrenal sympathetic preganglionic neurons in rats using a recombinant herpes simplex virus type 1

Although indirect evidence suggests that the control of sympathetic preganglionic neurons is mediated to a great extent through interneurons, little is known about the location, morphology or neurotransmitter phenotype of such interneurons. This limitation seriously impedes our understanding of spinal synaptic circuits crucial to control of arterial pressure and other visceral functions. We used a highly neurotropic, minimally cytopathic recombinant herpes simplex virus type-1 to study spinal "sympathetic" interneurons labelled by trans-synaptic transport of the virus from the adrenal gland in rats. Approximately 120-320 infected neurons/rat were identified by immunocytochemical detection of the viral antigen. We distinguished between virus-infected preganglionic neurons and infected interneurons by (i) their location within the spinal laminae, (ii) their size and shape and (iii) the presence or absence of immunoreactivity for the acetylcholine-synthesizing enzyme, choline acetyltransferase, a marker of sympathetic preganglionic neurons. Virus-labelled sympathetic preganglionic neurons were found within the known spinal preganglionic nuclei. Non-cholinergic, virus-labelled neurons were located throughout lamina VII and in the ventral portion of lamina V. These putative interneurons were found in the major spinal preganglionic nuclei, usually intermingled with the preganglionic neurons. Sometimes, they were located in clusters separate from the preganglionic neurons. The interneurons were approximately 15 microm in diameter, smaller than the average preganglionic neuron (diameter=25 microm), and had a few fine processes emanating from them. These non-cholinergic interneurons constituted approximately one-half of the population of virus-infected neurons. In summary, with the use of a recombinant herpes simplex virus, we identified a large number of non-cholinergic interneurons close to, or intermingled with, adrenal sympathetic preganglionic neurons. The neurotransmitter phenotype of these neurons remains to be determined but they likely integrate much of the supraspinal and primary afferent inputs to spinal preganglionic neurons that control arterial pressure and other visceral functions.

Simultaneous identification of two populations of sympathetic preganglionic neurons using recombinant herpes simplex virus type 1 expressing different reporter genes

We generated neurotropic herpes simplex type 1 viruses expressing human placental alkaline phosphatase and studied the utility of this enzyme as a marker of infected neurons. The neurotropism of these viruses was assessed by their ability to infect sympathetic preganglionic neurons after adrenal injection in hamsters. The transneuronal transfer of these viruses was examined by their ability to cross the peripheral synapse from the kidney to renal preganglionic neurons or to cross the central synapse from the adrenal gland to the medulla oblongata. Finally, we injected an alkaline phosphatase-expressing herpes simplex virus into the adrenal gland and a beta-galactosidase-expressing herpes simplex virus (US5gal) into the muscular wall of the small intestine to label two neural circuits in one animal and to assess the feasibility of a dual-virus labelling system. The alkaline phosphatase gene was inserted into the glycoprotein J locus or the virus-induced host shut-off locus in the herpes simplex genome to create viruses which replicate (gJHAP HSV or vhsHAP HSV) or into the thymidine kinase locus to generate a virus that does not replicate in neurons in vivo (TK- HAP HSV). Each of the three viruses was retrogradely transported from the adrenal gland of hamsters to sympathetic preganglionic neurons, suggesting that the neurotropism of these viruses was maintained. gJHAP HSV travelled transneuronally from the kidney to sympathorenal preganglionic neurons and from the adrenal gland to neurons in the rostral ventrolateral medulla. Neuronal infection with alkaline phosphatase-expressing virus could be identified using histochemistry but detailed morphology of these neurons was not revealed. However, staining by anti-herpes simplex virus immunoperoxidase demonstrated that they had normal morphology. Identification of two distinct neural circuits in one animal was achieved with our dual-virus labelling system. The nonreplicating TK- HAP HSV was used in combination with US5gal to identify intestinal and adrenal sympathetic preganglionic neurons. The beta-galactosidase-expressing intestinal neurons were labelled bilaterally in the nucleus intermediolateralis, pars principalis, and alkaline phosphatase-expressing adrenal neurons were found ipsilaterally. Some clusters of sympathetic preganglionic neurons in the nucleus intermediolateralis, pars principalis contained mostly intestinal sympathetic preganglionic neurons and a few adrenal sympathetic preganglionic neurons. In other areas, the opposite pattern occurred. About 3-7% of the labelled sympathetic preganglionic neurons were double-labelled by both markers. The distinct and crisp morphology and dendritic processes of neurons stained by beta-galactosidase histochemistry contrasted with the partial staining of neurons by alkaline phosphatase, revealing beta-galactosidase as a better marker of infected neurons. In conclusion, alkaline phosphatase-expressing herpes simplex viruses are yet neurotropic after insertion of this marker enzyme into any of three different loci of the herpes simplex genome. One replicating alkaline phosphatase-expressing virus travelled transneuronally. These alkaline phosphatase-expressing herpes simplex virus can be used together with beta-galactosidase-expressing herpes simplex viruses to determine the target specificity of sympathetic preganglionic neurons controlling visceral organs or can be used to express two different recombinant genes in two targeted neuronal populations. This study suggests that sympathetic preganglionic neurons controlling the intestine and adrenal gland are almost completely distinct.

Gene transfer into sympathetic preganglionic neurons in vivo using a non-replicating thymidine kinase-deficient herpes simplex virus type 1

The suitability of non-replicating thymidine kinase deficient herpes simplex virus type 1 expressing bacterial beta-galactosidase (tk-lacZ HSV-1) as a transfer vehicle into sympathetic preganglionic neurons in vivo was assessed. Many sympathoadrenal preganglionic neurons (451 +/- 105) with normal morphology were identified using beta-galactosidase histochemistry two days after inoculation of tk-lacZ HSV-1 into the adrenal gland of hamsters. Beta-galactosidase activity co-localized with nicotinamide adenine dinucleotide phosphate-diaphorase-positive sympathetic preganglionic neurons in the nucleus intermediolateralus, pars principalis. The maximal number of beta-galactosidase expressing neurons was found two days post-inoculation but this number dropped dramatically after this time. An inflammatory infiltrate was abundant around infected neurons and in the white matter at five days and infected neurons appeared morphologically abnormal. At 26 days, the infiltrate was still present but no infected sympathoadrenal preganglionic neurons were detected. Approximately 25% fewer nicotinamide adenine dinucleotide phosphate-diaphorase-positive neurons in the nucleus intermediolateralis, pars principalis were counted ipsilaterally than contralaterally in animals infected for 14, 21 or 26 days with tk-lacZ HSV-1, compared to the 3% difference in animals mock-infected for 26 days. Approximately 33% of the estimated number of sympathoadrenal preganglionic neurons infected with tk-lacZ HSV-1 at five days were apoptotic or necrotic. About 60% of neurons infected with tk-lacZ HSV-1 at two days no longer expressed nicotinamide adenine dinucleotide phosphate-diaphorase at 14-26 days. In conclusion, the non-replicating thymidine kinase deficient HSV-1 was efficiently retrogradely transported from the adrenal gland to infect sympathoadrenal preganglionic neurons. These gene transfer experiments using tk-lacZ HSV-1 suggest that foreign gene expression in sympathetic preganglionic neurons in vivo may be maximal two days after inoculation when beta-galactosidase was expressed in the greatest number of sympathetic preganglionic neurons. After two days, fewer neurons expressed beta-galactosidase and the presence of tk-lacZ HSV-1 appeared to be altering protein expression in sympathetic preganglionic neurons and/or leading to the demise of the infected neuron.

Experimental infection of swine and cat central nervous systems by the pig paramyxovirus of the blue eye disease

This study analyses whether the pig paramyxovirus of blue eye disease (PPBED) infects the central nervous system (CNS) utilizing anterograde and retrograde peripheral nerve transport systems. The virus was injected into muscle and skin, and inoculated per nasum. The presence of PPBED was detected by an immunohistochemical method using polyclonal mouse antibodies against the whole inactivated virus, and was revealed with polyclonal rabbit antibodies against mouse immunoglobulin G (IgG) labelled with peroxidase. The PPBED injected into the pig medial gastrocnemius (MG) muscle was detected in a terminal branch innervating the MG muscle, in neural fibres of the sciatic nerve, in fibres of the ventral and dorsal spinal roots and in ventral horn neurones of the spinal cord. When PPBED was injected into the skin area innervated by the sural nerve, it was detected in neural fibres of the sural and sciatic nerves and in spinal cord dorsal horn neurones. The per nasum inoculum rapidly invaded the CNS through the olfactory nerve. The study concluded that, in order to invade the CNS, PPBED was transported retrogradely by peripheral cutaneous and muscular nerves, and anterogradely by the olfactory nerve. No PPBED was detected in either cat peripheral nerves or in cat CNS.

Identification of sympathetic preganglionic neurons controlling the small intestine in hamsters using a recombinant herpes simplex virus type-1

Sympathetic preganglionic neurons (SPNs) may be organized topographically within the spinal cord for selective control of visceral organs. We used a recombinant herpes simplex virus type-1 (rHSV-1) to identify SPNs innervating the small intestine in hamsters. These SPNs were distributed bilaterally in the cord from the fifth thoracic spinal segment to the second lumbar segment, but predominantly in thoracic segments 5-10. They had morphology similar to that of renal and adrenal SPNs infected with HSV-1. The majority of intestinal SPNs were found in the intermediolateral cell column, with a few located in the lateral funiculus. The SPNs labelled following duodenal injection of rHSV-1 were in the same spinal segments as the SPNs labelled following jejunal or ileal injections, suggesting lack of a relation between target topography and the topographic organization of these neurons. In addition, intestinal SPNs were located in the same spinal segments, and autonomic nuclei as renal and adrenal SPNs suggesting that SPNs controlling the abdominal viscera are not organized viscerotopically for discrete control of different organs.

CNS cell groups involved in the control of the ischiocavernosus and bulbospongiosus muscles: a transneuronal tracing study using pseudorabies virus

Transneuronal tracing techniques were used to identify spinal and brainstem neurons involved in the control of perineal muscles in the male rat. Two penile muscles, the bulbospongiosus and ischiocavernosus muscles, were injected with Bartha's strain of pseudorabies virus. After survival periods of 2, 4, and 5 days, the rats were killed and viral labeled neurons identified by immunohistochemistry. After a 2 day survival period, only pudendal motoneurons were labeled. More spinal and brainstem neurons were labeled at longer survival times. Putative spinal interneurons were found from T13 to S1. Large numbers of neurons were found in the lateral horn of the T13-L2 and L6-S1 segments which contain sympathetic and parasympathetic preganglionic neurons, respectively. However, retrograde labeling experiments verified that very few of the viral neurons were preganglionic neurons. Other labeled neurons were found in the intermediate cord, especially around the central canal. Relatively few labeled neurons were seen in the dorsal or ventral horn. In the brainstem, consistent labeling was seen in the ventrolateral medulla, raphe pallidus, and magnus, the A5 and locus ceruleus noradrenergic cell groups. Barrington's nucleus in the pontine tegmentum, the periaqueductal gray, and the paraventricular nucleus of the hypothalamus. The transneuronal labeling was consistent with what is currently known of the central nervous system (CNS) control of the perineal muscles.

Delivery of a foreign gene to sympathetic preganglionic neurons using recombinant herpes simplex virus

Two recombinant herpes simplex type 1 viruses expressing beta-galactosidase (encoded by the Escherichia coli lacZ gene) inserted into the unique long 41 (encoding virus host shutoff) or unique short 5 (encoding glycoprotein J) open reading frames were generated. Purified recombinants or wild-type herpes simplex type 1 were injected into the left adrenal gland of hamsters. Three days later, virus-infected neurons were detected in spinal cord sections from all infected hamsters. Neurons were visualized with beta-galactosidase histochemistry in spinal cord sections from hamsters infected with either of the recombinants but not with the wild-type virus. Wild-type virus could only be detected with immunocytochemistry. Insertional mutagenesis into the unique long 41 or unique short 5 regions of the herpes simplex genome by lacZ did not disrupt the neurotropic properties of the virus. Both recombinant viruses labelled the central nervous system sympathoadrenal preganglionic neurons as well as brainstem neurons. Because the virus host shutoff recombinant more readily crossed synapses to reach the brainstem compared to the glycoprotein J recombinant, the presence of glycoprotein J may facilitate cell to cell transmission in vivo. Both recombinants may be useful for the study of synaptic organization of neural circuits. Our recombinant viruses were less lytic yet neurovirulent after mutation of either glycoprotein J or virus host shutoff of herpes simplex virus type 1 wild-type. These recombinant viruses express the bacterial beta-galactosidase which is readily detectable using simple histochemistry. Inoculation of the adrenal gland or kidney with these viruses led to clear labelling of spinal cord cells. These viruses may be useful markers of specific neural circuits.

Identification of spinal interneurons antecedent to adrenal sympathetic preganglionic neurons using trans-synaptic transport of herpes simplex virus type 1

Control of sympathetic preganglionic neurons appears to be mediated, in part, through polysynaptic pathways using spinal interneurons. To identify spinal interneurons antecedent to adrenal sympathetic preganglionic neurons, we injected herpes simplex virus type 1 into the adrenal gland of hamsters as this virus is an effective trans-synaptic tracer of neural pathways. After a three day survival period, immunocytochemistry was used to visualize virus-infected spinal cord cells. Infected sympathetic preganglionic neurons with somata that were either kite-shaped, elliptical or fusiform and that had extensive dendrite arbors were identified as well as a group of smaller round cells with finer processes. For comparison, in additional hamsters, labelling with the retrograde tracer Fluoro-Gold and histochemical reactions for the enzyme nicotinamide adenine dinucleotide phosphate-diaphorase were used to identify sympathetic preganglionic neurons. Sympathetic preganglionic neurons identified with Fluoro-Gold or herpes virus were present mostly in the nucleus intermediolateralis, pars intermediolateralis and nucleus intermediolateralis, pars funicularis of the spinal cord. The smaller herpes virus-infected cells were found mostly medial to the preganglionic neurons in lamina VII and also dorsally in lamina V of the spinal cord. Assessing immunoreactivity for glial fibrillary acidic protein demonstrated that the smaller herpes virus-infected cells were not reactive astrocytes. Furthermore, these cells were immunoreactive for two neuronal markers, neuron-specific enolase and for microtubule-associated protein 2. These findings suggest that these smaller round cells with finer processes are distinct from sympathetic preganglionic neurons and astrocytes and may be interneurons antecedent to the sympathetic preganglionic neurons.

Central sympathetic mechanisms of blood pressure control in hamsters

The goal of this study was to investigate central vasomotor control of blood pressure in golden hamsters. Electrophysiological experiments demonstrated that tonic and reflex firing of renal nerves was controlled by brainstem and spinal circuits in manner similar to control of these nerves in rats, rabbits and cats. These findings confirmed that autonomic neural circuits for vasomotor control in hamsters are functionally similar to those of other well-studied species.