Connectivity of pacemaker neurons in the neonatal rat superficial dorsal horn.

Pacemaker neurons with an intrinsic ability to generate rhythmic burst-firing have been characterized in lamina I of the neonatal spinal cord, where they are innervated by high-threshold sensory afferents. However, little is known about the output of these pacemakers, as the neuronal populations that are targeted by pacemaker axons have yet to be identified. The present study combines patch-clamp recordings in the intact neonatal rat spinal cord with tract-tracing to demonstrate that lamina I pacemaker neurons contact multiple spinal motor pathways during early life. Retrograde labeling of premotor interneurons with the trans-synaptic pseudorabies virus PRV-152 revealed the presence of burst-firing in PRV-infected lamina I neurons, thereby confirming that pacemakers are synaptically coupled to motor networks in the spinal ventral horn. Notably, two classes of pacemakers could be distinguished in lamina I based on cell size and the pattern of their axonal projections. Whereas small pacemaker neurons possessed ramified axons that contacted ipsilateral motor circuits, large pacemaker neurons had unbranched axons that crossed the midline and ascended rostrally in the contralateral white matter. Recordings from identified spino-parabrachial and spino-periaqueductal gray neurons indicated the presence of pacemaker activity within neonatal lamina I projection neurons. Overall, these results show that lamina I pacemakers are positioned to regulate both the level of activity in developing motor circuits and the ascending flow of nociceptive information to the brain, thus highlighting a potential role for pacemaker activity in the maturation of pain and sensorimotor networks in the central nervous system.

The motor cortex communicates with the kidney.

We used retrograde transneuronal transport of rabies virus from the rat kidney to identify the areas of the cerebral cortex that are potential sources of central commands for the neural regulation of this organ. Our results indicate that multiple motor and nonmotor areas of the cerebral cortex contain output neurons that indirectly influence kidney function. These cortical areas include the primary motor cortex (M1), the rostromedial motor area (M2), the primary somatosensory cortex, the insula and other regions surrounding the rhinal fissure, and the medial prefrontal cortex. The vast majority of the output neurons from the cerebral cortex were located in two cortical areas, M1 (68%) and M2 (15%). If the visceromotor functions of M1 and M2 reflect their skeletomotor functions, then the output to the kidney from each cortical area could make a unique contribution to autonomic control. The output from M1 could add precision and organ-specific regulation to descending visceromotor commands, whereas the output from M2 could add anticipatory processing which is essential for allostatic regulation. We also found that the output from M1 and M2 to the kidney originates predominantly from the trunk representations of these two cortical areas. Thus, a map of visceromotor representation appears to be embedded within the classic somatotopic map of skeletomotor representation.

Amygdala connections with jaw, tongue and laryngo-pharyngeal premotor neurons.

As the central nucleus (CE) is the only amygdaloid nucleus to send axons to the pons and medulla, it is thought to be involved in the expression of conditioned responses by accessing hindbrain circuitry generating stereotypic responses to aversive stimuli. Responses to aversive oral stimuli include gaping and tongue protrusion generated by central pattern generators and other premotor neurons in the ponto-medullary reticular formation. We investigated central nucleus connections with the reticular formation by identifying premotor reticular formation neurons through the retrograde trans-synaptic transport of pseudorabies virus (PRV) inoculated into masseter, genioglossus, thyroarytenoid or inferior constrictor muscles in combination with anterograde labeling of CE axons with biotinylated dextran amine. Three dimensional mapping of PRV infected premotor neurons revealed specific clusters of these neurons associated with different oro-laryngo-pharyngeal muscles, particularly in the parvicellular reticular formation. CE axon terminals were concentrated in certain parvicellular clusters but overall putative contacts were identified with premotor neurons associated with all four oro-laryngo-pharyngeal muscles investigated. We also mapped the retrograde trans-synaptic spread of PRV through the various nuclei of the amygdaloid complex. Medial CE was the first amygdala structure infected (4 days post-inoculation) with trans-synaptic spread to the lateral CE and the caudomedial parvicellular basolateral nucleus by day 5 post-inoculation. Infected neurons were only very rarely found in the lateral capsular CE and the lateral nucleus and then at only the latest time points. The data demonstrate that the CE is directly connected with clusters of reticular premotor neurons that may represent complex pattern generators and/or switching elements for the generation of stereotypic oral and laryngo-pharyngeal movements during aversive oral stimulation. Serial connections through the amygdaloid complex linked with the oro-laryngo-pharyngeal musculature appear quite distinct from those believed to sub-serve fear responses, suggesting there are distinct "channels" for the acquisition and expression of particular conditioned behaviors.

Brainstem substrates of sympatho-motor circuitry identified using trans-synaptic tracing with pseudorabies virus recombinants.

Previous physiological investigations have suggested the existence of a neural circuit that coordinates activation of motor and autonomic efferents before or at the onset of exercise. Traditionally these circuits have been postulated to involve forebrain areas. However, overlapping populations of medullary reticular formation neurons that participate in motor or autonomic control have been described previously, suggesting that individual pontomedullary reticular formation neurons may coordinate both motor and autonomic responses. We tested this hypothesis by conducting transneuronal retrograde tracing of motor and sympathetic nervous system pathways in rats using recombinant strains of pseudorabies virus (PRV). A PRV strain expressing the green fluorescent protein (PRV-152) was injected into the left gastrocnemius muscle, which was surgically sympathectomized, whereas another recombinant (PRV-BaBlu) was injected into the left adrenal gland. Immunofluorescence methods using monospecific antisera and distinct fluorophores identified neurons infected with one or both of the recombinants. Brainstem neurons coinfected with both PRV recombinants, which presumably had collateralized projections to both adrenal sympathetic preganglionic neurons and gastrocnemius motoneurons, were observed in several areas of the pontomedullary reticular formation. The largest number of such neurons was located in the rostral ventromedial medulla within the ventral gigantocellular nucleus, gigantocellular nucleus pars alpha, raphe obscurus, and raphe magnus. These neurons are candidates for relaying central command signals to the spinal cord.

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.

Transneuronal tracing of neural pathways controlling abdominal musculature in the ferret.

Abdominal musculature participates in generating a large number of behaviors and protective reflexes, although each abdominal muscle is frequently activated differentially during particular motor responses. For example, rectus abdominis has been reported to play less of a role in respiration than other abdominal muscles, such as transversus abdominis. In the present study, the inputs to transversus abdominis and rectus abdominis motoneurons were determined and compared using the transneuronal transport of two recombinant isogenic strains of pseudorabies virus. After a 5-day post-inoculation period, infected presumed motoneurons were observed principally in cord levels T10-T15 ipsilateral to the injections. The injection of a monosynaptic tracer, beta-cholera toxin, into transversus abdominis confirmed the distribution of motoneurons innervating this muscle. In the brainstem, neurons transneuronally infected following injection of pseudorabies virus into rectus abdominis or transversus abdominis were located in the same regions, which included the medial medullary reticular formation, the medullary raphe nuclei, and nucleus retroambiguus (the expiration region of the caudal ventral respiratory group). Double-labeled cells providing inputs to both rectus and transversus motoneurons were present in both the medial medullary reticular formation and nucleus retroambiguus. These data show that the medial medullary reticular formation contains neurons influencing the activity of multiple abdominal muscles, and support our hypothesis that this region globally affects the excitability of motoneurons involved in respiration.

Activity of cardiorespiratory networks revealed by transsynaptic virus expressing GFP.

A fluorescent transneuronal marker capable of labeling individual neurons in a central network while maintaining their normal physiology would permit functional studies of neurons within entire networks responsible for complex behaviors such as cardiorespiratory reflexes. The Bartha strain of pseudorabies virus (PRV), an attenuated swine alpha herpesvirus, can be used as a transsynaptic marker of neural circuits. Bartha PRV invades neuronal networks in the CNS through peripherally projecting axons, replicates in these parent neurons, and then travels transsynaptically to continue labeling the second- and higher-order neurons in a time-dependent manner. A Bartha PRV mutant that expresses green fluorescent protein (GFP) was used to visualize and record from neurons that determine the vagal motor outflow to the heart. Here we show that Bartha PRV-GFP-labeled neurons retain their normal electrophysiological properties and that the labeled baroreflex pathways that control heart rate are unaltered by the virus. This novel transynaptic virus permits in vitro studies of identified neurons within functionally defined neuronal systems including networks that mediate cardiovascular and respiratory function and interactions. We also demonstrate superior laryngeal motorneurons fire spontaneously and synapse on cardiac vagal neurons in the nucleus ambiguus. This cardiorespiratory pathway provides a neural basis of respiratory sinus arrhythmias.

Definition of neuronal circuitry controlling the activity of phrenic and abdominal motoneurons in the ferret using recombinant strains of pseudorabies virus.

During a number of behaviors, including vomiting and some postural adjustments, activity of both the diaphragm and abdominal muscles increases. Previous transneuronal tracing studies using injection of pseudorabies virus (PRV) into either the diaphragm or rectus abdominis (RA) of the ferret demonstrated that motoneurons innervating these muscles receive inputs from neurons in circumscribed regions of the spinal cord and brainstem, some of which have an overlapping distribution in the magnocellular part of the medullary reticular formation (MRF). This observation raises two possibilities: that two populations of MRF neurons provide independent inputs to inspiratory and expiratory motoneurons or that single MRF neurons have collateralized projections to both groups of motoneurons. The present study sought to distinguish between these prospects. For this purpose, recombinant isogenic strains of PRV were injected into these respiratory muscles in nine ferrets; the strain injected into the diaphragm expressed beta-galactosidase, whereas that injected into RA expressed green fluorescent protein. Immunofluorescence localization of the unique reporters of each virus revealed three populations of infected premotor neurons, two of which expressed only one virus and a third group that contained both viruses. Dual-infected neurons were predominantly located in the magnocellular part of the MRF, but were absent from both the dorsal and ventral respiratory cell groups. These data suggest that coactivation of inspiratory and expiratory muscles during behaviors such as emesis and some postural adjustments can be elicited through collateralized projections from a single group of brainstem neurons located in the MRF.

Efferent connections of the lamina terminalis, the preoptic area and the insular cortex to submandibular and sublingual gland of the rat traced with pseudorabies virus.

Neurones situated in the lamina terminalis (organum vasculosum of the lamina terminalis, median preoptic nucleus and subfornical organ) as well as within medial and lateral parts of the preoptic area and in the insular cortex become transneuronally labelled following pseudorabies virus injections into the submandibular or the sublingual gland. These neurones are efferently connected to a chain of central neurones directed to secretory or vascular tissue of the submandibular or the sublingual gland. By varying the postinoculation time a stepwise infection of different forebrain nuclei was registered, with the hypothalamic paraventricular nucleus and the lateral hypothalamic area being the first forebrain structures labelled. Such early infected neurones within these hypothalamic nuclei are in all likelihood third order neurones regulating salivary secretion and might have functioned as relays transmitting virus to other forebrain structures. The above mentioned forebrain areas together with several other hypothalamic nuclei as well as the bed nucleus of the stria terminalis, the central nucleus of the amygdala and the substantia innominata, seem to be the widespread anatomical basis for the central regulation of salivary gland function.

Central nervous system neurons identified after injection of pseudorabies virus into the rat clitoris.

Transneuronal tracing techniques were used to identify putative spinal and brain neurons involved in the efferent control of the clitoris. Pseudorabies virus was injected into the rat clitoris and virus-labeled neurons were identified immunohistochemically. Neurons were found primarily in L5-S1 segments of the spinal cord. In addition, virus-labeled cells were found in T12-L4 and S2-S4. In the brain, virus-labeled cells were found in the nucleus paragigantocellularis, raphe pallidus, raphe magnus, Barrington's nucleus, ventrolateral central gray, hypothalamus and medial pre-optic region. These data identify a multisynaptic circuit of neurons which may be involved in clitoral control.