The interferon stimulated gene viperin, restricts Shigella. flexneri in vitro.

The role of interferon and interferon stimulated genes (ISG) in limiting bacterial infection is controversial, and the role of individual ISGs in the control of the bacterial life-cycle is limited. Viperin, is a broad acting anti-viral ISGs, which restricts multiple viral pathogens with diverse mechanisms. Viperin is upregulated early in some bacterial infections, and using the intracellular bacterial pathogen, S. flexneri, we have shown for the first time that viperin inhibits the intracellular bacterial life cycle. S. flexneri replication in cultured cells induced a predominantly type I interferon response, with an early increase in viperin expression. Ectopic expression of viperin limited S. flexneri cellular numbers by as much as 80% at 5hrs post invasion, with similar results also obtained for the intracellular pathogen, Listeria monocytogenes. Analysis of viperins functional domains required for anti-bacterial activity revealed the importance of both viperin's N-terminal, and its radical SAM enzymatic function. Live imaging of S. flexneri revealed impeded entry into viperin expressing cells, which corresponded to a loss of cellular cholesterol. This data further defines viperin's multi-functional role, to include the ability to limit intracellular bacteria; and highlights the role of ISGs and the type I IFN response in the control of bacterial pathogens.

Dendritic morphology of cardiac related medullary neurons defined by circuit-specific infection by a recombinant pseudorabies virus expressing beta-galactosidase.

The transneuronal herpesvirus tracer, pseudorabies virus (PRV) was used to determine the dendritic architecture of cardiac-related neurons. We constructed a derivative of the Bartha strain of PRV called PRV-BaBlu, that carries the lacZ gene of E. coli. Expression of beta-galactosidase by this recombinant virus enabled us to define the dendritic morphology of motoneurons and interneurons that innervate the heart. beta-galactosidase antigen filled dendritic processes that were clearly revealed by antibodies to beta-galactosidase. In contrast, the standard enzymatic reaction for detection of beta-galactosidase activity stained the cell soma well, but was inferior for labeling dendrites. Following PRV-BaBlu cardiac injection, infected neurons were clearly defined and labeled dendrites could be traced for long distances, sometimes greater than 800 microns from the cell body. Labeled dendrites of cardiomotor neurons primarily located in the nucleus ambiguus (NA) were extensive and sometimes intertwined with dendrites from other labeled motoneurons. Dendrites of labeled neurons in the dorsal motor nucleus of the vagus (DMV) typically extended in the mediolateral direction in the transverse plane. Transynaptically labeled interneurons interposed between the cardiorespiratory region of the nucleus tractus solitarius (NTS) and the NA were primarily located in the NA region and the reticular arc, the area between the DMV and NA. These interneurons had long dendrites extending along the reticular arc in the transverse plane. The dendritic arborizations of infected cardiac-related neurons in the NTS were variable in extent. We conclude that antibody detection of beta-galactosidase expressed by PRV-BaBlu after infection of neural cardiac circuits provides a superior method to define the dendrites and dendritic fields of cardiac-related motoneurons and interneurons.

Central neuronal circuit innervating the rat heart defined by transneuronal transport of pseudorabies virus.

We defined the central circuit innervating various regions of the rat heart using a neurotropic herpesvirus as a transneuronal tracer. Location of viral antigens in the brain after cardiac injection of three strains of pseudorabies virus (PRV) provided insight into vagal preganglionic neurons and their connected interneurons. At short survival times, labeled vagal preganglionic neurons were localized in both the nucleus ambiguus (NA) and the dorsal motor nucleus of the vagus (DMV), and in an arc-like band through the reticular formation between the NA and the DMV. The amount of DMV labeling was dependent on viral strain. Similar distributions of labeled neurons were observed following either ganglionic, sinoatrial node, or ventricular injections. At intermediate survival times postcardiac injection, the virus replicated in vagal preganglionic neurons and was trans-synaptically transported to interneurons observed primarily in the NA regions and in an arc-like band through the reticular formation. Labeled neurons were also observed in ventral regions of the nucleus of the solitary tract (NTS). At longer survival times, labeled neurons were found in various regions of the NTS with the most abundant label dorsal and dorsomedial to the solitary tract. Abundant neuronal labeling was also found in the intermediolateral cell column, the raphe nuclei, the caudal and rostral ventral lateral medulla, the A5 region, the locus coeruleus, and the lateral and paraventricular hypothalamic nuclei. These data define the central circuits including the interneuronal connections that innervate various cardiac targets.

Innervation of the heart and its central medullary origin defined by viral tracing.

The vagus nerve exerts a profound influence on the heart, regulating the heart rate and rhythm. An extensive vagal innervation of the cardiac ventricles and the central origin and extent of this innervation was demonstrated by transynaptic transport of pseudorabies virus with a virulent and two attenuated pseudorabies viral strains. The neurons that innervate the ventricles are numerous, and their distribution within the nucleus ambiguus and dorsal motor nucleus of the vagus is similar to that of neurons innervating other cardiac targets, such as the sino-atrial node. These data provide a neuroanatomical correlate to the physiological influence of the vagus nerve on ventricular function.

Tonic descending modulation of spinal neuronal responses to activation of renal receptors.

Experiments were conducted in anesthetized cats to determine if spinal neuronal responses to activation of renal receptors are tonically modulated by descending spinal pathways. Eighty-seven thoracolumbar spinal neurons with renal and somatic input were tested for responses to occlusion of the renal vein, renal artery, and ureter before, during, and after cooling the spinal cord rostral to the recording site. Cooling increased the number of neurons that responded as well as the magnitude of the responses to renal vein (RVO), renal artery (RAO), and ureteral occlusion (UO). RVO increased cell activity of 21 neurons from 12.5 +/- 2.7 to 31.7 +/- 6.0 spikes/s during cooling. UO increased cell activity of 24 neurons from 9.0 +/- 2.1 before cooling to 25.0 +/- 4.9 spikes/s during cooling. Cold block increased the magnitude of both types of responses to RAO that were due to mechanical deformation of the renal artery and prolonged renal ischemia. These data show that the majority of spinal neuronal responses to renal receptor stimulation are modulated by tonic inhibitory influences. Thus these results provide a mechanism by which the brain may control spinal circuitry that underlies reflexes of renal origin.

Effects of renal receptor stimulation on neurons within the ventrolateral medulla of the cat.

Experiments were performed to determine if activation of renal receptors by occlusion of the renal artery, renal vein, or ureter would alter activity of cells within the ventrolateral medulla of the cat. Extracellular unit recordings were obtained from 195 cells located within the rostral ventrolateral medulla of 90 alpha-chloralose-anesthetized cats. Fifty-five of 195 cells (28.2%) tested for responses to renal receptor activation responded to at least one of the occlusions. Occlusion of the ureter increased the activity of 25 cells from 9.7 +/- 3.7 to 23.0 +/- 6.5 impulses/s and decreased the activity of 5 cells from 11.9 +/- 3.6 to 3.5 +/- 1.2 impulses/s. Occlusion of the renal vein increased the activity of seven cells from 7.5 +/- 3.3 to 22.3 +/- 7.3 impulses/s and decreased the activity of six cells from 13.8 +/- 3.8 to 4.1 +/- 2.0 impulses/s. Renal artery occlusion elicited solely excitatory responses from 43 cells. Thirty-one of the 43 cells increased their activity within 0-3 s of the onset of renal artery occlusion from 4.1 +/- 0.8 to 12.6 +/- 1.2 impulses/s. Renal artery occlusion increased the activity of 10 out of 43 cells with a mean latency of 26.1 +/- 6.5 s from 8.3 +/- 2.5 to 29.6 +/- 9.3 impulses/s. Twenty-four of the 55 (43.6%) responders were responsive to two or more forms of renal receptor activation. These results demonstrate that activation of renal mechanoreceptors and chemoreceptors affects cells within the ventrolateral medulla of the cat.(ABSTRACT TRUNCATED AT 250 WORDS)

Renal afferent input to the ventrolateral medulla of the cat.

Experiments were performed to determine if information from the kidneys projects to the rostral ventrolateral medulla. Extracellular action potentials were recorded from 148 cells within the rostral ventrolateral medulla of alpha-chloralose-anesthetized cats. Cells within the rostral ventrolateral medulla were tested for responses to electrical stimulation of both left and right renal nerves. Electrical stimulation of renal nerves excited 144 cells (97.3%) and inhibited 4. The majority of cells received either bilateral or contralateral renal nerve input. Cells with bilateral renal nerve input responded to contralateral renal nerve stimulation with a significantly greater number of impulses compared with ipsilateral renal nerve stimulation (P less than 0.05). All cells but one responding to renal nerve stimulation had convergent somatic input. Comparisons between thresholds for cell responses and activation thresholds for the A and C volleys of the compound action potential recorded in the least splanchnic nerve revealed that 44 cells required activation of A delta-fibers, and 12 cells required activation of both A delta- and C-fibers. A conditioning stimulus applied to renal nerves on one side significantly decreased the response elicited by a test stimulus applied to the renal nerves on the opposite side for at least 300 ms (P less than 0.05). The demonstration that an afferent connection exists between the kidneys and the ventrolateral medulla suggests that the rostral ventrolateral medulla may play a role in mediating supraspinal reflexes of renal origin.

Tonic descending modulation of spinal neurons with renal input.

Experiments were conducted to determine the influence of tonically active descending pathways on thoracolumbar spinal neurons that respond to renal nerve stimulation in anesthetized cats. We examined the effect of reversible blockade of spinal conduction on spontaneous activity, responses to renal nerve stimulation and responses to somatic stimuli of 71 spinal neurons. Mid-thoracic cold block resulted in enhanced responses (tonically inhibited neurons), reduced responses (tonically excited neurons), or did not affect neuronal responses. The spontaneous activity of 47 of 69 neurons (68%) increased from 7.3 +/- 2.0 spikes/s before cooling to 23.3 +/- 4.5 spikes/s during cooling. Activity of 8 neurons (12%) decreased while 14 (20%) had no change in activity. Cooling increased the responses of 51 of 71 neurons (72%) to renal nerve stimulation. Renal nerve stimulation evoked a two-fold increase in both short latency (early) and long latency (late) responses. Four neurons had a late response which was revealed by cold block. Cooling decreased responses of 8 of 71 neurons (11%) and 9 neurons (13%) were not affected. Cooling increased the early responses but decreased the late responses of 3 of 71 neurons (4%). All neurons had somatic receptive fields and 33 of 56 exhibited increased responses to somatic stimulation during cooling. In addition, receptive field sizes of 26 neurons increased. Four neurons had a decrease and 25 neurons had no change in receptive field size during cooling. These data indicate that tonically active descending pathways modulate the activity of most spinal neurons with renal input and the major effect of these pathways is inhibitory. This influence may be important in the modulation of spinal circuits that participate in reflexes evoked by renal afferent fibers.