Your search keyword '"R. R. Miselis"' showing total 8 results

1. A tasteless lesion

Author

Alan C. Rosenquist, J. A. Feldman, R. R. Miselis, SL Galetta, and Beau M. Ances

Subjects

Dorsum, Male, Taste, Afferent Pathways, business.industry, Anatomy, Middle Aged, Magnetic Resonance Imaging, Pons, Lesion, medicine.anatomical_structure, Thalamus, Tongue, Brain mri, Enhancing Lesion, Solitary Nucleus, Medicine, Humans, Neurology (clinical), medicine.symptom, business, Ageusia

Abstract

A 45-year-old restaurant owner noted loss of taste over his entire left tongue during a two-week time period. Neurologic exam was otherwise normal including facial strength. Brain MRI revealed an enhancing lesion of the left dorsal pons (figure, A and B). The patient subsequently developed …

Published

2006

2. Transneuronal labeling from the rat distal colon: anatomic evidence for regulation of distal colon function by a pontine corticotropin-releasing factor system

Author

R J, Valentino, M, Kosboth, M, Colflesh, and R R, Miselis

Subjects

Male, Neurons, Rats, Sprague-Dawley, Spinal Cord, Colon, Corticotropin-Releasing Hormone, Immune Sera, Pons, Animals, Brain, Herpesvirus 1, Suid, Immunohistochemistry, Rats

Abstract

Neural circuits that are positioned to regulate rat distal colon function were identified by immunohistochemical detection of pseudorabies virus (PRV) and corticotropin-releasing factor (CRF). The distribution of PRV-immunoreactive neurons was examined in spinal cord and brain at increasing times (72-118 hours) after distal colon injection. At 72-80 hours, PRV-labeling was confined to the spinal cord, in the parasympathetic preganglionic column in the lumbosacral spinal cord and in the intermediolateral column of the thoracic spinal cord. At longer survival times (88 hours), PRV-immunolabeled neurons in the lumbosacral spinal cord were also distributed in superficial layers of the dorsal horn, the dorsal commissure, and around the central canal. Trans-synaptic labeling was identified in the medullary raphe nuclei, parapyramidal region, A5, Barrington's nucleus, A7, and the dorsal cap of the paraventricular nucleus of the hypothalamus after longer survival times (88-91 hours). Substantial labeling of the locus coeruleus, periaqueductal gray and forebrain regions occurred at later survival times (or = 96 hours). In dual-labeled sections, CRF terminal labeling surrounded PRV-labeled neurons in the parasympathetic preganglionic column of the lumbosacral spinal cord. Additionally, many neurons in Barrington's nucleus, but not other CRF-containing nuclei, were double labeled for CRF and PRV. These results, taken with previous studies, support a convergence in transneuronal labeling from different pelvic viscera that may be related to coordination of overall pelvic visceral functions. Importantly, they provide an anatomic substrate for an impact of CRF from Barrington's nucleus in normal and pathophysiological functions of the distal colon.

Published

2000

3. Distribution of bombesin-like immunoreactivity in the nucleus of the solitary tract and dorsal motor nucleus of the rat and human: colocalization with tyrosine hydroxylase

Author

R B, Lynn, T M, Hyde, R R, Cooperman, and R R, Miselis

Subjects

Adult, Brain Chemistry, Male, Stilbamidines, Tyrosine 3-Monooxygenase, Brain, Cell Count, Vagus Nerve, Middle Aged, Immunohistochemistry, Rats, Rats, Sprague-Dawley, Fluorescent Antibody Technique, Direct, Solitary Nucleus, Animals, Humans, Bombesin, Fluorescent Dyes

Abstract

Bombesin is a peptide neurotransmitter/neuromodulator with important autonomic and behavioral effects that are mediated, at least in part, by bombesin-containing neurons and nerve terminals in the nucleus of the solitary tract (NTS) and the dorsal motor nucleus of the vagus (DMV). The distribution of bombesin-like immunoreactive nerve terminals/fibers and cell bodies in relation to a viscerotopically relevant subnuclear map of this region was studied by using an immunoperoxidase technique. In the rat, bombesin fiber/terminal staining was heavy in an area that included the medial subnucleus of the NTS and the DMV over their full rostral-caudal extent. Distinctly void of staining were the gelatinous, central, and rostral commissural subnuclei and the periventricular area of the NTS, regions to which gastric, esophageal, cecal, and colonic primary afferents preferentially project. The caudal commissural and dorsal subnuclei had light bombesin fiber/terminal staining, as did the intermediate, interstitial, ventral, and ventrolateral subnuclei. With colchicine pretreatment, numerous cell bodies were stained in the medial and dorsal subnuclei, with fewer neurons in the caudal commissural, intermediate, interstitial, ventral, and ventrolateral subnuclei. Bombesin-like immunoreactive neurons were found in numerous other areas of the brain, including the ventrolateral medulla, the parabrachial nucleus, and the medial geniculate body. In the human NTS/DMV complex, the distribution of bombesin fiber/terminal staining was very similar to the rat. In addition, occasional bombesin-like immunoreactive neurons were labeled in a number of subnuclei, with clusters of neurons labeled in the dorsal and ventrolateral subnuclei. Double immunofluorescence studies in rat demonstrated that bombesin colocalizes with tyrosine hydroxylase in neurons in the dorsal subnucleus of the NTS. Bombesin does not colocalize with tyrosine hydroxylase in any other location in the brain. In conclusion, the distribution of bombesin in the NTS adheres to a viscerotopically relevant map. This is the anatomical substrate for the effects of bombesin on gastrointestinal function and satiety and its likely role in concluding a meal. The anatomic similarities between human and rat suggest that bombesin has similar functions in the visceral neuraxis of these two species. Bombesin coexists with catecholamines in neurons in the dorsal subnucleus, which likely mediate, in part, the cardiovascular effects of bombesin.

Published

1996

4. Neurotropic properties of pseudorabies virus: uptake and transneuronal passage in the rat central nervous system

Author

R. R. Miselis, J. P. Card, Linda Rinaman, M. E. Whealy, Lynn W. Enquist, James S. Schwaber, and A. K. Robbins

Subjects

Nervous system, Central Nervous System, Male, Pathology, medicine.medical_specialty, Time Factors, viruses, Pseudorabies, Virus Replication, Injections, Esophagus, Tongue, Neural Pathways, medicine, Tegmentum, Animals, Nucleus ambiguus, Neurotropic virus, Neurons, biology, General Neuroscience, Stomach, Rats, Inbred Strains, Articles, biology.organism_classification, Herpesvirus 1, Suid, Rats, Monoaminergic cell groups, medicine.anatomical_structure, Axoplasmic transport, Neuron, Brain Stem

Abstract

Uptake, replication, and transneuronal passage of a swine neurotropic herpesvirus (pseudorabies virus, PRV) was evaluated in the rat CNS. PRV was localized in neural circuits innervating the tongue, stomach, esophagus and eye with light microscopic immunohistochemistry. In each instance, the distribution of PRV-immunoreactive neurons was entirely consistent with that observed following injection of cholera toxin- horseradish peroxidase conjugate (CT-HRP). Injections of the tongue resulted in retrograde transport of PRV and CT-HRP to hypoglossal motor neurons, while preganglionic neurons in the dorsal motor vagal nucleus or somatic motor neurons in the nucleus ambiguus were labeled following injections of the stomach or esophagus, respectively. At longer times after infection, viral antigens were found in astrocytes adjacent to infected neurons and their efferent axons and second-order neuron labeling became apparent. The distribution of second-order neurons was also entirely dependent upon the site of PRV injection. Following tongue injection, second-order neurons were observed in the trigeminal complex, the brain-stem tegmentum and in monoaminergic cell groups. Injection of the stomach or esophagus led to second-order neuron labeling confined to distinct subdivisions of the neucleus of the solitary tract and monoaminergic cell groups. Comparative quantitative analysis of the number of PRV immunoreactive neurons present in the diencephalon and brain stem following injection of virus into both the eye and stomach musculature of the same animal demonstrated that retrograde transport of PRV from the viscera was more efficient and occurred at a much faster rate than anterograde transport of virus. These data demonstrate projection-specific transport of PRV in the nervous system and provide further insight into the means through which this neurotropic virus infects the nervous system.

Published

1990

5. Effects of area postrema/caudal medial nucleus of solitary tract lesions on food intake and body weight

Author

T. M. Hyde and R. R. Miselis

Subjects

Male, medicine.medical_specialty, Physiology, media_common.quotation_subject, Appetite, Drinking Behavior, Stimulation, Biology, Lesion, Sex Factors, Physiology (medical), Internal medicine, Hypophagia, medicine, Animals, Medulla, media_common, Medulla Oblongata, Body Weight, Area postrema, Solitary tract, Rats, Inbred Strains, Feeding Behavior, Animal Feed, Diet, Rats, Endocrinology, Medulla oblongata, Female, medicine.symptom

Abstract

Lesions of the area postrema/caudal medial nucleus of the solitary tract (AP/cmNTS), located on the surface of the dorsal medulla of the rat, cause a transient syndrome of hypophagia and body weight loss, with the establishment of a new growth curve at a lower body weight set point. The regulatory responses to prolonged food deprivation, glucoprivic stimulation, and chronic access to a palatable diet are left largely intact. However, there is an overconsumption of highly palatable foods during acute exposure to supermarket and high-fat diets. Intestinal transit and gastric retention are unaffected by the lesion, indicating normal motor function within the gastrointestinal system. The hypophagia and chronic depression of body weight by the AP/cmNTS lesion demonstrate that this area is an important part of the larger neurocircuitry subserving feeding behavior and energy balance.

Published

1983

6. Area postrema and adjacent nucleus of the solitary tract in water and sodium balance

Author

R. R. Miselis and T. M. Hyde

Subjects

Male, medicine.medical_specialty, Physiology, Sodium, Drinking, chemistry.chemical_element, Natriuresis, Cerebral Ventricles, Lesion, Kidney Concentrating Ability, Eating, Polyuria, Physiology (medical), Internal medicine, medicine, Animals, Medulla Oblongata, Water Deprivation, Area postrema, Body Weight, Osmolar Concentration, Solitary tract, Rats, Inbred Strains, Water-Electrolyte Balance, Rats, Endocrinology, chemistry, Medulla oblongata, medicine.symptom, Polydipsia

Abstract

Lesions of the area postrema (AP) and adjacent caudal medial nucleus of the solitary tract (cmNTS) cause significant changes in water and sodium balance. Lesioned rats display a permanent polydipsia, which in part is due to a primary polyuria. Water-to-food ratios are elevated chronically. Lesioned rats are unable to concentrate their urine as well as controls. In addition, lesioned rats overdrink in response to 24-h water deprivation. This lesion also causes a natriuresis and an overconsumption of 3% NaCl solution. These findings establish the AP-cmNTS as an important part of the neurocircuitry underlying water and sodium balance.

Published

1984

7. Lack of ingestive compensation to osmotic stimuli in chronic decerebrate rats

Author

R. R. Miselis and H. J. Grill

Subjects

Male, medicine.medical_specialty, Food deprivation, Sucrose, Physiology, Drinking, Hypothalamus, Hippocampus, chemistry.chemical_compound, Eating, Thalamus, Physiology (medical), Internal medicine, Isotonic, medicine, Ingestion, Animals, Dehydration, Meal, Water Deprivation, Water-Electrolyte Balance, medicine.disease, Rats, Osmotic stimulus, Endocrinology, chemistry, Anesthesia, Tonicity, Brain Stem

Abstract

Chronic decerebrate rats fitted with oral fistulas for remote injection of water or nutrient were tested for their capacity to behaviorally compensate for dehydration by increasing their ingestion of water. Decerebrates and their controls were given water for ingestion via the oral fistula in 50-microliter aliquots following various challenges. The rats' ejection of water from the mouth marked behavioral termination of the drinking. The volume of water was measured 1 and 24 h after an intragastric meal of regular diet; 0.5, 4, 8, and 24 h following subcutaneous isotonic or hypertonic NaCl injection; and 1, 4, 8, and 24 h following an intragastric meal of regular or 3% NaCl adulterated diet. Unlike controls, decerebrates failed to increase the amount of water ingested following intracellular dehydration regardless of the means of producing dehydration or the duration of time permitted for a response. However, both control and decerebrate rats increased their ingestion of a sweet solution (0.03 M sucrose) demonstrating their capacity to respond and confirming their ability to compensate for food deprivation. This lack of increased water intake in response to dehydration for decerebrate rats favors the existence of at least some aspects of the regulatory circuitry for this behavioral control of water balance to lie in the forebrain.

Published

1981

8. Pseudorabies virus infection of the rat central nervous system: ultrastructural characterization of viral replication, transport, and pathogenesis

Author

RB Lynn, BH Lee, R. R. Miselis, Linda Rinaman, Lynn W. Enquist, J. P. Card, and R P Meade

Subjects

Male, Cytoplasm, viruses, Pseudorabies, Golgi Apparatus, Virus Replication, Virus, Rats, Sprague-Dawley, Capsid, Viral envelope, Viral entry, Cell Movement, Animals, Viral shedding, Neurons, Cell fusion, biology, General Neuroscience, Virion, Articles, biology.organism_classification, Virology, Herpesvirus 1, Suid, Rats, Microscopy, Electron, Dorsal motor nucleus, Viral replication, nervous system, Lysosomes

Abstract

Pseudorabies virus (PRV) has been used extensively to map synaptic circuits in the CNS and PNS. A fundamental assumption of these studies is that the virus replicates within synaptically linked populations of neurons and does not spread through the extracellular space or by cell- to-cell fusion. In the present analysis we have used electron microscopy to characterize pathways of viral replication and egress that lead to transneuronal infection of neurons, and to document the non-neuronal response to neuronal infection. Three strains of PRV that differ in virulence were used to infect preganglionic motor neurons in the dorsal motor nucleus of the vagus (DMV). The data demonstrate that viral replication and transneuronal passage occur in a stepwise fashion that utilizes existing cellular processes, and that the non-neuronal response to infection serves to restrict nonspecific spread of virus by isolating severely infected neurons. Specifically, capsids containing viral DNA replicate in the cell nucleus, traverse the endoplasmic reticulum to gain access to the cytoplasm, and acquire a bilaminar membrane envelope from the trans cisternae of the Golgi. The outer leaf of this envelope fuses with the neuron membrane to release virus adjacent to axon terminals that synapse upon the infected cell. A second fusion event involving the viral envelope and the afferent terminal releases the naked capsid into the bouton. Systematic analysis of serial sections demonstrated that release of virus from infected neurons occurs preferentially at sites of afferent contact. Nonspecific diffusion of virus from even the most severely infected cells is restricted by astrocytes and other non-neuronal elements that are mobilized to the site of viral infectivity. The ability of glia and macrophages to restrict spread of virus from necrotic neurons is the product of (1) temporal differences in the mobilization of these cells to the site of infection, (2) differential susceptibility of these cells to PRV infection, and (3) abortive viral replication in cells that are permissive for infection. The findings provide further insight into the intracellular routes of viral assembly and egress and support the contention that transneuronal spread of virus in the brain results from specific passage of virions through synaptically linked neurons rather than through cell fusion or release of virus into the extracellular space.