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1. The sleep-wake cycle regulates brain interstitial fluid tau in mice and CSF tau in humans

Author

Holth, Jerrah K, Fritschi, Sarah K, Wang, Chanung, Pedersen, Nigel P, Cirrito, John R, Mahan, Thomas E, Finn, Mary Beth, Manis, Melissa, Geerling, Joel C, Fuller, Patrick M, Lucey, Brendan P, and Holtzman, David M

Subjects
Biochemistry and Cell Biology, Biological Sciences, Behavioral and Social Science, Acquired Cognitive Impairment, Neurodegenerative, Aging, Basic Behavioral and Social Science, Neurosciences, Brain Disorders, Alzheimer's Disease, Sleep Research, Dementia, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Neurological, Amyloid beta-Peptides, Animals, Brain, Circadian Rhythm, Extracellular Fluid, Female, Male, Mice, Mice, Transgenic, Sleep, Sleep Deprivation, Wakefulness, tau Proteins, General Science & Technology
Abstract

The sleep-wake cycle regulates interstitial fluid (ISF) and cerebrospinal fluid (CSF) levels of β-amyloid (Aβ) that accumulates in Alzheimer's disease (AD). Furthermore, chronic sleep deprivation (SD) increases Aβ plaques. However, tau, not Aβ, accumulation appears to drive AD neurodegeneration. We tested whether ISF/CSF tau and tau seeding and spreading were influenced by the sleep-wake cycle and SD. Mouse ISF tau was increased ~90% during normal wakefulness versus sleep and ~100% during SD. Human CSF tau also increased more than 50% during SD. In a tau seeding-and-spreading model, chronic SD increased tau pathology spreading. Chemogenetically driven wakefulness in mice also significantly increased both ISF Aβ and tau. Thus, the sleep-wake cycle regulates ISF tau, and SD increases ISF and CSF tau as well as tau pathology spreading.

Published
2019

5. Alpha-Synuclein Pre-Formed Fibrils Injected into Prefrontal Cortex Primarily Spread to Cortical and Subcortical Structures

Author

Weber, Matthew A., primary, Kerr, Gemma, additional, Thangavel, Ramasamy, additional, Conlon, Mackenzie M., additional, Gumusoglu, Serena B., additional, Gupta, Kalpana, additional, Abdelmotilib, Hisham A., additional, Halhouli, Oday, additional, Zhang, Qiang, additional, Geerling, Joel C., additional, Narayanan, Nandakumar S., additional, and Aldridge, Georgina M., additional

Published
2023
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8. Alpha-Synuclein Pre-Formed Fibrils Injected into Prefrontal Cortex Primarily Spread to Cortical and Subcortical Structures.

Author

Weber, Matthew A., Kerr, Gemma, Thangavel, Ramasamy, Conlon, Mackenzie M., Gumusoglu, Serena B., Gupta, Kalpana, Abdelmotilib, Hisham A., Halhouli, Oday, Zhang, Qiang, Geerling, Joel C., Narayanan, Nandakumar S., and Aldridge, Georgina M.

Subjects
PREFRONTAL cortex, LEWY body dementia, ALPHA-synuclein, PARKINSON'S disease, EXECUTIVE function
Abstract

Background: Parkinson's disease dementia (PDD) and dementia with Lewy bodies (DLB) are characterized by diffuse spread of alpha-synuclein (α-syn) throughout the brain. Patients with PDD and DLB have a neuropsychological pattern of deficits that include executive dysfunction, such as abnormalities in planning, timing, working memory, and behavioral flexibility. The prefrontal cortex (PFC) plays a major role in normal executive function and often develops α-syn aggregates in DLB and PDD. Objective: To investigate the long-term behavioral and cognitive consequences of α-syn pathology in the cortex and characterize pathological spread of α-syn. Methods: We injected human α-syn pre-formed fibrils into the PFC of wild-type male mice. We then assessed the behavioral and cognitive effects between 12- and 21-months post-injection and characterized the spread of pathological α-syn in cortical, subcortical, and brainstem regions. Results: We report that PFC PFFs: 1) induced α-syn aggregation in multiple cortical and subcortical regions with sparse aggregation in midbrain and brainstem nuclei; 2) did not affect interval timing or spatial learning acquisition but did mildly alter behavioral flexibility as measured by intraday reversal learning; and 3) increased open field exploration. Conclusions: This model of cortical-dominant pathology aids in our understanding of how local α-syn aggregation might impact some symptoms in PDD and DLB. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Alpha-synuclein pre-formed fibrils injected into prefrontal cortex primarily impact cortical and subcortical structures and lead to restricted behavioral impacts

Author

Weber, Matthew A., de Choisy, Gemma, Thangavel, Ramasamy, Conlon, Mackenzie M., Abdelmotilib, Hisham A., Halhouli, Oday, Zhang, Qiang, Geerling, Joel C., Narayanan, Nandakumar S., and Aldridge, Georgina M.

Subjects
Article
Abstract

Parkinson ‘s disease dementia (PDD) and Lewy Body dementia (LBD) are characterized by diffuse spread of alpha-synuclein (α-syn) throughout the brain. These patients have a neuropsychological pattern of deficits that include executive dysfunction, including abnormalities in planning, timing, working memory, and behavioral flexibility. The prefrontal cortex (PFC) plays a major role in normal executive function and often develops α-syn aggregates in LBD and PDD. To investigate the consequences of α-syn pathology in the cortex, we injected human α-syn pre-formed fibrils into the PFC of wildtype mice. We report that PFC PFFs: 1) induced α-syn deposition in multiple cortical and subcortical regions with sparse aggregation in midbrain and brainstem nuclei; 2) did not affect interval timing or working memory but did mildly alter behavioral flexibility as measured by reversal learning; 3) increased open field exploration; and 4) did not affect susceptibility to model of cortical-dominant pathology adds to our understanding of the etiology of varied symptoms in PDD and LBD.

Published
2023

19. Thalamic strokes that severely impair arousal extend into the brainstem

Author

Hindman, Joseph, Bowren, Mark D., Bruss, Joel, Wright, Brad, Geerling, Joel C., and Boes, Aaron D.

Subjects
Male, Brain Mapping, Time Factors, Magnetic Resonance Imaging, Article, Stroke, Imaging, Three-Dimensional, nervous system, Thalamus, Humans, Female, Coma, Stupor, Arousal, Brain Stem, Retrospective Studies
Abstract

In this study, we evaluate the role of the thalamus in the neural circuitry of arousal. Level of consciousness within the first 12 hours of a thalamic stroke is assessed with lesion symptom mapping. Impaired arousal correlates with lesions in the paramedian posterior thalamus near the centromedian and parafascicular nuclei, posterior hypothalamus, and midbrain tegmentum. All patients with severely impaired arousal (coma, stupor) had lesion extension into the midbrain and/or pontine tegmentum, whereas purely thalamic lesions did not severely impair arousal. These results are consistent with growing evidence that pathways most critical for human arousal lie outside the thalamus. Ann Neurol 2018;84:926-930.

Published
2018

20. Kölliker–Fuse GABAergic and glutamatergic neurons project to distinct targets

Author

Geerling, Joel C., Yokota, Shigefumi, Rukhadze, Irma, Roe, Dan, and Chamberlin, Nancy L.

Subjects
Male, Neurons, Fluorescent Antibody Technique, Glutamic Acid, Mice, Transgenic, Immunohistochemistry, Article, Rats, Mice, nervous system, Neural Pathways, Image Processing, Computer-Assisted, Animals, Kolliker-Fuse Nucleus, Female, GABAergic Neurons, Rats, Wistar, In Situ Hybridization
Abstract

The Kölliker-Fuse nucleus (KF) is known primarily for its respiratory function as the “pneumotaxic center” or “pontine respiratory group.” Considered part of the parabrachial (PB) complex, KF contains glutamatergic neurons that project to respiratory-related targets in the medulla and spinal cord (Yokota, Oka, Tsumori, Nakamura, & Yasui, 2007). Here we describe an unexpected population of neurons in the caudal KF and adjacent lateral crescent subnucleus (PBlc), which are γ-aminobutyric acid (GABA)ergic and have an entirely different pattern of projections than glutamatergic KF neurons. First, immunofluorescence, in situ hybridization, and Cre-reporter labeling revealed that many of these GABAergic neurons express FoxP2 in both rats and mice. Next, using Cre-dependent axonal tracing in Vgat-IRES-Cre and Vglut2-IRES-Cre mice, we identified different projection patterns from GABAergic and glutamatergic neurons in this region. GABAergic neurons in KF and PBlc project heavily and almost exclusively to trigeminal sensory nuclei, with minimal projections to cardiorespiratory nuclei in the brainstem, and none to the spinal cord. In contrast, glutamatergic KF neurons project heavily to the autonomic, respiratory, and motor regions of the medulla and spinal cord previously identified as efferent targets mediating KF cardiorespiratory effects. These findings identify a novel, GABAergic subpopulation of KF/PB neurons with a distinct efferent projection pattern targeting the brainstem trigeminal sensory system. Rather than regulating breathing, we propose that these neurons influence vibrissal sensorimotor function.

Published
2017

22. Reciprocal Control of Drinking Behavior by Median Preoptic Neurons in Mice.

Author

Abbott, Stephen B. G., Machado, Natalia L. S., Geerling, Joel C., and Saper, Clifford B.

Subjects
DRINKING behavior, PREOPTIC area, ORGANON vasculosum laminae terminalis, OPTOGENETICS, GABA transporters, DEHYDRATION
Abstract

Stimulation of glutamatergic neurons in the subfornical organ drives drinking behavior, but the brain targets that mediate this response are not known. The densest target of subfornical axons is the anterior tip of the third ventricle, containing the median preoptic nucleus (MnPO) and organum vasculosum of the lamina terminalis (OVLT), a region that has also been implicated in fluid and electrolyte management. The neurochemical composition of this region is complex, containing both GABAergic and glutamatergic neurons, but the possible roles of these neurons in drinking responses have not been addressed. In mice, we show that optogenetic stimulation of glutamatergic neurons in MnPO/OVLT drives voracious water consumption, and that optogenetic stimulation of GABAergic neurons in the same region selectively reduces water consumption. Both populations of neurons have extensive projections to overlapping regions of the thalamus, hypothalamus, and hindbrain that are much more extensive than those from the subfornical organ, suggesting that the MnPO/OVLT serves as a key link in regulating drinking responses. [ABSTRACT FROM AUTHOR]

Published
2016
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27. Aldosterone in the brain.

Author

Geerling, Joel C. and Loewy, Arthur D.

Subjects
*ALDOSTERONE, *CENTRAL nervous system, *BRAIN physiology, *GLUCOCORTICOIDS, *NEURONS, *DEHYDROGENASES
Abstract

Pharmacological and physiological phenomena suggest that cells somewhere inside the central nervous system are responsive to aldosterone. Here, we present the fundamental physiological limitations for aldosterone action in the brain, including its limited blood-brain barrier penetration and its substantial competition from glucocorticoids. Recently, a small group of neurons with unusual sensitivity to circulating aldosterone were identified in the nucleus of the solitary tract. We review the discovery and characterization of these neurons, which express the enzyme 1β-hydroxysteroid dehydrogenase type 2, and consider alternative proposals regarding sites and mechanisms for mineralocorticoid action within the brain. [ABSTRACT FROM AUTHOR]

Published
2009
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28. Aldosterone Target Neurons in the Nucleus Tractus Solitarius Drive Sodium Appetite.

Author

Geerling, Joel C., Engeland, William C., Kawata, Mitsuhiro, and Loewy, Arthur D.

Subjects
*ALDOSTERONE, *BRAIN, *SODIUM, *NEURONS, *CENTRAL nervous system
Abstract

Sodium appetite can be enhanced by the adrenal steroid aldosterone via an unknown brain mechanism. A novel group of neurons in the nucleus tractus solitarius expresses the enzyme 11-β-hydroxysteroid dehydrogenase type 2, which makes them selectively responsive to aldosterone. Their activation parallels sodium appetite in different paradigms of salt loss even in the absence of aldosterone. These unique aldosterone target neurons may represent a previously unrecognized central convergence point at which hormonal and neural signals can be integrated to drive sodium appetite. [ABSTRACT FROM AUTHOR]

Published
2006
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30. Aldosterone-induced salt appetite requires HSD2 neurons.

Author

Gasparini S, Peltekian L, McDonough MC, Mitchell CJ, Hefti M, Resch JM, and Geerling JC

Subjects
Animals, Mice, Humans, Male, Brain metabolism, Female, Hyperaldosteronism metabolism, Mice, Knockout, Mice, Inbred C57BL, 11-beta-Hydroxysteroid Dehydrogenase Type 2 metabolism, 11-beta-Hydroxysteroid Dehydrogenase Type 2 genetics, Aldosterone metabolism, Neurons metabolism, Appetite drug effects, Sodium Chloride, Dietary adverse effects
Abstract

Excessive aldosterone production increases the risk of heart disease, stroke, dementia, and death. Aldosterone increases both sodium retention and sodium consumption, and increased sodium consumption may worsen end-organ damage in patients with aldosteronism. Preventing this increase could improve outcomes, but the behavioral mechanisms of aldosterone-induced sodium appetite remain unclear. In rodents, we previously identified aldosterone-sensitive neurons, which express the mineralocorticoid receptor and its prereceptor regulator, 11-β-hydroxysteroid dehydrogenase 2 (HSD2). In the present study, we identified HSD2 neurons in the human brain and then used a mouse model to evaluate their role in aldosterone-induced salt intake. First, we confirmed that dietary sodium deprivation increases aldosterone production, salt intake, and HSD2 neuron activity. Next, we showed that continuous chemogenetic stimulation of HSD2 neurons causes a large and specific increase in salt intake. Finally, we used dose-response studies and genetically targeted ablation of HSD2 neurons to show that these neurons are necessary for aldosterone-induced salt intake. Identifying HSD2 neurons in the human brain and establishing their necessity for aldosterone-induced salt intake in mice improves our understanding of appetitive circuits and highlights this small cell population as a therapeutic target for moderating dietary sodium.

Published
2024
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31. Renovating the Barnes maze for mouse models of Dementia with STARR FIELD: A 4-day protocol that probes learning rate, retention and cognitive flexibility.

Author

Bertolli A, Halhouli O, Liu-Martínez Y, Blaine B, Thangavel R, Zhang Q, Emmons E, Narayanan NS, Gumusoglu SB, Geerling JC, and Aldridge GM

Abstract

Land-based mazes that require spatial cues to identify the location of a hiding-place are a low-stress method to evaluate learning rate and memory retention in mice. One version, the Barnes maze, allows quantification of naturalistic exploratory behaviors not evident in water-based tasks. As the task relies on innate behaviors, it does not require overtraining, making it more feasible to examine early learning and non-memory executive functions that are characteristic of some non-amnestic dementias. However, because it is difficult to hide odor cues in the traditional version of the maze, learning rate during individual trials can be difficult to interpret. We designed and tested the use of 3D-printed escape shuttles that can be made in duplicate, as well as a docking tunnel that allows mice to self-exit the maze to improve reproducibility and limit experimenter influence. In combination with maze turning and escape tunnel caps, we show our shuttles mitigate the possibility of undesired cues. We then compare use of our 4-day protocol across several mouse models of cognitive impairment. We demonstrate an additional stage, the STARR protocol (Spatial Training and Rapid Reversal), to better challenge executive functions such as working memory and behavioral flexibility. We examine commonly used outcome measures across mice with and without access to spatial cues, as well as across mouse models of cognitive impairment to demonstrate the use of our 4-day protocol. Overall, this protocol provides detailed instructions to build and perform a robust spatial maze that can help expand the range of deficits identified. Our findings will aid in interpretation of traditional protocols, as well as provide an updated method to screen for both amnestic and non-amnestic cognitive changes.

Published
2024
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32. Efferent projections of Nps -expressing neurons in the parabrachial region.

Author

Zhang R, Huang D, Gasparini S, and Geerling JC

Abstract

In the brain, connectivity determines function. Neurons in the parabrachial nucleus (PB) relay diverse information to widespread brain regions, but the connections and functions of PB neurons that express Nps (neuropeptide S) remain mysterious. Here, we use Cre-dependent anterograde tracing and whole-brain analysis to map their output connections. While many other PB neurons project ascending axons through the central tegmental tract, NPS axons reach the forebrain via distinct periventricular and ventral pathways. Along the periventricular pathway, NPS axons target the tectal longitudinal column and periaqueductal gray then continue rostrally to target the paraventricular nucleus of the thalamus. Along the ventral pathway, NPS axons blanket much of the hypothalamus but avoid the ventromedial and mammillary nuclei. They also project prominently to the ventral bed nucleus of the stria terminalis, A13 cell group, and magnocellular subparafasciular nucleus. In the hindbrain, NPS axons have fewer descending projections, targeting primarily the superior salivatory nucleus, nucleus of the lateral lemniscus, and periolivary region. Combined with what is known about NPS and its receptor, the output pattern of Nps -expressing neurons in the PB region predicts a role in threat response and circadian behavior., Competing Interests: Conflict of Interest. The authors declare no conflicts of interest.

Published
2023
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33. Alpha-synuclein pre-formed fibrils injected into prefrontal cortex primarily spread to cortical and subcortical structures and lead to isolated behavioral symptoms.

Author

Weber MA, Kerr G, Thangavel R, Conlon MM, Abdelmotilib HA, Halhouli O, Zhang Q, Geerling JC, Narayanan NS, and Aldridge GM

Abstract

Parkinson's disease dementia (PDD) and dementia with Lewy bodies (DLB) are characterized by diffuse spread of alpha-synuclein (α-syn) throughout the brain. Patients with PDD and DLB have a neuropsychological pattern of deficits that include executive dysfunction, such as abnormalities in planning, timing, working memory, and behavioral flexibility. The prefrontal cortex (PFC) plays a major role in normal executive function and often develops α-syn aggregates in DLB and PDD. To investigate the consequences of α-syn pathology in the cortex, we injected human α-syn pre-formed fibrils into the PFC of wildtype mice. We report that PFC PFFs: 1) induced α-syn aggregation in multiple cortical and subcortical regions with sparse aggregation in midbrain and brainstem nuclei; 2) did not affect interval timing or spatial learning acquisition but did mildly alter behavioral flexibility as measured by intraday reversal learning; 3) increased open field exploration; and 4) did not affect susceptibility to an inflammatory challenge. This model of cortical-dominant pathology aids in our understanding of how local α-syn aggregation might impact some symptoms in PDD and DLB., Competing Interests: COMPETING INTERESTS The authors have no conflict of interest to report.

Published
2023
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