Your search keyword '"Huey, Erica"' showing total 9 results

1. A gut-to-brain signal of fluid osmolarity controls thirst satiation

Author

Zimmerman, Christopher A., Huey, Erica L., Ahn, Jamie S., Beutler, Lisa R., Tan, Chan Lek, Kosar, Seher, Bai, Ling, Chen, Yiming, Corpuz, Timothy V., Madisen, Linda, Zeng, Hongkui, and Knight, Zachary A.

Published

2019

2. Thirst neurons anticipate the homeostatic consequences of eating and drinking

Author

Zimmerman, Christopher A., Lin, Yen-Chu, Leib, David E., Guo, Ling, Huey, Erica L., Daly, Gwendolyn E., Chen, Yiming, and Knight, Zachary A.

Subjects

Drinking (Physiology) -- Research, Neurological research, Eating (Physiology) -- Research, Neurons -- Physiological aspects, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Author(s): Christopher A. Zimmerman [1, 2, 3]; Yen-Chu Lin [1, 2]; David E. Leib [1, 2, 3]; Ling Guo [1, 2, 3]; Erica L. Huey [1, 2]; Gwendolyn E. Daly [...]

Published

2016

3. The chromatin-associated 53BP1 ortholog, HSR-9, regulates recombinational repair and X chromosome segregation in the Caenorhabditis elegans germ line.

Author

Li, Qianyan, Hariri, Sara, Calidas, Aashna, Kaur, Arshdeep, Huey, Erica, and Engebrecht, JoAnne

Subjects

*BIOLOGICAL models, *GERM cells, *RESEARCH funding, *CELL physiology, *CELL proliferation, *DESCRIPTIVE statistics, *MICE, *CHROMOSOMES, *DNA damage, *DNA repair, *ANIMAL experimentation, *CAENORHABDITIS elegans, *GENETIC mutation, *DNA-binding proteins, *GENETICS

Abstract

53BP1 plays a crucial role in regulating DNA damage repair pathway choice and checkpoint signaling in somatic cells; however, its role in meiosis has remained enigmatic. In this study, we demonstrate that the Caenorhabditis elegans ortholog of 53BP1, HSR-9 , associates with chromatin in both proliferating and meiotic germ cells. Notably, HSR-9 is enriched on the X chromosome pair in pachytene oogenic germ cells. HSR-9 is also present at kinetochores during both mitotic and meiotic divisions but does not appear to be essential for monitoring microtubule–kinetochore attachments or tension. Using cytological markers of different steps in recombinational repair, we found that HSR-9 influences the processing of a subset of meiotic double-stranded breaks into COSA-1 -marked crossovers. Additionally, HSR-9 plays a role in meiotic X chromosome segregation under conditions where X chromosomes fail to pair, synapse, and recombine. Together, these results highlight that chromatin-associated HSR-9 has both conserved and unique functions in the regulation of meiotic chromosome behavior. [ABSTRACT FROM AUTHOR]

Published

2024

4. Mechanoreceptor synapses in the brainstem shape the central representation of touch.

Author

Lehnert, Brendan P., Santiago, Celine, Huey, Erica L., Emanuel, Alan J., Renauld, Sophia, Africawala, Nusrat, Alkislar, Ilayda, Zheng, Yang, Bai, Ling, Koutsioumpa, Charalampia, Hong, Jennifer T., Magee, Alexandra R., Harvey, Christopher D., and Ginty, David D.

Subjects

*SYNAPSES, *PERIPHERAL nervous system, *PROPORTIONAL representation, *BODY surface mapping, *NEURONS

Abstract

Mammals use glabrous (hairless) skin of their hands and feet to navigate and manipulate their environment. Cortical maps of the body surface across species contain disproportionately large numbers of neurons dedicated to glabrous skin sensation, in part reflecting a higher density of mechanoreceptors that innervate these skin regions. Here, we find that disproportionate representation of glabrous skin emerges over postnatal development at the first synapse between peripheral mechanoreceptors and their central targets in the brainstem. Mechanoreceptor synapses undergo developmental refinement that depends on proximity of their terminals to glabrous skin, such that those innervating glabrous skin make synaptic connections that expand their central representation. In mice incapable of sensing gentle touch, mechanoreceptors innervating glabrous skin still make more powerful synapses in the brainstem. We propose that the skin region a mechanoreceptor innervates controls the developmental refinement of its central synapses to shape the representation of touch in the brain. [Display omitted] • Disproportionate representation of glabrous skin emerges over postnatal development • Body representation remaps over development through changes at brainstem synapses • Adult mechanoreceptors in or near glabrous skin make stronger central synapses • Regional differences in mechanoreceptor synaptic strength persist absent evoked activity. Mechanoreceptors that innervate glabrous skin form more numerous and powerful synaptic connections onto ascending projection neurons in brainstem than mechanoreceptors that innervate hairy skin. This suggests that skin type affects how neurons in the brain represent neurons in the body. [ABSTRACT FROM AUTHOR]

Published

2021

5. γ-Protocadherins control synapse formation and peripheral branching of touch sensory neurons.

Author

Meltzer, Shan, Boulanger, Katelyn C., Chirila, Anda M., Osei-Asante, Emmanuella, DeLisle, Michelle, Zhang, Qiyu, Kalish, Brian T., Tasnim, Aniqa, Huey, Erica L., Fuller, Leah C., Flaherty, Erin K., Maniatis, Tom, Garrett, Andrew M., Weiner, Joshua A., and Ginty, David D.

Subjects

*SENSORY neurons, *SYNAPTOGENESIS, *SPINAL cord, *NEURON development, *CARRIER proteins

Abstract

Light touch sensation begins with activation of low-threshold mechanoreceptor (LTMR) endings in the skin and propagation of their signals to the spinal cord and brainstem. We found that the clustered protocadherin gamma (Pcdhg) gene locus, which encodes 22 cell-surface homophilic binding proteins, is required in somatosensory neurons for normal behavioral reactivity to a range of tactile stimuli. Developmentally, distinct Pcdhg isoforms mediate LTMR synapse formation through neuron-neuron interactions and peripheral axonal branching through neuron-glia interactions. The Pcdhgc3 isoform mediates homophilic interactions between sensory axons and spinal cord neurons to promote synapse formation in vivo and is sufficient to induce postsynaptic specializations in vitro. Moreover, loss of Pcdhgs and somatosensory synaptic inputs to the dorsal horn leads to fewer corticospinal synapses on dorsal horn neurons. These findings reveal essential roles for Pcdhg isoform diversity in somatosensory neuron synapse formation, peripheral axonal branching, and stepwise assembly of central mechanosensory circuitry. [Display omitted] • Pcdhg isoforms have compartmentalized roles in touch sensory neuron development • Pcdhgc3 promotes synapse formation between sensory neurons and spinal cord neurons • Pcdhgs promote peripheral axonal branching through neuron-glia interactions • Sensory inputs to the spinal cord regulate the assembly of spinal cord circuitry Meltzer et al. show that the clustered protocadherin gamma (Pcdhg) gene locus regulates somatosensory neuron synapse formation and peripheral axonal branching. Pcdhgc3 is the only isoform that promotes synapse formation between sensory neurons and spinal cord neurons. Further, they found that somatosensory inputs regulate the assembly of spinal cord circuitry. [ABSTRACT FROM AUTHOR]

Published

2023

6. The chromatin-associated 53BP1 ortholog, HSR-9, regulates recombinational repair and X chromosome segregation in the Caenorhabditis elegans germ line.

Author

Li Q, Hariri S, Calidas A, Kaur A, Huey E, and Engebrecht J

Abstract

53BP1 plays a crucial role in regulating DNA damage repair pathway choice and checkpoint signaling in somatic cells; however, its role in meiosis has remained enigmatic. In this study, we demonstrate that the Caenorhabditis elegans ortholog of 53BP1, HSR-9, associates with chromatin in both proliferating and meiotic germ cells. Notably, HSR-9 is enriched on the X chromosome pair in pachytene oogenic germ cells. HSR-9 is also present at kinetochores during both mitotic and meiotic divisions but does not appear to be essential for monitoring microtubule-kinetochore attachments or tension. Using cytological markers of different steps in recombinational repair, we found that HSR-9 influences the processing of a subset of meiotic double strand breaks into COSA-1-marked crossovers. Additionally, HSR-9 plays a role in meiotic X chromosome segregation under conditions where X chromosomes fail to pair, synapse, and recombine. Together, these results highlight that chromatin-associated HSR-9 has both conserved and unique functions in the regulation of meiotic chromosome behavior.

Published

2024

7. The auditory midbrain mediates tactile vibration sensing.

Author

Huey EL, Turecek J, Delisle MM, Mazor O, Romero GE, Dua M, Sarafis ZK, Hobble A, Booth KT, Goodrich LV, Corey DP, and Ginty DD

Abstract

Vibrations are ubiquitous in nature, shaping behavior across the animal kingdom. For mammals, mechanical vibrations acting on the body are detected by mechanoreceptors of the skin and deep tissues and processed by the somatosensory system, while sound waves traveling through air are captured by the cochlea and encoded in the auditory system. Here, we report that mechanical vibrations detected by the body's Pacinian corpuscle neurons, which are unique in their ability to entrain to high frequency (40-1000 Hz) environmental vibrations, are prominently encoded by neurons in the lateral cortex of the inferior colliculus (LCIC) of the midbrain. Remarkably, most LCIC neurons receive convergent Pacinian and auditory input and respond more strongly to coincident tactile-auditory stimulation than to either modality alone. Moreover, the LCIC is required for behavioral responses to high frequency mechanical vibrations. Thus, environmental vibrations captured by Pacinian corpuscles are encoded in the auditory midbrain to mediate behavior.

Published

2024

8. Genetic Identification of Vagal Sensory Neurons That Control Feeding.

Author

Bai L, Mesgarzadeh S, Ramesh KS, Huey EL, Liu Y, Gray LA, Aitken TJ, Chen Y, Beutler LR, Ahn JS, Madisen L, Zeng H, Krasnow MA, and Knight ZA

Subjects

Agouti-Related Protein metabolism, Animals, Brain physiology, Gastrointestinal Tract innervation, Genetic Markers, Mechanoreceptors metabolism, Mice, Vagus Nerve anatomy & histology, Viscera innervation, Feeding Behavior physiology, Genetic Phenomena, Sensory Receptor Cells physiology, Vagus Nerve physiology

Abstract

Energy homeostasis requires precise measurement of the quantity and quality of ingested food. The vagus nerve innervates the gut and can detect diverse interoceptive cues, but the identity of the key sensory neurons and corresponding signals that regulate food intake remains unknown. Here, we use an approach for target-specific, single-cell RNA sequencing to generate a map of the vagal cell types that innervate the gastrointestinal tract. We show that unique molecular markers identify vagal neurons with distinct innervation patterns, sensory endings, and function. Surprisingly, we find that food intake is most sensitive to stimulation of mechanoreceptors in the intestine, whereas nutrient-activated mucosal afferents have no effect. Peripheral manipulations combined with central recordings reveal that intestinal mechanoreceptors, but not other cell types, potently and durably inhibit hunger-promoting AgRP neurons in the hypothalamus. These findings identify a key role for intestinal mechanoreceptors in the regulation of feeding., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

9. The Forebrain Thirst Circuit Drives Drinking through Negative Reinforcement.

Author

Leib DE, Zimmerman CA, Poormoghaddam A, Huey EL, Ahn JS, Lin YC, Tan CL, Chen Y, and Knight ZA

Subjects

Animals, Channelrhodopsins genetics, Channelrhodopsins metabolism, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Mice, Transgenic, Neurons physiology, Optogenetics, Pituitary Adenylate Cyclase-Activating Polypeptide genetics, Pituitary Adenylate Cyclase-Activating Polypeptide metabolism, Preoptic Area physiology, Prosencephalon cytology, Receptor, Angiotensin, Type 1 genetics, Receptor, Angiotensin, Type 1 metabolism, Subfornical Organ physiology, Drinking Behavior physiology, Motivation, Prosencephalon physiology, Reinforcement, Psychology, Thirst physiology

Abstract

The brain transforms the need for water into the desire to drink, but how this transformation is performed remains unknown. Here we describe the motivational mechanism by which the forebrain thirst circuit drives drinking. We show that thirst-promoting subfornical organ neurons are negatively reinforcing and that this negative-valence signal is transmitted along projections to the organum vasculosum of the lamina terminalis (OVLT) and median preoptic nucleus (MnPO). We then identify molecularly defined cell types within the OVLT and MnPO that are activated by fluid imbalance and show that stimulation of these neurons is sufficient to drive drinking, cardiovascular responses, and negative reinforcement. Finally, we demonstrate that the thirst signal exits these regions through at least three parallel pathways and show that these projections dissociate the cardiovascular and behavioral responses to fluid imbalance. These findings reveal a distributed thirst circuit that motivates drinking by the common mechanism of drive reduction., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017