Your search keyword '"Kim, Young Joon"' showing total 15 results

1. Postprandial sodium sensing by enteric neurons in Drosophila.

Author

Kim B, Hwang G, Yoon SE, Kuang MC, Wang JW, Kim YJ, and Suh GSB

Subjects

Animals, Postprandial Period, Drosophila melanogaster, Enteric Nervous System metabolism, Taste physiology, Mutation, Drosophila, Sodium Channels, Receptors, Ionotropic Glutamate, Sodium metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Neurons metabolism

Abstract

Sodium is essential for all living organisms 1 . Animals including insects and mammals detect sodium primarily through peripheral taste cells 2-7 . It is not known, however, whether animals can detect this essential micronutrient independently of the taste system. Here, we report that Drosophila Ir76b mutants that were unable to detect sodium 2 became capable of responding to sodium following a period of salt deprivation. From a screen for cells required for the deprivation-induced sodium preference, we identified a population of anterior enteric neurons, which we named internal sodium-sensing (INSO) neurons, that are essential for directing a behavioural preference for sodium. Enteric INSO neurons innervate the gut epithelia mainly through their dendritic processes and send their axonal projections along the oesophagus to the brain and to the crop duct. Through calcium imaging and CaLexA experiments, we found that INSO neurons respond immediately and specifically to sodium ions. Notably, the sodium-evoked responses were observed only after a period of sodium deprivation. Taken together, we have identified a taste-independent sodium sensor that is essential for the maintenance of sodium homeostasis., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Single-neuronal elements of speech production in humans.

Author

Khanna AR, Muñoz W, Kim YJ, Kfir Y, Paulk AC, Jamali M, Cai J, Mustroph ML, Caprara I, Hardstone R, Mejdell M, Meszéna D, Zuckerman A, Schweitzer J, Cash S, and Williams ZM

Subjects

Humans, Movement, Speech Perception physiology, Neurons physiology, Phonetics, Speech physiology, Prefrontal Cortex cytology, Prefrontal Cortex physiology

Abstract

Humans are capable of generating extraordinarily diverse articulatory movement combinations to produce meaningful speech. This ability to orchestrate specific phonetic sequences, and their syllabification and inflection over subsecond timescales allows us to produce thousands of word sounds and is a core component of language 1,2 . The fundamental cellular units and constructs by which we plan and produce words during speech, however, remain largely unknown. Here, using acute ultrahigh-density Neuropixels recordings capable of sampling across the cortical column in humans, we discover neurons in the language-dominant prefrontal cortex that encoded detailed information about the phonetic arrangement and composition of planned words during the production of natural speech. These neurons represented the specific order and structure of articulatory events before utterance and reflected the segmentation of phonetic sequences into distinct syllables. They also accurately predicted the phonetic, syllabic and morphological components of upcoming words and showed a temporally ordered dynamic. Collectively, we show how these mixtures of cells are broadly organized along the cortical column and how their activity patterns transition from articulation planning to production. We also demonstrate how these cells reliably track the detailed composition of consonant and vowel sounds during perception and how they distinguish processes specifically related to speaking from those related to listening. Together, these findings reveal a remarkably structured organization and encoding cascade of phonetic representations by prefrontal neurons in humans and demonstrate a cellular process that can support the production of speech., (© 2024. The Author(s).)

Published

2024

3. Parallel functional architectures within a single dendritic tree.

Author

Kim YJ, Ujfalussy BB, and Lengyel M

Subjects

Pyramidal Cells physiology, Action Potentials physiology, Synapses physiology, Models, Neurological, Dendrites physiology, Neurons physiology

Abstract

The input-output transformation of individual neurons is a key building block of neural circuit dynamics. While previous models of this transformation vary widely in their complexity, they all describe the underlying functional architecture as unitary, such that each synaptic input makes a single contribution to the neuronal response. Here, we show that the input-output transformation of CA1 pyramidal cells is instead best captured by two distinct functional architectures operating in parallel. We used statistically principled methods to fit flexible, yet interpretable, models of the transformation of input spikes into the somatic "output" voltage and to automatically select among alternative functional architectures. With dendritic Na + channels blocked, responses are accurately captured by a single static and global nonlinearity. In contrast, dendritic Na + -dependent integration requires a functional architecture with multiple dynamic nonlinearities and clustered connectivity. These two architectures incorporate distinct morphological and biophysical properties of the neuron and its synaptic organization., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

4. Identification and characterization of GAL4 drivers that mark distinct cell types and regions in the Drosophila adult gut.

Author

Lim SY, You H, Lee J, Lee J, Lee Y, Lee KA, Kim B, Lee JH, Jeong J, Jang S, Kim B, Choi H, Hwang G, Choi MS, Yoon SE, Kwon JY, Lee WJ, Kim YJ, and Suh GSB

Subjects

Animals, Brain-Gut Axis physiology, Drosophila Proteins metabolism, Drosophila melanogaster, Transcription Factors metabolism, Drosophila Proteins genetics, Enteric Nervous System metabolism, Gastrointestinal Tract metabolism, Gene Expression Regulation, Developmental, Neurons metabolism, Transcription Factors genetics

Abstract

The gastrointestinal tract in the adult Drosophila serves as a model system for exploring the mechanisms underlying digestion, absorption and excretion, stem cell plasticity, and inter-organ communication, particularly through the gut-brain axis. It is also useful for studying the cellular and adaptive responses to dietary changes, alterations in microbiota and immunity, and systematic and endocrine signals. Despite the various cell types and distinct regions in the gastrointestinal tract, few tools are available to target and manipulate the activity of each cell type and region, and their gene expression. Here, we report 353 GAL4 lines and several split-GAL4 lines that are expressed in enteric neurons (ENs), progenitors (ISCs and EBs), enterocytes (ECs), enteroendocrine cells (EEs), or/and other cell types that are yet to be identified in distinct regions of the gut. We had initially collected approximately 600 GAL4 lines that may be expressed in the gut based on RNA sequencing data, and then crossed them to UAS-GFP to perform immunohistochemistry to identify those that are expressed selectively in the gut. The cell types and regional expression patterns that are associated with the entire set of GAL4 drivers and split-GAL4 combinations are annotated online at http://kdrc.kr/index.php (K-Gut Project). This GAL4 resource can be used to target specific populations of distinct cell types in the fly gut, and therefore, should permit a more precise investigation of gut cells that regulate important biological processes.

Published

2021

5. The neuropeptide allatostatin C from clock-associated DN1p neurons generates the circadian rhythm for oogenesis.

Author

Zhang C, Daubnerova I, Jang YH, Kondo S, Žitňan D, and Kim YJ

Subjects

Animals, Brain cytology, Brain metabolism, Drosophila Proteins metabolism, Drosophila melanogaster cytology, Drosophila melanogaster metabolism, Female, Gene Expression Regulation, Developmental, Insulin genetics, Insulin metabolism, Insulin-Secreting Cells cytology, Insulin-Secreting Cells metabolism, Juvenile Hormones genetics, Juvenile Hormones metabolism, Male, Neurons cytology, Receptors, G-Protein-Coupled genetics, Receptors, G-Protein-Coupled metabolism, Reproduction genetics, Signal Transduction, Vitellogenesis genetics, Circadian Clocks genetics, Circadian Rhythm genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Neurons metabolism, Oogenesis genetics

Abstract

The link between the biological clock and reproduction is evident in most metazoans. The fruit fly Drosophila melanogaster , a key model organism in the field of chronobiology because of its well-defined networks of molecular clock genes and pacemaker neurons in the brain, shows a pronounced diurnal rhythmicity in oogenesis. Still, it is unclear how the circadian clock generates this reproductive rhythm. A subset of the group of neurons designated "posterior dorsal neuron 1" (DN1p), which are among the ∼150 pacemaker neurons in the fly brain, produces the neuropeptide allatostatin C (AstC-DN1p). Here, we report that six pairs of AstC-DN1p send inhibitory inputs to the brain insulin-producing cells, which express two AstC receptors, star1 and AICR2. Consistent with the roles of insulin/insulin-like signaling in oogenesis, activation of AstC-DN1p suppresses oogenesis through the insulin-producing cells. We show evidence that AstC-DN1p activity plays a role in generating an oogenesis rhythm by regulating juvenile hormone and vitellogenesis indirectly via insulin/insulin-like signaling. AstC is orthologous to the vertebrate neuropeptide somatostatin (SST). Like AstC, SST inhibits gonadotrophin secretion indirectly through gonadotropin-releasing hormone neurons in the hypothalamus. The functional and structural conservation linking the AstC and SST systems suggest an ancient origin for the neural substrates that generate reproductive rhythms., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

6. Endocrine regulation of airway clearance in Drosophila .

Author

Kim DH, Kim YJ, and Adams ME

Subjects

Animals, Calcium metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster drug effects, Ion Channels, Larva drug effects, Larva physiology, Neurons cytology, Neurons drug effects, Receptors, Peptide genetics, Receptors, Peptide metabolism, Signal Transduction, TRPA1 Cation Channel genetics, TRPA1 Cation Channel metabolism, Trachea cytology, Trachea drug effects, Airway Obstruction drug therapy, Drosophila melanogaster physiology, Insect Hormones pharmacology, Kinins pharmacology, Neurons physiology, Trachea physiology

Abstract

Fluid clearance from the respiratory system during developmental transitions is critically important for achieving optimal gas exchange in animals. During insect development from embryo to adult, airway clearance occurs episodically each time the molt is completed by performance of the ecdysis sequence, coordinated by a peptide-signaling cascade initiated by ecdysis-triggering hormone (ETH). We find that the neuropeptide Kinin (also known as Drosokinin or Leukokinin) is required for normal respiratory fluid clearance or "tracheal air-filling" in Drosophila larvae. Disruption of Kinin signaling leads to defective air-filling during all larval stages. Such defects are observed upon ablation or electrical silencing of Kinin neurons, as well as RNA silencing of the Kinin gene or the ETH receptor in Kinin neurons, indicating that ETH targets Kinin neurons to promote tracheal air-filling. A Kinin receptor mutant fly line ( Lkr f02594 ) also exhibits tracheal air-filling defects in all larval stages. Targeted Kinin receptor silencing in tracheal epithelial cells using breathless or pickpocket ( ppk ) drivers compromises tracheal air-filling. On the other hand, promotion of Kinin signaling in vivo through peptide injection or Kinin neuron activation through Drosophila TrpA1 (dTrpA1) expression induces premature tracheal collapse and air-filling. Moreover, direct exposure of tracheal epithelial cells in vitro to Kinin leads to calcium mobilization in tracheal epithelial cells. Our findings strongly implicate the neuropeptide Kinin as an important regulator of airway clearance via intracellular calcium mobilization in tracheal epithelial cells of Drosophila ., Competing Interests: The authors declare no conflict of interest.

Published

2018

7. Fine-scale mapping of natural variation in fly fecundity identifies neuronal domain of expression and function of an aquaporin.

Author

Bergland AO, Chae HS, Kim YJ, and Tatar M

Subjects

Animals, Aquaporins metabolism, Chromosome Mapping, Drosophila Proteins genetics, Drosophila Proteins metabolism, Female, Gene Expression Regulation, Neuropeptides genetics, Neuropeptides metabolism, Quantitative Trait Loci genetics, RNA Interference, RNA, Messenger genetics, Transcription Factors genetics, Transcription Factors metabolism, Aquaporins genetics, Drosophila melanogaster genetics, Drosophila melanogaster physiology, Fertility genetics, Genetic Fitness genetics, Neurons metabolism

Abstract

To gain insight into the molecular genetic basis of standing variation in fitness related traits, we identify a novel factor that regulates the molecular and physiological basis of natural variation in female Drosophila melanogaster fecundity. Genetic variation in female fecundity in flies derived from a wild orchard population is heritable and largely independent of other measured life history traits. We map a portion of this variation to a single QTL and then use deficiency mapping to further refine this QTL to 5 candidate genes. Ubiquitous expression of RNAi against only one of these genes, an aquaporin encoded by Drip, reduces fecundity. Within our mapping population Drip mRNA level in the head, but not other tissues, is positively correlated with fecundity. We localize Drip expression to a small population of corazonin producing neurons located in the dorsolateral posterior compartments of the protocerebrum. Expression of Drip-RNAi using both the pan-neuronal ELAV-Gal4 and the Crz-Gal4 drivers reduces fecundity. Low-fecundity RILs have decreased Crz expression and increased expression of pale, the enzyme encoding the rate-limiting step in the production of dopamine, a modulator of insect life histories. Taken together these data suggest that natural variation in Drip expression in the corazonin producing neurons contributes to standing variation in fitness by altering the concentration of two neurohormones., Competing Interests: The authors have declared that no competing interests exist.

Published

2012

8. Regulation of insect steroid hormone biosynthesis by innervating peptidergic neurons.

Author

Yamanaka N, Zitnan D, Kim YJ, Adams ME, Hua YJ, Suzuki Y, Suzuki M, Suzuki A, Satake H, Mizoguchi A, Asaoka K, Tanaka Y, and Kataoka H

Subjects

Amino Acid Sequence, Animals, Bombyx metabolism, FMRFamide chemistry, FMRFamide genetics, FMRFamide isolation & purification, Ganglia metabolism, Humans, Molecular Sequence Data, Neurons cytology, RNA, Messenger genetics, RNA, Messenger metabolism, FMRFamide metabolism, Gene Expression Regulation, Developmental, Insect Hormones biosynthesis, Neurons metabolism

Abstract

In insects, steroid hormones named ecdysteroids elicit molting and metamorphosis. The prothoracic gland (PG) is a predominant source of ecdysteroids, where their biosynthesis (ecdysteroidogenesis) is regulated by several neuropeptides. Here, we report that FMRFamide-related peptides (FaRPs) regulate ecdysteroidogenesis through direct innervation of the PG in the silkworm Bombyx mori. We purified a previously uncharacterized Bombyx FaRP, DPSFIRFamide, and identified the corresponding Bombyx FMRFamide gene (Bommo-FMRFamide, BRFa), which encodes three additional FaRPs. All BRFa peptides suppressed ecdysteroidogenesis in the PG by reducing cAMP production by means of the receptor for Bommo-myosuppressin, another FaRP we have previously shown to act as a prothoracicostatic factor. BRFa is predominantly expressed in neurosecretory cells of thoracic ganglia, and the neurons in the prothoracic ganglion innervate the PG to supply all four peptides to the gland surface. Electrophysiological recordings during development confirmed the increased firing activity of BRFa neurons in stages with low PG activity and decreased ecdysteroid levels in the hemolymph. To our knowledge, this study provides the first report of peptides controlling ecdysteroidogenesis by direct innervation.

Published

2006

9. Corazonin Receptor Signaling in Ecdysis Initiation

Author

Kim, Young-Joon, Spalovská-Valachová, Ivana, Cho, Kook-Ho, Zitnanova, Inka, Park, Yoonseong, Adams, Michael E., Žitňan, Dušan, and Hammock, Bruce D.

Published

2004

10. Central Peptidergic Ensembles Associated with Organization of an Innate Behavior

Author

Kim, Young-Joon, Žiňan, Dušan, Cho, Kook-Ho, Schooley, David A., Mizoguchi, Akira, and Adams, Michael E.

Published

2006

11. Endocrine regulation of airway clearance in Drosophila

Author

Kim, Do-Hyoung, Kim, Young-Joon, and Adams, Michael E

Subjects

Neurons, tracheal collapse, pickpocket, Kinins, Kinin, Ion Channels, tracheal air-filling, Trachea, Airway Obstruction, Drosophila melanogaster, Insect Hormones, Larva, Receptors, Peptide, ecdysis-triggering hormone, Respiratory, Animals, Drosophila Proteins, Calcium, TRPA1 Cation Channel, Signal Transduction

Abstract

Fluid clearance from the respiratory system during developmental transitions is critically important for achieving optimal gas exchange in animals. During insect development from embryo to adult, airway clearance occurs episodically each time the molt is completed by performance of the ecdysis sequence, coordinated by a peptide-signaling cascade initiated by ecdysis-triggering hormone (ETH). We find that the neuropeptide Kinin (also known as Drosokinin or Leukokinin) is required for normal respiratory fluid clearance or "tracheal air-filling" in Drosophila larvae. Disruption of Kinin signaling leads to defective air-filling during all larval stages. Such defects are observed upon ablation or electrical silencing of Kinin neurons, as well as RNA silencing of the Kinin gene or the ETH receptor in Kinin neurons, indicating that ETH targets Kinin neurons to promote tracheal air-filling. A Kinin receptor mutant fly line (Lkrf02594 ) also exhibits tracheal air-filling defects in all larval stages. Targeted Kinin receptor silencing in tracheal epithelial cells using breathless or pickpocket (ppk) drivers compromises tracheal air-filling. On the other hand, promotion of Kinin signaling in vivo through peptide injection or Kinin neuron activation through Drosophila TrpA1 (dTrpA1) expression induces premature tracheal collapse and air-filling. Moreover, direct exposure of tracheal epithelial cells in vitro to Kinin leads to calcium mobilization in tracheal epithelial cells. Our findings strongly implicate the neuropeptide Kinin as an important regulator of airway clearance via intracellular calcium mobilization in tracheal epithelial cells of Drosophila.

Published

2018

12. A fat-derived metabolite regulates a peptidergic feeding circuit in Drosophila.

Author

Kim, Do-Hyoung, Shin, Minjung, Jung, Sung-Hwan, Kim, Young-Joon, and Jones, Walton D.

Subjects

DROSOPHILA, TETRAHYDROBIOPTERIN, BIOSYNTHESIS, NEUROPEPTIDES, METABOLITES

Abstract

Here, we show that the enzymatic cofactor tetrahydrobiopterin (BH4) inhibits feeding in Drosophila. BH4 biosynthesis requires the sequential action of the conserved enzymes Punch, Purple, and Sepiapterin Reductase (Sptr). Although we observe increased feeding upon loss of Punch and Purple in the adult fat body, loss of Sptr must occur in the brain. We found Sptr expression is required in four adult neurons that express neuropeptide F (NPF), the fly homologue of the vertebrate appetite regulator neuropeptide Y (NPY). As expected, feeding flies BH4 rescues the loss of Punch and Purple in the fat body and the loss of Sptr in NPF neurons. Mechanistically, we found BH4 deficiency reduces NPF staining, likely by promoting its release, while excess BH4 increases NPF accumulation without altering its expression. We thus show that, because of its physically distributed biosynthesis, BH4 acts as a fat-derived signal that induces satiety by inhibiting the activity of the NPF neurons. [ABSTRACT FROM AUTHOR]

Published

2017

13. A Homeostatic Sleep-Stabilizing Pathway in Drosophila Composed of the Sex Peptide Receptor and Its Ligand, the Myoinhibitory Peptide.

Author

Oh, Yangkyun, Yoon, Sung-Eun, Zhang, Qi, Chae, Hyo-Seok, Daubnerová, Ivana, Shafer, Orie T., Choe, Joonho, and Kim, Young-Joon

Subjects

DROSOPHILA melanogaster, SLEEP, PEPTIDE receptors, CIRCADIAN rhythms, REPRODUCTION, NEURONS, INSECTS

Abstract

: A ligand of the sex peptide receptor maintains sleep stability and homeostasis by inhibiting wakefulness-promoting neurons in Drosophila. [ABSTRACT FROM AUTHOR]

Published

2014

14. A Command Chemical Triggers an Innate Behavior by Sequential Activation of Multiple Peptidergic Ensembles

Author

Kim, Young-Joon, Žitňan, Dušan, Galizia, C. Giovanni, Cho, Kook-Ho, and Adams, Michael E.

Subjects

*ECDYSIS, *NERVOUS system, *NEURONS, *PEPTIDES

Abstract

Summary: Background: At the end of each molt, insects shed their old cuticle by performing the ecdysis sequence, an innate behavior consisting of three steps: pre-ecdysis, ecdysis, and postecdysis. Blood-borne ecdysis-triggering hormone (ETH) activates the behavioral sequence through direct actions on the central nervous system. Results: To elucidate neural substrates underlying the ecdysis sequence, we identified neurons expressing ETH receptors (ETHRs) in Drosophila. Distinct ensembles of ETHR neurons express numerous neuropeptides including kinin, FMRFamides, eclosion hormone (EH), crustacean cardioactive peptide (CCAP), myoinhibitory peptides (MIP), and bursicon. Real-time imaging of intracellular calcium dynamics revealed sequential activation of these ensembles after ETH action. Specifically, FMRFamide neurons are activated during pre-ecdysis; EH, CCAP, and CCAP/MIP neurons are active prior to and during ecdysis; and activity of CCAP/MIP/bursicon neurons coincides with postecdysis. Targeted ablation of specific ETHR ensembles produces behavioral deficits consistent with their proposed roles in the behavioral sequence. Conclusions: Our findings offer novel insights into how a command chemical orchestrates an innate behavior by stepwise recruitment of central peptidergic ensembles. [Copyright &y& Elsevier]

Published

2006

15. Identification of a Peptidergic Pathway Critical to Satiety Responses in Drosophila.

Author

Min, Soohong, Chae, Hyo-Seok, Jang, Yong-Hoon, Choi, Sekyu, Lee, Sion, Jeong, Yong Taek, Jones, Walton D., Moon, Seok Jun, Kim, Young-Joon, and Chung, Jongkyeong

Subjects

*DROSOPHILA, *NEUROPEPTIDES, *NEURONS, *PEPTIDE receptors, *REGULATION of body weight

Abstract

Summary Although several neural pathways have been implicated in feeding behaviors in mammals [ 1–7 ], it remains unclear how the brain coordinates feeding motivations to maintain a constant body weight (BW). Here, we identified a neuropeptide pathway important for the satiety and BW control in Drosophila . Silencing of myoinhibitory peptide (MIP) neurons significantly increased BW through augmented food intake and fat storage. Likewise, the loss-of-function mutation of mip also increased feeding and BW. Suppressing the MIP pathway induced satiated flies to behave like starved ones, with elevated sensitivity toward food. Conversely, activating MIP neurons greatly decreased food intake and BW and markedly blunted the sensitivity of starved flies toward food. Upon terminating the activation protocol of MIP neurons, the decreased BW reverts rapidly to the normal level through a strong feeding rebound, indicating the switch-like role of MIP pathway in feeding. Surprisingly, the MIP-mediated BW decrease occurred independently of sex peptide receptor (SPR), the only known receptor for MIP, suggesting the presence of a yet-unknown MIP receptor. Together, our results reveal a novel anorexigenic pathway that controls satiety in Drosophila and provide a new avenue to study how the brain actively maintains a constant BW. [ABSTRACT FROM AUTHOR]

Published

2016