Your search keyword '"neuronal circuits"' showing total 1,386 results

1. Causal contributions of cell-type-specific circuits in the posterior dorsal striatum to auditory decision-making

Author

Cui, Lele, Tang, Shunhang, Pan, Jingwei, Deng, Li, Zhang, Zhaoran, Zhao, Kai, Si, Bailu, and Xu, Ning-long

Published

2025

2. Impaired pain in mice lacking first-order posterior medial thalamic neurons.

Author

Sgourdou, Paraskevi, Schaffler, Melanie, Choi, Kyuhyun, McCall, Nora M., Burdge, Justin, Williams, Joelle, Corder, Gregory, Fuccillo, Marc V., Abdus-Saboor, Ishmail, and Epstein, Douglas J.

Subjects

*CEREBRAL cortex, *SOMATOSENSORY cortex, *PAIN perception, *THALAMUS, *EMBRYOLOGY, *THALAMIC nuclei

Abstract

The rostral, or first-order, area of the posterior medial thalamic nucleus is mainly responsible for the acute pain response in mice. The thalamus plays an important role in sensory and motor information processing by mediating communication between the periphery and the cerebral cortex. Alterations in thalamic development have profound consequences on sensory and motor function. In this study, we investigated a mouse model in which thalamic nuclei formation is disrupted because of the absence of Sonic hedgehog (Shh) expression from 2 key signaling centers that are required for embryonic forebrain development. The resulting defects observed in distinct thalamic sensory nuclei in Shh mutant embryos persisted into adulthood prompting us to examine their effect on behavioral responses to somatosensory stimulation. Our findings reveal a role for first-order posterior medial thalamic neurons and their projections to layer 4 of the secondary somatosensory cortex in the transmission of nociceptive information. Together, these results establish a connection between a neurodevelopmental lesion in the thalamus and a modality-specific disruption in pain perception. [ABSTRACT FROM AUTHOR]

Published

2025

3. Dynamic changes in the hippocampal neuronal circuits activity following acute stress revealed by miniature fluorescence microscopy imaging.

Author

Gerasimov, Evgenii, Pchitskaya, Ekaterina, Vlasova, Olga, and Bezprozvanny, Ilya

Subjects

*FLUORESCENCE microscopy, *MEDICAL sciences, *TIME pressure, *INFORMATION processing, *NEUROSCIENCES

Abstract

Coordinated activity of neuronal ensembles is a basis for information processing in the brain. Recent development of miniscope imaging technology enabled recordings of neuronal circuits activity in vivo in freely behaving animals. Acute stress is believed to affect various hippocampal functions, especially memory. In the current study, we utilized miniscope imaging to investigate the hippocampal neuronal circuits properties in a mouse as function of time and immediately in response to an acute stress, induced by passive restraint, 3 h and 10 days after. Comprehensive quantitative analysis of network activity changes at the neuronal ensembles level revealed highly stable neuronal activity parameters, which exhibited a rapid and robust shift in response to acute stress stimulation. This shift was accompanied by the restructuring of the pairwise-correlated neuronal pairs. Remarkably, we discovered that ensembles activity characteristics returned to the initial state following recovery period, demonstrating hippocampal homeostatic stability at the neuronal circuits level. Obtained results provide an evidence about hippocampal neuronal ensembles activity in response to acute stress over time. [ABSTRACT FROM AUTHOR]

Published

2024

4. Increased understanding of complex neuronal circuits in the cerebellar cortex.

Author

Jun, Soyoung, Park, Heeyoun, Kim, Muwoong, Kang, Seulgi, Kim, Taehyeong, Kim, Daun, Yamamoto, Yukio, and Tanaka-Yamamoto, Keiko

Subjects

GRANULE cells, PURKINJE cells, MOTOR learning, POTENTIAL functions, CEREBELLUM, CEREBELLAR cortex, NEURAL transmission

Abstract

The prevailing belief has been that the fundamental structures of cerebellar neuronal circuits, consisting of a few major neuron types, are simple and well understood. Given that the cerebellum has long been known to be crucial for motor behaviors, these simple yet organized circuit structures seemed beneficial for theoretical studies proposing neural mechanisms underlying cerebellar motor functions and learning. On the other hand, experimental studies using advanced techniques have revealed numerous structural properties that were not traditionally defined. These include subdivided neuronal types and their circuit structures, feedback pathways from output Purkinje cells, and the multidimensional organization of neuronal interactions. With the recent recognition of the cerebellar involvement in non-motor functions, it is possible that these newly identified structural properties, which are potentially capable of generating greater complexity than previously recognized, are associated with increased information capacity. This, in turn, could contribute to the wide range of cerebellar functions. However, it remains largely unknown how such structural properties contribute to cerebellar neural computations through the regulation of neuronal activity or synaptic transmissions. To promote further research into cerebellar circuit structures and their functional significance, we aim to summarize the newly identified structural properties of the cerebellar cortex and discuss future research directions concerning cerebellar circuit structures and their potential functions. [ABSTRACT FROM AUTHOR]

Published

2024

5. Nutritional state-dependent modulation of insulin-producing cells in Drosophila

Author

Rituja S Bisen, Fathima Mukthar Iqbal, Federico Cascino-Milani, Till Bockemühl, and Jan M Ache

Subjects

Insulin, incretin effect, metabolic homeostasis, in vivo electrophysiology, neuronal circuits, locomotion, Medicine, Science, Biology (General), QH301-705.5

Abstract

Insulin plays a key role in metabolic homeostasis. Drosophila insulin-producing cells (IPCs) are functional analogues of mammalian pancreatic beta cells and release insulin directly into circulation. To investigate the in vivo dynamics of IPC activity, we quantified the effects of nutritional and internal state changes on IPCs using electrophysiological recordings. We found that the nutritional state strongly modulates IPC activity. IPC activity decreased with increasing periods of starvation. Refeeding flies with glucose or fructose, two nutritive sugars, significantly increased IPC activity, whereas non-nutritive sugars had no effect. In contrast to feeding, glucose perfusion did not affect IPC activity. This was reminiscent of the mammalian incretin effect, where glucose ingestion drives higher insulin release than intravenous application. Contrary to IPCs, Diuretic hormone 44-expressing neurons in the pars intercerebralis (DH44PINs) responded to glucose perfusion. Functional connectivity experiments demonstrated that these DH44PINs do not affect IPC activity, while other DH44Ns inhibit them. Hence, populations of autonomously and systemically sugar-sensing neurons work in parallel to maintain metabolic homeostasis. Accordingly, activating IPCs had a small, satiety-like effect on food-searching behavior and reduced starvation-induced hyperactivity, whereas activating DH44Ns strongly increased hyperactivity. Taken together, we demonstrate that IPCs and DH44Ns are an integral part of a modulatory network that orchestrates glucose homeostasis and adaptive behavior in response to shifts in the metabolic state.

Published

2025

6. Prefrontal Regulation of Social Behavior and Related Deficits: Insights From Rodent Studies.

Author

Mack, Nancy R., Bouras, Nadia N., and Gao, Wen-Jun

Subjects

*COLLECTIVE memory, *SOCIAL isolation, *SOCIAL cues, *SOCIAL processes, *SOCIAL status

Abstract

The prefrontal cortex (PFC) is well known as the executive center of the brain, combining internal states and goals to execute purposeful behavior, including social actions. With the advancement of tools for monitoring and manipulating neural activity in rodents, substantial progress has been made in understanding the specific cell types and neural circuits within the PFC that are essential for processing social cues and influencing social behaviors. Furthermore, combining these tools with translationally relevant behavioral paradigms has also provided novel insights into the PFC neural mechanisms that may contribute to social deficits in various psychiatric disorders. This review highlights findings from the past decade that have shed light on the PFC cell types and neural circuits that support social information processing and distinct aspects of social behavior, including social interactions, social memory, and social dominance. We also explore how the PFC contributes to social deficits in rodents induced by social isolation, social fear conditioning, and social status loss. These studies provide evidence that the PFC uses both overlapping and unique neural mechanisms to support distinct components of social cognition. Furthermore, specific PFC neural mechanisms drive social deficits induced by different contexts. [ABSTRACT FROM AUTHOR]

Published

2024

7. Predictive Processing: A Circuit Approach to Psychosis.

Author

Keller, Georg B. and Sterzer, Philipp

Subjects

*ANTIPSYCHOTIC agents, *NEURAL circuitry, *CIRCUIT elements, *PSYCHOSES, *SCHIZOPHRENIA

Abstract

Predictive processing is a computational framework that aims to explain how the brain processes sensory information by making predictions about the environment and minimizing prediction errors. It can also be used to explain some of the key symptoms of psychotic disorders such as schizophrenia. In recent years, substantial advances have been made in our understanding of the neuronal circuitry that underlies predictive processing in cortex. In this review, we summarize these findings and how they might relate to psychosis and to observed cell type–specific effects of antipsychotic drugs. We argue that quantifying the effects of antipsychotic drugs on specific neuronal circuit elements is a promising approach to understanding not only the mechanism of action of antipsychotic drugs but also psychosis. Finally, we outline some of the key experiments that should be done. The aims of this review are to provide an overview of the current circuit-based approaches to psychosis and to encourage further research in this direction. [ABSTRACT FROM AUTHOR]

Published

2024

8. Cell type-specific and frequency-dependent centrifugal modulation in olfactory bulb output neurons in vivo.

Author

Puche, Adam C., Hook, Chelsea, and Zhou, Fu-Wen

Subjects

*OLFACTORY bulb, *GABAERGIC neurons, *NEURONS, *NEURAL circuitry, *INTERNEURONS, *INFERIOR colliculus

Abstract

Mitral/tufted cells (M/TCs) form complex local circuits with interneurons in the olfactory bulb and are powerfully inhibited by these interneurons. The horizontal limb of the diagonal band of Broca (HDB), the only GABAergic/inhibitory source of centrifugal circuit with the olfactory bulb, is known to target olfactory bulb interneurons, and we have shown targeting also to olfactory bulb glutamatergic neurons in vitro. However, the net efficacy of these circuits under different patterns of activation in vivo and the relative balance between the various targeted intact local and centrifugal circuits was the focus of this study. Here channelrhodopsin-2 (ChR2) was expressed in HDB GABAergic neurons to investigate the short-term plasticity of HDB-activated disinhibitory rebound excitation of M/TCs. Optical activation of HDB interneurons increased spontaneous M/TC firing without odor presentation and increased odor-evoked M/TC firing. HDB activation induced disinhibitory rebound excitation (burst or cluster of spiking) in all classes of M/TCs. This excitation was frequency dependent, with short-term facilitation only at higher HDB stimulation frequency (5 Hz and above). However, frequency-dependent HDB regulation was more potent in the deeper layer M/TCs compared with more superficial layer M/TCs. In all neural circuits the balance between inhibition and excitation in local and centrifugal circuits plays a critical functional role, and this patterned input-dependent regulation of inhibitory centrifugal inputs to the olfactory bulb may help maintain the precise balance across the populations of output neurons in different environmental odors, putatively to sharpen the enhancement of tuning specificity of individual or classes of M/TCs to odors. NEW & NOTEWORTHY: Neuronal local circuits in the olfactory bulb are modulated by centrifugal long circuits. In vivo study here shows that inhibitory horizontal limb of the diagonal band of Broca (HDB) modulates all five types of mitral/tufted cells (M/TCs), by direct inhibitory circuits HDB → M/TCs and indirect disinhibitory long circuits HDB → interneurons → M/TCs. The HDB net effect exerts excitation in all types of M/TCs but more powerful in deeper layer output neurons as HDB activation frequency increases, which may sharpen the tuning specificity of classes of M/TCs to odors during sensory processing. [ABSTRACT FROM AUTHOR]

Published

2024

9. Neural Circuits-Adjusted Diagnostic Approach to Predict Recurrence of Atrial Fibrillation

Author

Sidorenko, Ludmila, Sidorenko, Irina, Chornopyshchuk, Roman, Cemortan, Igor, Capcelea, Svetlana, Macaev, Fliur, Rotaru, Ludmila, Badan, Liliana, Wessel, Niels, Magjarević, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Sontea, Victor, editor, Tiginyanu, Ion, editor, and Railean, Serghei, editor

Published

2024

10. Multiscale spatio-temporal dynamics of UBE3A gene in brain physiology and neurodevelopmental disorders

Author

Martina Biagioni, Federica Baronchelli, and Matteo Fossati

Subjects

Neurodevelopmental disorders, Protein ubiquitination, Neuronal circuits, Synapses, Developmental trajectories of disease, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The UBE3A gene, located in the chromosomal region 15q11-13, is subject to neuron-specific genomic imprinting and it plays a critical role in brain development. Genetic defects of UBE3A cause severe neurodevelopmental disorders, namely the Angelman syndrome (AS) and the 15q11.2-q13.3 duplication syndrome (Dup15q). In the last two decades, the development of in vitro and in vivo models of AS and Dup15q were fundamental to improve the understanding of UBE3A function in the brain. However, the pathogenic mechanisms of these diseases remain elusive and effective treatments are lacking. Recent evidence suggests that UBE3A functions are both spatially and temporally specific, varying across subcellular compartments, brain regions, and neuronal circuits. In the present review, we summarize current knowledge on the role of UBE3A in neuronal pathophysiology under this spatio-temporal perspective. Additionally, we propose key research questions that will be instrumental to better understand the pathogenic mechanisms underpinning AS and Dup15q disorders and provide the rationale to develop novel therapies.

Published

2024

11. Increased understanding of complex neuronal circuits in the cerebellar cortex

Author

Soyoung Jun, Heeyoun Park, Muwoong Kim, Seulgi Kang, Taehyeong Kim, Daun Kim, Yukio Yamamoto, and Keiko Tanaka-Yamamoto

Subjects

cerebellar cortex, neuronal circuits, heterogeneity, Purkinje cells, granule cells, molecular layer interneurons, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The prevailing belief has been that the fundamental structures of cerebellar neuronal circuits, consisting of a few major neuron types, are simple and well understood. Given that the cerebellum has long been known to be crucial for motor behaviors, these simple yet organized circuit structures seemed beneficial for theoretical studies proposing neural mechanisms underlying cerebellar motor functions and learning. On the other hand, experimental studies using advanced techniques have revealed numerous structural properties that were not traditionally defined. These include subdivided neuronal types and their circuit structures, feedback pathways from output Purkinje cells, and the multidimensional organization of neuronal interactions. With the recent recognition of the cerebellar involvement in non-motor functions, it is possible that these newly identified structural properties, which are potentially capable of generating greater complexity than previously recognized, are associated with increased information capacity. This, in turn, could contribute to the wide range of cerebellar functions. However, it remains largely unknown how such structural properties contribute to cerebellar neural computations through the regulation of neuronal activity or synaptic transmissions. To promote further research into cerebellar circuit structures and their functional significance, we aim to summarize the newly identified structural properties of the cerebellar cortex and discuss future research directions concerning cerebellar circuit structures and their potential functions.

Published

2024

12. Editorial: Broadening our conceptual understanding of endogenous opioids in systems neuroscience

Author

Tejeda, Hugo A, Massaly, Nicolas, Corder, Gregory, and Cahill, Catherine M

Subjects

opioid peptides, opioid receptors, neuronal circuits, pain, reward, alcohol and substance use disorders, neuromodulation, respiratory depression, Physiology, Neurosciences, Medical Physiology

Published

2023

13. Mouse auditory cortex sub-fields receive neuronal projections from MGB subdivisions independently

Author

Chi Wang, Zhen-yu Jiang, Jian-yuan Chai, Hong-suo Chen, Li-xia Liu, Tong Dang, and Xian-mei Meng

Subjects

Mouse auditory cortex, Neuronal circuits, Belt area, Thalamus projection, Optical imaging, Medicine, Science

Abstract

Abstract Mouse auditory cortex is composed of six sub-fields: primary auditory field (AI), secondary auditory field (AII), anterior auditory field (AAF), insular auditory field (IAF), ultrasonic field (UF) and dorsoposterior field (DP). Previous studies have examined thalamo-cortical connections in the mice auditory system and learned that AI, AAF, and IAF receive inputs from the ventral division of the medial geniculate body (MGB). However, the functional and thalamo-cortical connections between nonprimary auditory cortex (AII, UF, and DP) is unclear. In this study, we examined the locations of neurons projecting to these three cortical sub-fields in the MGB, and addressed the question whether these cortical sub-fields receive inputs from different subsets of MGB neurons or common. To examine the distributions of projecting neurons in the MGB, retrograde tracers were injected into the AII, UF, DP, after identifying these areas by the method of Optical Imaging. Our results indicated that neuron cells which in ventral part of dorsal MGB (MGd) and that of ventral MGB (MGv) projecting to UF and AII with less overlap. And DP only received neuron projecting from MGd. Interestingly, these three cortical areas received input from distinct part of MGd and MGv in an independent manner. Based on our foundings these three auditory cortical sub-fields in mice may independently process auditory information.

Published

2024

14. Mouse auditory cortex sub-fields receive neuronal projections from MGB subdivisions independently.

Author

Wang, Chi, Jiang, Zhen-yu, Chai, Jian-yuan, Chen, Hong-suo, Liu, Li-xia, Dang, Tong, and Meng, Xian-mei

Abstract

Mouse auditory cortex is composed of six sub-fields: primary auditory field (AI), secondary auditory field (AII), anterior auditory field (AAF), insular auditory field (IAF), ultrasonic field (UF) and dorsoposterior field (DP). Previous studies have examined thalamo-cortical connections in the mice auditory system and learned that AI, AAF, and IAF receive inputs from the ventral division of the medial geniculate body (MGB). However, the functional and thalamo-cortical connections between nonprimary auditory cortex (AII, UF, and DP) is unclear. In this study, we examined the locations of neurons projecting to these three cortical sub-fields in the MGB, and addressed the question whether these cortical sub-fields receive inputs from different subsets of MGB neurons or common. To examine the distributions of projecting neurons in the MGB, retrograde tracers were injected into the AII, UF, DP, after identifying these areas by the method of Optical Imaging. Our results indicated that neuron cells which in ventral part of dorsal MGB (MGd) and that of ventral MGB (MGv) projecting to UF and AII with less overlap. And DP only received neuron projecting from MGd. Interestingly, these three cortical areas received input from distinct part of MGd and MGv in an independent manner. Based on our foundings these three auditory cortical sub-fields in mice may independently process auditory information. [ABSTRACT FROM AUTHOR]

Published

2024

15. Environmental experiences shape sexually dimorphic neuronal circuits and behaviour.

Author

Peedikayil‐Kurien, Sonu, Setty, Hagar, and Oren‐Suissa, Meital

Subjects

*SEXUAL selection, *NATURAL selection, *TRANSCRIPTION factors

Abstract

Dimorphic traits, shaped by both natural and sexual selection, ensure optimal fitness and survival of the organism. This includes neuronal circuits that are largely affected by different experiences and environmental conditions. Recent evidence suggests that sexual dimorphism of neuronal circuits extends to different levels such as neuronal activity, connectivity and molecular topography that manifest in response to various experiences, including chemical exposures, starvation and stress. In this review, we propose some common principles that govern experience‐dependent sexually dimorphic circuits in both vertebrate and invertebrate organisms. While sexually dimorphic neuronal circuits are predetermined, they have to maintain a certain level of fluidity to be adaptive to different experiences. The first layer of dimorphism is at the level of the neuronal circuit, which appears to be dictated by sex‐biased transcription factors. This could subsequently lead to differences in the second layer of regulation namely connectivity and synaptic properties. The third regulator of experience‐dependent responses is the receptor level, where dimorphic expression patterns determine the primary sensory encoding. We also highlight missing pieces in this field and propose future directions that can shed light onto novel aspects of sexual dimorphism with potential benefits to sex‐specific therapeutic approaches. Thus, sexual identity and experience simultaneously determine behaviours that ultimately result in the maximal survival success. [ABSTRACT FROM AUTHOR]

Published

2024

16. Fear Learning: An Evolving Picture for Plasticity at Synaptic Afferents to the Amygdala.

Author

Palchaudhuri, Shriya, Osypenko, Denys, and Schneggenburger, Ralf

Subjects

*NEUROPLASTICITY, *AFFERENT pathways, *PARALLEL electric circuits, *AMYGDALOID body, *LONG-term potentiation, *AUDITORY cortex, *NEURAL transmission

Abstract

Unraveling the neuronal mechanisms of fear learning might allow neuroscientists to make links between a learned behavior and the underlying plasticity at specific synaptic connections. In fear learning, an innocuous sensory event such as a tone (called the conditioned stimulus, CS) acquires an emotional value when paired with an aversive outcome (unconditioned stimulus, US). Here, we review earlier studies that have shown that synaptic plasticity at thalamic and cortical afferents to the lateral amygdala (LA) is critical for the formation of auditory-cued fear memories. Despite the early progress, it has remained unclear whether there are separate synaptic inputs that carry US information to the LA to act as a teaching signal for plasticity at CS-coding synapses. Recent findings have begun to fill this gap by showing, first, that thalamic and cortical auditory afferents can also carry US information; second, that the release of neuromodulators contributes to US-driven teaching signals; and third, that synaptic plasticity additionally happens at connections up- and downstream of the LA. Together, a picture emerges in which coordinated synaptic plasticity in serial and parallel circuits enables the formation of a finely regulated fear memory. [ABSTRACT FROM AUTHOR]

Published

2024

17. Genetic context drives age‐related disparities in synaptic maintenance and structure across cortical and hippocampal neuronal circuits.

Author

Heuer, Sarah E., Nickerson, Emily W., Howell, Gareth R., and Bloss, Erik B.

Subjects

*NEURAL circuitry, *COGNITIVE aging, *PYRAMIDAL neurons, *THETA rhythm, *SUCCESSFUL aging, *HIPPOCAMPUS (Brain)

Abstract

The disconnection of neuronal circuitry through synaptic loss is presumed to be a major driver of age‐related cognitive decline. Age‐related cognitive decline is heterogeneous, yet whether genetic mechanisms differentiate successful from unsuccessful cognitive decline through maintenance or vulnerability of synaptic connections remains unknown. Previous work using rodent and primate models leveraged various techniques to imply that age‐related synaptic loss is widespread on pyramidal cells in prefrontal cortex (PFC) circuits but absent on those in area CA1 of the hippocampus. Here, we examined the effect of aging on synapses on projection neurons forming a hippocampal‐cortico‐thalamic circuit important for spatial working memory tasks from two genetically distinct mouse strains that exhibit susceptibility (C57BL/6J) or resistance (PWK/PhJ) to cognitive decline during aging. Across both strains, synapse density on CA1‐to‐PFC projection neurons appeared completely intact with age. In contrast, we found synapse loss on PFC‐to‐nucleus reuniens (RE) projection neurons from aged C57BL/6J but not PWK/PhJ mice. Moreover, synapses from aged PWK/PhJ mice but not from C57BL/6J exhibited altered morphologies that suggest increased efficiency to drive depolarization in the parent dendrite. Our findings suggest resistance to age‐related cognitive decline results in part by age‐related synaptic adaptations, and identification of these mechanisms in PWK/PhJ mice could uncover new therapeutic targets for promoting successful cognitive aging and extending human health span. [ABSTRACT FROM AUTHOR]

Published

2024

18. Thermosensation and Temperature Preference: From Molecules to Neuronal Circuits in Drosophila.

Author

Chiang, Meng-Hsuan, Lin, Yu-Chun, Wu, Tony, and Wu, Chia-Lin

Subjects

*BODY temperature, *DROSOPHILA, *DROSOPHILA melanogaster, *GENE regulatory networks, *TEMPERATURE control, *FRUIT flies

Abstract

Temperature has a significant effect on all physiological processes of animals. Suitable temperatures promote responsiveness, movement, metabolism, growth, and reproduction in animals, whereas extreme temperatures can cause injury or even death. Thus, thermosensation is important for survival in all animals. However, mechanisms regulating thermosensation remain unexplored, mostly because of the complexity of mammalian neural circuits. The fruit fly Drosophila melanogaster achieves a desirable body temperature through ambient temperature fluctuations, sunlight exposure, and behavioral strategies. The availability of extensive genetic tools and resources for studying Drosophila have enabled scientists to unravel the mechanisms underlying their temperature preference. Over the past 20 years, Drosophila has become an ideal model for studying temperature-related genes and circuits. This review provides a comprehensive overview of our current understanding of thermosensation and temperature preference in Drosophila. It encompasses various aspects, such as the mechanisms by which flies sense temperature, the effects of internal and external factors on temperature preference, and the adaptive strategies employed by flies in extreme-temperature environments. Understanding the regulating mechanisms of thermosensation and temperature preference in Drosophila can provide fundamental insights into the underlying molecular and neural mechanisms that control body temperature and temperature-related behavioral changes in other animals. [ABSTRACT FROM AUTHOR]

Published

2023

19. Neuroscience Developments of Concern

Author

Dando, Malcolm and Dando, Malcolm

Published

2023

20. Striatal Dopamine Signals and Reward Learning.

Author

Bech, Pol, Crochet, Sylvain, Dard, Robin, Ghaderi, Parviz, Liu, Yanqi, Malekzadeh, Meriam, Petersen, Carl C H, Pulin, Mauro, Renard, Anthony, and Sourmpis, Christos

Subjects

*DOPAMINERGIC neurons, *REWARD (Psychology), *DOPAMINE, *NEUROPLASTICITY, *ACTION potentials, *ACTION theory (Psychology)

Abstract

We are constantly bombarded by sensory information and constantly making decisions on how to act. In order to optimally adapt behavior, we must judge which sequences of sensory inputs and actions lead to successful outcomes in specific circumstances. Neuronal circuits of the basal ganglia have been strongly implicated in action selection, as well as the learning and execution of goal-directed behaviors, with accumulating evidence supporting the hypothesis that midbrain dopamine neurons might encode a reward signal useful for learning. Here, we review evidence suggesting that midbrain dopaminergic neurons signal reward prediction error, driving synaptic plasticity in the striatum underlying learning. We focus on phasic increases in action potential firing of midbrain dopamine neurons in response to unexpected rewards. These dopamine neurons prominently innervate the dorsal and ventral striatum. In the striatum, the released dopamine binds to dopamine receptors, where it regulates the plasticity of glutamatergic synapses. The increase of striatal dopamine accompanying an unexpected reward activates dopamine type 1 receptors (D1Rs) initiating a signaling cascade that promotes long-term potentiation of recently active glutamatergic input onto striatonigral neurons. Sensorimotor-evoked glutamatergic input, which is active immediately before reward delivery will thus be strengthened onto neurons in the striatum expressing D1Rs. In turn, these neurons cause disinhibition of brainstem motor centers and disinhibition of the motor thalamus, thus promoting motor output to reinforce rewarded stimulus-action outcomes. Although many details of the hypothesis need further investigation, altogether, it seems likely that dopamine signals in the striatum might underlie important aspects of goal-directed reward-based learning. Graphical Abstract [ABSTRACT FROM AUTHOR]

Published

2023

21. Neuronal Circuits Associated with Fear Memory: Potential Therapeutic Targets for Posttraumatic Stress Disorder.

Author

Yan, Yan, Aierken, Ailikemu, Wang, Chunjian, Jin, Wei, Quan, Zhenzhen, Wang, Zhe, Qing, Hong, Ni, Junjun, and Zhao, Juan

Subjects

*POST-traumatic stress disorder, *DRUG target, *EPISODIC memory, *NEURAL circuitry, *MEMORY, *MENTAL illness

Abstract

Posttraumatic stress disorder (PTSD) is a psychiatric disorder that is associated with long-lasting memories of traumatic experiences. Extinction and discrimination of fear memory have become therapeutic targets for PTSD. Newly developed optogenetics and advanced in vivo imaging techniques have provided unprecedented spatiotemporal tools to characterize the activity, connectivity, and functionality of specific cell types in complicated neuronal circuits. The use of such tools has offered mechanistic insights into the exquisite organization of the circuitry underlying the extinction and discrimination of fear memory. This review focuses on the acquisition of more detailed, comprehensive, and integrated neural circuits to understand how the brain regulates the extinction and discrimination of fear memory. A future challenge is to translate these researches into effective therapeutic treatment for PTSD from the perspective of precise regulation of the neural circuits associated with the extinction and discrimination of fear memories. [ABSTRACT FROM AUTHOR]

Published

2023

22. Editorial: Broadening our conceptual understanding of endogenous opioids in systems neuroscience

Author

Hugo A. Tejeda, Nicolas Massaly, Gregory Corder, and Catherine M. Cahill

Subjects

opioid peptides, opioid receptors, neuronal circuits, pain, reward, alcohol and substance use disorders, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2023

23. An Attention Mechanism‐Based Adaptive Feedback Computing Component by Neuromorphic Ion Gated MoS2 Transistors.

Author

Liu, Chang, Wang, Yanghao, Zhang, Teng, Yuan, Rui, and Yang, Yuchao

Subjects

ADAPTIVE computing systems, INFORMATION filtering systems, COMPUTER systems, BIOLOGICALLY inspired computing, COGNITIVE computing, MACHINE learning, TRANSISTORS

Abstract

Neuromorphic computing is expected to bridge cognitive behaviors with computing systems in an efficient, expandable, and biologically inspired way. A pivotal cognitive behavior is the attention mechanism, which is highly important in filtering and regulating spatio‐temporal information. Emerging neuromorphic devices hold prospect in utilizing their internal physical mechanisms for dynamic computing resources. Here, a basic top–down attention computing component consisting of a synaptic transistor and a neuron is proposed, where efficient information processing is realized by combining the inherent device dynamics and the feedback loop. A theoretical model is established in simulation to demonstrate the capabilities of such a computing system in information filtering and control. Notably, new dynamic circuit behaviors, such as conductance oscillation and activate function switching, are discovered from appropriate time parameters. The attention computing component contains rich dynamic behaviors, providing a power and area‐saving method to construct high‐complexity neuromorphic systems for spatio‐temporal signal preprocessing and control. [ABSTRACT FROM AUTHOR]

Published

2023

24. The role of the prefrontal cortex in modulating aggression in humans and rodents.

Author

Li, Xinyang, Xiong, Lize, and Li, Yan

Subjects

*ANIMAL aggression, *PREFRONTAL cortex, *HUMAN anatomy, *AGGRESSION (Psychology), *MENTAL illness

Abstract

Accumulating evidence suggests that the prefrontal cortex (PFC) plays an important role in aggression. However, the findings regarding the key neural mechanisms and molecular pathways underlying the modulation of aggression by the PFC are relatively scattered, with many inconsistencies and areas that would benefit from exploration. Here, we highlight the relationship between the PFC and aggression in humans and rodents and describe the anatomy and function of the human PFC, along with homologous regions in rodents. At the molecular level, we detail how the major neuromodulators of the PFC impact aggression. At the circuit level, this review provides an overview of known and potential subcortical projections that regulate aggression in rodents. Finally, at the disease level, we review the correlation between PFC alterations and heightened aggression in specific human psychiatric disorders. Our review provides a framework for PFC modulation of aggression, resolves several intriguing paradoxes from previous studies, and illuminates new avenues for further study. • This review outlines the molecular mechanisms underlying the regulation of aggression by neuromodulators in the PFC. • We provide a circuit-level assessment of the known and predicted cortico-subcortical projections for regulating aggression. • We describe the relationship between the PFC and aggression in human psychiatric disorders associated with aggression. [ABSTRACT FROM AUTHOR]

Published

2025

25. History and future of leptin: Discovery, regulation and signaling.

Author

Münzberg, Heike, Heymsfield, Steven B., Berthoud, Hans-Rudolf, and Morrison, Christopher D.

Subjects

LEPTIN receptors, CENTRAL nervous system, LEPTIN, OBESITY, MOLECULAR cloning, GENE expression

Abstract

The cloning of leptin 30 years ago in 1994 was an important milestone in obesity research. Prior to the discovery of leptin, obesity was stigmatized as a condition caused by lack of character and self-control. Mutations in either leptin or its receptor were the first single gene mutations found to cause severe obesity, and it is now recognized that obesity is caused mostly by a dysregulation of central neuronal circuits. Since the discovery of the leptin-deficient obese mouse (ob/ob) the cloning of leptin (ob aka lep) and leptin receptor (db aka lepr) genes, we have learned much about leptin and its action in the central nervous system. The first hope that leptin would cure obesity was quickly dampened because humans with obesity have increased leptin levels and develop leptin resistance. Nevertheless, leptin target sites in the brain represent an excellent blueprint to understand how neuronal circuits control energy homeostasis. Our expanding understanding of leptin function, interconnection of leptin signaling with other systems and impact on distinct physiological functions continues to guide and improve the development of safe and effective interventions to treat metabolic illnesses. This review highlights past concepts and current emerging concepts of the hormone leptin, leptin receptor signaling pathways and central targets to mediate distinct physiological functions. • Physiological and obesity related changes in leptin gene expression • Mechanisms of CNS leptin access and known impacts for obesity • Leptin receptor signaling events and impact in leptin resistance for whole body energy homeostasis • Function-specific circuits of Lepr-expressing neurons and their role in energy and glucose homeostasis [ABSTRACT FROM AUTHOR]

Published

2024

26. An Attention Mechanism‐Based Adaptive Feedback Computing Component by Neuromorphic Ion Gated MoS2 Transistors

Author

Chang Liu, Yanghao Wang, Teng Zhang, Rui Yuan, and Yuchao Yang

Subjects

attention mechanism, neuromorphic computing, neuronal circuits, synapse transistor, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4, Physics, QC1-999

Abstract

Abstract Neuromorphic computing is expected to bridge cognitive behaviors with computing systems in an efficient, expandable, and biologically inspired way. A pivotal cognitive behavior is the attention mechanism, which is highly important in filtering and regulating spatio‐temporal information. Emerging neuromorphic devices hold prospect in utilizing their internal physical mechanisms for dynamic computing resources. Here, a basic top–down attention computing component consisting of a synaptic transistor and a neuron is proposed, where efficient information processing is realized by combining the inherent device dynamics and the feedback loop. A theoretical model is established in simulation to demonstrate the capabilities of such a computing system in information filtering and control. Notably, new dynamic circuit behaviors, such as conductance oscillation and activate function switching, are discovered from appropriate time parameters. The attention computing component contains rich dynamic behaviors, providing a power and area‐saving method to construct high‐complexity neuromorphic systems for spatio‐temporal signal preprocessing and control.

Published

2023

27. The Superior Colliculus: Cell Types, Connectivity, and Behavior.

Author

Liu, Xue, Huang, Hongren, Snutch, Terrance P., Cao, Peng, Wang, Liping, and Wang, Feng

Abstract

The superior colliculus (SC), one of the most well-characterized midbrain sensorimotor structures where visual, auditory, and somatosensory information are integrated to initiate motor commands, is highly conserved across vertebrate evolution. Moreover, cell-type-specific SC neurons integrate afferent signals within local networks to generate defined output related to innate and cognitive behaviors. This review focuses on the recent progress in understanding of phenotypic diversity amongst SC neurons and their intrinsic circuits and long-projection targets. We further describe relevant neural circuits and specific cell types in relation to behavioral outputs and cognitive functions. The systematic delineation of SC organization, cell types, and neural connections is further put into context across species as these depend upon laminar architecture. Moreover, we focus on SC neural circuitry involving saccadic eye movement, and cognitive and innate behaviors. Overall, the review provides insight into SC functioning and represents a basis for further understanding of the pathology associated with SC dysfunction. [ABSTRACT FROM AUTHOR]

Published

2022

28. Genetically Encoded Voltage Indicators

Author

Mollinedo-Gajate, Irene, Song, Chenchen, Knöpfel, Thomas, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Yawo, Hiromu, editor, Kandori, Hideki, editor, Koizumi, Amane, editor, and Kageyama, Ryoichiro, editor

Published

2021

29. A striatal circuit balances learned fear in the presence and absence of sensory cues

Author

Michael Kintscher, Olexiy Kochubey, and Ralf Schneggenburger

Subjects

fear memory, neuronal circuits, striatum, calcium imaging, synaptic plasticity, freezing behavior, Medicine, Science, Biology (General), QH301-705.5

Abstract

During fear learning, defensive behaviors like freezing need to be finely balanced in the presence or absence of threat-predicting cues (conditioned stimulus, CS). Nevertheless, the circuits underlying such balancing are largely unknown. Here, we investigate the role of the ventral tail striatum (vTS) in auditory-cued fear learning of male mice. In vivo Ca2+ imaging showed that sizable sub-populations of direct (D1R+) and indirect pathway neurons (Adora+) in the vTS responded to footshocks, and to the initiation of movements after freezing; moreover, a sub-population of D1R+ neurons increased its responsiveness to an auditory CS during fear learning. In-vivo optogenetic silencing shows that footshock-driven activity of D1R+ neurons contributes to fear memory formation, whereas Adora+ neurons modulate freezing in the absence of a learned CS. Circuit tracing identified the posterior insular cortex (pInsCx) as an important cortical input to the vTS, and recording of optogenetically evoked EPSCs revealed long-term plasticity with opposite outcomes at the pInsCx synapses onto D1R+ - and Adora+ neurons. Thus, direct- and indirect pathways neurons of the vTS show differential signs of plasticity after fear learning, and balance defensive behaviors in the presence and absence of learned sensory cues.

Published

2023

30. Mechanisms Underlying Circuit Dysfunction in Neurodevelopmental Disorders.

Author

Exposito-Alonso, David and Rico, Beatriz

Abstract

Recent advances in genomics have revealed a wide spectrum of genetic variants associated with neurodevelopmental disorders at an unprecedented scale. An increasing number of studies have consistently identified mutations—both inherited and de novo—impacting the function of specific brain circuits. This suggests that, during brain development, alterations in distinct neural circuits, cell types, or broad regulatory pathways ultimately shaping synapses might be a dysfunctional process underlying these disorders. Here, we review findings from human studies and animal model research to provide a comprehensive description of synaptic and circuit mechanisms implicated in neurodevelopmental disorders. We discuss how specific synaptic connections might be commonly disrupted in different disorders and the alterations in cognition and behaviors emerging from imbalances in neuronal circuits. Moreover, we review new approaches that have been shown to restore or mitigate dysfunctional processes during specific critical windows of brain development. Considering the heterogeneity of neurodevelopmental disorders, we also highlight the recent progress in developing improved clinical biomarkers and strategies that will help to identify novel therapeutic compounds and opportunities for early intervention. [ABSTRACT FROM AUTHOR]

Published

2022

31. Editorial: Broadening our conceptual understanding of endogenous opioids in systems neuroscience.

Author

Tejeda, Hugo A., Massaly, Nicolas, Corder, Gregory, and Cahill, Catherine M.

Subjects

OPIOID peptides, ALCOHOLISM, NEUROSCIENCES, OPIOID receptors

Published

2023

32. The Neural Circuit Architecture of Social Hierarchy in Rodents and Primates.

Author

Ferreira-Fernandes, Emanuel and Peça, João

Subjects

POWER (Social sciences), SOCIAL hierarchies, SOCIAL status, SYNAPSES, ARTIFICIAL neural networks, PREFRONTAL cortex

Abstract

Social status is recognized as a major determinant of social behavior and health among animals; however, the neural circuits supporting the formation and navigation of social hierarchies remain under extensive research. Available evidence suggests the prefrontal cortex is a keystone in this circuit, but upstream and downstream candidates are progressively emerging. In this review, we compare and integrate findings from rodent and primate studies to create a model of the neural and cellular networks supporting social hierarchies, both from a macro (i.e., circuits) to a micro-scale perspective (microcircuits and synapses). We start by summarizing the literature on the prefrontal cortex and other relevant brain regions to expand the current "prefrontal-centric" view of social hierarchy behaviors. Based on connectivity data we also discuss candidate regions that might inspire further investigation, as well as the caveats and strategies that have been used to further our understanding of the biological substrates underpinning social hierarchy and dominance. [ABSTRACT FROM AUTHOR]

Published

2022

33. Rhythmic Memory Consolidation in the Hippocampus.

Author

Nokia, Miriam S. and Penttonen, Markku

Subjects

NEURAL circuitry, EXPLICIT memory, MEMORY, HIPPOCAMPUS (Brain), THALAMUS, NEOCORTEX

Abstract

Functions of the brain and body are oscillatory in nature and organized according to a logarithmic scale. Brain oscillations and bodily functions such as respiration and heartbeat appear nested within each other and coupled together either based on phase or based on phase and amplitude. This facilitates communication in wide-spread neuronal networks and probably also between the body and the brain. It is a widely accepted view, that nested electrophysiological brain oscillations involving the neocortex, thalamus, and the hippocampus form the basis of memory consolidation. This applies especially to declarative memories, that is, memories of life events, for example. Here, we present our view of hippocampal contribution to the process of memory consolidation based on the general ideas stated above and on some recent findings on the topic by us and by other research groups. We propose that in addition to the interplay between neocortical slow oscillations, spindles, and hippocampal sharp-wave ripples during sleep, there are also additional mechanisms available in the hippocampus to control memory consolidation: a rather non-oscillatory hippocampal electrophysiological phenomenon called the dentate spike might provide a means to not only consolidate but to also modify the neural representation of declarative memories. Further, we suggest that memory consolidation in the hippocampus might be in part paced by breathing. These considerations might open new possibilities for regulating memory consolidation in rest and sleep. [ABSTRACT FROM AUTHOR]

Published

2022

34. Excitatory and Inhibitory Neurons of the Spinal Cord Superficial Dorsal Horn Diverge in Their Somatosensory Responses and Plasticity in Vivo.

Author

Sullivan, Steve J. and Sdrulla, Andrei D.

Subjects

*SPINAL cord, *NEURONS, *INTERNEURONS, *GLYCINE receptors, *NEUROPEPTIDES

Abstract

The superficial dorsal horn (SDH) of the spinal cord represents the first site of integration between innocuous and noxious somatosensory stimuli. According to gate control theory, diverse populations of excitatory and inhibitory interneurons within the SDH are activated by distinct sensory afferents, and their interplay determines the net nociceptive output projecting to higher pain centers. Although specific SDH cell types are ill defined, numerous classifications schemes find that excitatory and inhibitory neurons fundamentally differ in their morphology, electrophysiology, neuropeptides, and pain-associated plasticity; yet little is known about how these neurons respond over a range of natural innocuous and noxious stimuli. To address this question, we applied an in vivo imaging approach in male mice where the genetically encoded calcium indicator GCaMP6s was expressed either in vGluT2-positive excitatory or vIAAT-positive inhibitory neurons. We found that inhibitory neurons were markedly more sensitive to innocuous touch than excitatory neurons but still responded dynamically over a wide range of noxious mechanical stimuli. Inhibitory neurons were also less sensitive to thermal stimuli than their excitatory counterparts. In a capsaicin model of acute pain sensitization, the responses of excitatory neurons were significantly potentiated to innocuous and noxious mechanical stimuli, whereas inhibitory neural responses were only depressed to noxious stimuli. These in vivo findings show that excitatory and inhibitory SDH neurons diverge considerably in their somatosensory responses and plasticity, as postulated by gate control theory. [ABSTRACT FROM AUTHOR]

Published

2022

35. The Neural Circuit Architecture of Social Hierarchy in Rodents and Primates

Author

Emanuel Ferreira-Fernandes and João Peça

Subjects

social hierarchies, neuronal circuits, dominance, status syndrome, microcircuitry, social status, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Social status is recognized as a major determinant of social behavior and health among animals; however, the neural circuits supporting the formation and navigation of social hierarchies remain under extensive research. Available evidence suggests the prefrontal cortex is a keystone in this circuit, but upstream and downstream candidates are progressively emerging. In this review, we compare and integrate findings from rodent and primate studies to create a model of the neural and cellular networks supporting social hierarchies, both from a macro (i.e., circuits) to a micro-scale perspective (microcircuits and synapses). We start by summarizing the literature on the prefrontal cortex and other relevant brain regions to expand the current “prefrontal-centric” view of social hierarchy behaviors. Based on connectivity data we also discuss candidate regions that might inspire further investigation, as well as the caveats and strategies that have been used to further our understanding of the biological substrates underpinning social hierarchy and dominance.

Published

2022

36. Rhythmic Memory Consolidation in the Hippocampus

Author

Miriam S. Nokia and Markku Penttonen

Subjects

electrophysiology, respiration, brain oscillations, sleep, neuronal circuits, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Functions of the brain and body are oscillatory in nature and organized according to a logarithmic scale. Brain oscillations and bodily functions such as respiration and heartbeat appear nested within each other and coupled together either based on phase or based on phase and amplitude. This facilitates communication in wide-spread neuronal networks and probably also between the body and the brain. It is a widely accepted view, that nested electrophysiological brain oscillations involving the neocortex, thalamus, and the hippocampus form the basis of memory consolidation. This applies especially to declarative memories, that is, memories of life events, for example. Here, we present our view of hippocampal contribution to the process of memory consolidation based on the general ideas stated above and on some recent findings on the topic by us and by other research groups. We propose that in addition to the interplay between neocortical slow oscillations, spindles, and hippocampal sharp-wave ripples during sleep, there are also additional mechanisms available in the hippocampus to control memory consolidation: a rather non-oscillatory hippocampal electrophysiological phenomenon called the dentate spike might provide a means to not only consolidate but to also modify the neural representation of declarative memories. Further, we suggest that memory consolidation in the hippocampus might be in part paced by breathing. These considerations might open new possibilities for regulating memory consolidation in rest and sleep.

Published

2022

37. Recurrent Excitatory Feedback From Mossy Cells Enhances Sparsity and Pattern Separation in the Dentate Gyrus via Indirect Feedback Inhibition

Author

Alessandro R. Galloni, Aya Samadzelkava, Kiran Hiremath, Reuben Oumnov, and Aaron D. Milstein

Subjects

neuronal circuits, computational modeling, dentate gyrus, pattern separation, sparse coding, mossy cells, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

It is generally appreciated that storing memories of specific events in the mammalian brain, and associating features of the environment with behavioral outcomes requires fine-tuning of the strengths of connections between neurons through synaptic plasticity. It is less understood whether the organization of neuronal circuits comprised of multiple distinct neuronal cell types provides an architectural prior that facilitates learning and memory by generating unique patterns of neuronal activity in response to different stimuli in the environment, even before plasticity and learning occur. Here we simulated a neuronal network responding to sensory stimuli, and systematically determined the effects of specific neuronal cell types and connections on three key metrics of neuronal sensory representations: sparsity, selectivity, and discriminability. We found that when the total amount of input varied considerably across stimuli, standard feedforward and feedback inhibitory circuit motifs failed to discriminate all stimuli without sacrificing sparsity or selectivity. Interestingly, networks that included dedicated excitatory feedback interneurons based on the mossy cells of the hippocampal dentate gyrus exhibited improved pattern separation, a result that depended on the indirect recruitment of feedback inhibition. These results elucidate the roles of cellular diversity and neural circuit architecture on generating neuronal representations with properties advantageous for memory storage and recall.

Published

2022

38. Recurrent Excitatory Feedback From Mossy Cells Enhances Sparsity and Pattern Separation in the Dentate Gyrus via Indirect Feedback Inhibition.

Author

Galloni, Alessandro R., Samadzelkava, Aya, Hiremath, Kiran, Oumnov, Reuben, and Milstein, Aaron D.

Subjects

DENTATE gyrus, INTERNEURONS, NEURAL circuitry, NEUROPLASTICITY, HIPPOCAMPUS (Brain), NEURONS, STIMULUS & response (Psychology)

Abstract

It is generally appreciated that storing memories of specific events in the mammalian brain, and associating features of the environment with behavioral outcomes requires fine-tuning of the strengths of connections between neurons through synaptic plasticity. It is less understood whether the organization of neuronal circuits comprised of multiple distinct neuronal cell types provides an architectural prior that facilitates learning and memory by generating unique patterns of neuronal activity in response to different stimuli in the environment, even before plasticity and learning occur. Here we simulated a neuronal network responding to sensory stimuli, and systematically determined the effects of specific neuronal cell types and connections on three key metrics of neuronal sensory representations: sparsity, selectivity, and discriminability. We found that when the total amount of input varied considerably across stimuli, standard feedforward and feedback inhibitory circuit motifs failed to discriminate all stimuli without sacrificing sparsity or selectivity. Interestingly, networks that included dedicated excitatory feedback interneurons based on the mossy cells of the hippocampal dentate gyrus exhibited improved pattern separation, a result that depended on the indirect recruitment of feedback inhibition. These results elucidate the roles of cellular diversity and neural circuit architecture on generating neuronal representations with properties advantageous for memory storage and recall. [ABSTRACT FROM AUTHOR]

Published

2022

39. Neuronal circuits and reinforcement mechanisms underlying feeding behaviour

Author

Huang Cao, Zhen Fang

Subjects

612.8, Feeding behaviour, AGRP, Leptin, Reinforcement, Neuronal circuits

Abstract

Animal survival depends on the brain’s ability to detect the energetic state of the body and to alter behaviour in order to maintain homeostasis. Current research in the control of food consumption stresses the importance of identifying and establishing the specific roles of homeostatic neurons, which sense the body’s energetic state and elicit complex and flexible food seeking behaviours. Recent developments in optogenetics, molecular genetics, and anatomical techniques have made these investigations possible at the resolution of specific cell types and circuits. These neurons are of particular interest because they serve as key entry points to the identification of downstream circuits and reinforcement mechanisms that control feeding behaviour. This dissertation probes the role of two kinds of homeostatic neurons— agouti-related peptide (AGRP) in the arcuate nucleus (ARC) and leptin receptor (LepRb) neurons in the lateral hypothalamic area (LHA)—in the control of food intake. First, I examined the role of LepRb neurons in the LHA in feeding. Results from electrophysiological studies indicate that these neurons consist of a subpopulation of homeostatic sensing LHA γ-aminobutyric acid (GABA) expressing neurons. In addition to their response to leptin, these neurons are capable of modulating their activity in response to changes in glucose levels, further substantiating their role as homeostatic sensing neurons. Behavioural studies using optogenetic activation of these neurons show that their elevated activity is capable of reducing body weight, although their role in modulating feeding remains unclear. Second, I investigated the reinforcement mechanisms employed by AGRP neurons to elicit voracious food consumption and increased willingness to work for food. Conditioned place avoidance studies under optogenetic activation of AGRP neurons reveal that their increased activity has negative valence and is avoided. In addition, imposition of elevated AGRP neuron activity in an operant task reduced instrumental food seeking with particular sensitivity under high effort requirements. Taken together, these results suggest that AGRP neurons employ a negative reinforcement teaching signal to direct action selection during food seeking and consumption. Third, I systematically analyzed the contribution of specific AGRP neuron projection subpopulations in AGRP neuron mediated evoked-feeding behaviour. Optogenetic activation studies of AGRP neuron axons in downstream projection regions indicate that several, but not all, subpopulations are capable of independently evoke food consumption. This work reveals a parallel and redundant functional circuit organization for AGRP neurons in the control of food intake. Interestingly, all AGRP neuron subpopulations examined displayed similar modulation by states of energy deficit and signals of starvation, despite their apparent divergence in function. As a whole, this dissertation extends our understanding of the role of homeostatic neurons in food consumption and uncovers previously unappreciated functional organization and reinforcement mechanisms employed by neuronal circuits that control feeding behaviour.

Published

2015

40. Microglia Regulate Neuronal Circuits in Homeostatic and High-Fat Diet-Induced Inflammatory Conditions

Author

Xiao-Lan Wang and Lianjian Li

Subjects

microglia, cognition, obesity, neuronal circuits, phagocytosis, inflammation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Microglia are brain resident macrophages, which actively survey the surrounding microenvironment and promote tissue homeostasis under physiological conditions. During this process, microglia participate in synaptic remodeling, neurogenesis, elimination of unwanted neurons and cellular debris. The complex interplay between microglia and neurons drives the formation of functional neuronal connections and maintains an optimal neural network. However, activation of microglia induced by chronic inflammation increases synaptic phagocytosis and leads to neuronal impairment or death. Microglial dysfunction is implicated in almost all brain diseases and leads to long-lasting functional deficiency, such as hippocampus-related cognitive decline and hypothalamus-associated energy imbalance (i.e., obesity). High-fat diet (HFD) consumption triggers mediobasal hypothalamic microglial activation and inflammation. Moreover, HFD-induced inflammation results in cognitive deficits by triggering hippocampal microglial activation. Here, we have summarized the current knowledge of microglial characteristics and biological functions and also reviewed the molecular mechanism of microglia in shaping neural circuitries mainly related to cognition and energy balance in homeostatic and diet-induced inflammatory conditions.

Published

2021

41. Respiration-Driven Brain Oscillations in Emotional Cognition.

Author

Folschweiller, Shani and Sauer, Jonas-Frederic

Subjects

COGNITIVE ability, OSCILLATIONS, COGNITION, ACTION potentials, RESPIRATION

Abstract

Respiration paces brain oscillations and the firing of individual neurons, revealing a profound impact of rhythmic breathing on brain activity. Intriguingly, respiration-driven entrainment of neural activity occurs in a variety of cortical areas, including those involved in higher cognitive functions such as associative neocortical regions and the hippocampus. Here we review recent findings of respiration-entrained brain activity with a particular focus on emotional cognition. We summarize studies from different brain areas involved in emotional behavior such as fear, despair, and motivation, and compile findings of respiration-driven activities across species. Furthermore, we discuss the proposed cellular and network mechanisms by which cortical circuits are entrained by respiration. The emerging synthesis from a large body of literature suggests that the impact of respiration on brain function is widespread across the brain and highly relevant for distinct cognitive functions. These intricate links between respiration and cognitive processes call for mechanistic studies of the role of rhythmic breathing as a timing signal for brain activity. [ABSTRACT FROM AUTHOR]

Published

2021

42. Microglia Regulate Neuronal Circuits in Homeostatic and High-Fat Diet-Induced Inflammatory Conditions.

Author

Wang, Xiao-Lan and Li, Lianjian

Subjects

MICROGLIA, PHAGOCYTOSIS, HIGH-fat diet, NEURAL circuitry, BRAIN diseases, HOMEOSTASIS, HIPPOCAMPUS (Brain), HYPOTHALAMUS

Abstract

Microglia are brain resident macrophages, which actively survey the surrounding microenvironment and promote tissue homeostasis under physiological conditions. During this process, microglia participate in synaptic remodeling, neurogenesis, elimination of unwanted neurons and cellular debris. The complex interplay between microglia and neurons drives the formation of functional neuronal connections and maintains an optimal neural network. However, activation of microglia induced by chronic inflammation increases synaptic phagocytosis and leads to neuronal impairment or death. Microglial dysfunction is implicated in almost all brain diseases and leads to long-lasting functional deficiency, such as hippocampus-related cognitive decline and hypothalamus-associated energy imbalance (i.e., obesity). High-fat diet (HFD) consumption triggers mediobasal hypothalamic microglial activation and inflammation. Moreover, HFD-induced inflammation results in cognitive deficits by triggering hippocampal microglial activation. Here, we have summarized the current knowledge of microglial characteristics and biological functions and also reviewed the molecular mechanism of microglia in shaping neural circuitries mainly related to cognition and energy balance in homeostatic and diet-induced inflammatory conditions. [ABSTRACT FROM AUTHOR]

Published

2021

43. Locus coeruleus-norepinephrine: basic functions and insights into Parkinson’s disease

Author

Bilal Abdul Bari, Varun Chokshi, and Katharina Schmidt

Subjects

catecholamines, copper, neurodegenerative diseases, neuromodulation, neuronal circuits, neuropsychiatric symptoms, noradrenaline, synaptic plasticity, Neurology. Diseases of the nervous system, RC346-429

Abstract

The locus coeruleus is a pontine nucleus that produces much of the brain’s norepinephrine. Despite its small size, the locus coeruleus is critical for a myriad of functions and is involved in many neurodegenerative and neuropsychiatric disorders. In this review, we discuss the physiology and anatomy of the locus coeruleus system and focus on norepinephrine’s role in synaptic plasticity. We highlight Parkinson’s disease as a disorder with motor and neuropsychiatric symptoms that may be understood as aberrations in the normal functions of locus coeruleus.

Published

2020

44. Lateral hypothalamic LEPR neurons drive appetitive but not consummatory behaviors

Author

Justin N. Siemian, Miguel A. Arenivar, Sarah Sarsfield, Cara B. Borja, Charity N. Russell, and Yeka Aponte

Subjects

lateral hypothalamus, neuronal circuits, ventral tegmental area, leptin receptor, appetitive behaviors, consummatory behaviors, Biology (General), QH301-705.5

Abstract

Summary: Assigning behavioral roles to genetically defined neurons within the lateral hypothalamus (LH) is an ongoing challenge. We demonstrate that a subpopulation of LH GABAergic neurons expressing leptin receptors (LHLEPR) specifically drives appetitive behaviors in mice. Ablation of LH GABAergic neurons (LHVGAT) decreases weight gain and food intake, whereas LHLEPR ablation does not. Appetitive learning in a Pavlovian conditioning paradigm is delayed in LHVGAT-ablated mice but prevented entirely in LHLEPR-ablated mice. Both LHVGAT and LHLEPR neurons bidirectionally modulate reward-related behaviors, but only LHVGAT neurons affect feeding. In the Pavlovian paradigm, only LHLEPR activity discriminates between conditioned cues. Optogenetic activation or inhibition of either population in this task disrupts discrimination. However, manipulations of LHLEPR→VTA projections evoke divergent effects on responding. Unlike food-oriented learning, chemogenetic inhibition of LHLEPR neurons does not alter cocaine-conditioned place preference but attenuates cocaine sensitization. Thus, LHLEPR neurons may specifically regulate appetitive behaviors toward non-drug reinforcers.

Published

2021

45. Urocortin-3 neurons in the mouse perifornical area promote infant-directed neglect and aggression

Author

Anita E Autry, Zheng Wu, Vikrant Kapoor, Johannes Kohl, Dhananjay Bambah-Mukku, Nimrod D Rubinstein, Brenda Marin-Rodriguez, Ilaria Carta, Victoria Sedwick, Ming Tang, and Catherine Dulac

Subjects

parenting, aggression, neuronal circuits, social behavior, infanticide, hypothalamus, Medicine, Science, Biology (General), QH301-705.5

Abstract

While recent studies have uncovered dedicated neural pathways mediating the positive control of parenting, the regulation of infant-directed aggression and how it relates to adult-adult aggression is poorly understood. Here we show that urocortin-3 (Ucn3)-expressing neurons in the hypothalamic perifornical area (PeFAUcn3) are activated during infant-directed attacks in males and females, but not other behaviors. Functional manipulations of PeFAUcn3 neurons demonstrate the role of this population in the negative control of parenting in both sexes. PeFAUcn3 neurons receive input from areas associated with vomeronasal sensing, stress, and parenting, and send projections to hypothalamic and limbic areas. Optogenetic activation of PeFAUcn3 axon terminals in these regions triggers various aspects of infant-directed agonistic responses, such as neglect, repulsion, and aggression. Thus, PeFAUcn3 neurons emerge as a dedicated circuit component controlling infant-directed neglect and aggression, providing a new framework to understand the positive and negative regulation of parenting in health and disease.

Published

2021

46. Neuromodulation and Behavioral Flexibility in Larval Zebrafish: From Neurotransmitters to Circuits

Author

Laura Corradi and Alessandro Filosa

Subjects

zebrafish, neuromodulation, behavior, neuronal circuits, flexibility, foraging, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Animals adapt their behaviors to their ever-changing needs. Internal states, such as hunger, fear, stress, and arousal are important behavioral modulators controlling the way an organism perceives sensory stimuli and reacts to them. The translucent zebrafish larva is an ideal model organism for studying neuronal circuits regulating brain states, owning to the possibility of easy imaging and manipulating activity of genetically identified neurons while the animal performs stereotyped and well-characterized behaviors. The main neuromodulatory circuits present in mammals can also be found in the larval zebrafish brain, with the advantage that they contain small numbers of neurons. Importantly, imaging and behavioral techniques can be combined with methods for generating targeted genetic modifications to reveal the molecular underpinnings mediating the functions of such circuits. In this review we discuss how studying the larval zebrafish brain has contributed to advance our understanding of circuits and molecular mechanisms regulating neuromodulation and behavioral flexibility.

Published

2021

47. Chronic Stress Induces Sex-Specific Functional and Morphological Alterations in Corticoaccumbal and Corticotegmental Pathways.

Author

Bittar, Thibault P., Pelaez, Mari Carmen, Hernandez Silva, Jose Cesar, Quessy, Francis, Lavigne, Andrée-Anne, Morency, Daphnée, Blanchette, Léa-Jeanne, Arsenault, Eric, Cherasse, Yoan, Seigneur, Josée, Timofeev, Igor, Sephton, Chantelle F., Proulx, Christophe D., and Labonté, Benoit

Subjects

*PSYCHOLOGICAL stress, *NUCLEUS accumbens, *PREFRONTAL cortex

Abstract

The medial prefrontal cortex (mPFC) is part of a complex circuit controlling stress responses by sending projections to different limbic structures including the nucleus accumbens (NAc) and ventral tegmental area (VTA). However, the impact of chronic stress on NAc- and VTA-projecting mPFC neurons is still unknown, and the distinct contribution of these pathways to stress responses in males and females is unclear. Behavioral stress responses were induced by 21 days of chronic variable stress in male and female C57BL/6NCrl mice. An intersectional viral approach was used to label both pathways and assess the functional, morphological, and transcriptional adaptations in NAc- and VTA-projecting mPFC neurons in stressed males and females. Using chemogenetic approaches, we modified neuronal activity of NAc-projecting mPFC neurons to decipher their contribution to stress phenotypes. Chronic variable stress induced depressive-like behaviors in males and females. NAc- and VTA-projecting mPFC neurons exhibited sex-specific functional, morphological, and transcriptional alterations. The functional changes were more severe in females in NAc-projecting mPFC neurons, while males exhibited more drastic reductions in dendritic complexity in VTA-projecting mPFC neurons after chronic variable stress. Finally, chemogenetic overactivation of the corticoaccumbal pathway triggered anxiety and behavioral despair in both sexes, while its inhibition rescued the phenotype only in females. Our results suggest that stress responses in males and females result from pathway-specific changes in the activity of transcriptional programs controlling the morphological and synaptic properties of corticoaccumbal and corticotegmental pathways in a sex-specific fashion. [ABSTRACT FROM AUTHOR]

Published

2021

48. Spatial organization and transitions of spontaneous neuronal activities in the developing sensory cortex.

Author

Nakazawa, Shingo and Iwasato, Takuji

Subjects

*PERCEIVED control (Psychology), *ORGANIZATION

Abstract

The sensory cortex underlies our ability to perceive and interact with the external world. Sensory perceptions are controlled by specialized neuronal circuits established through fine‐tuning, which relies largely on neuronal activity during the development. Spontaneous neuronal activity is an essential driving force of neuronal circuit refinement. At early developmental stages, sensory cortices display spontaneous activities originating from the periphery and characterized by correlated firing arranged spatially according to the modality. The firing patterns are reorganized over time and become sparse, which is typical for the mature brain. This review focuses mainly on rodent sensory cortices. First, the features of the spontaneous activities during early postnatal stages are described. Then, the developmental changes in the spatial organization of the spontaneous activities and the transition mechanisms involved are discussed. The identification of the principles controlling the spatial organization of spontaneous activities in the developing sensory cortex is essential to understand the self‐organization process of neuronal circuits. This review aims to provide an integrated overview of the spatial organization of the neuronal spontaneous activity in sensory cortices with a focus on recent studies. [ABSTRACT FROM AUTHOR]

Published

2021

49. Neuromodulation and Behavioral Flexibility in Larval Zebrafish: From Neurotransmitters to Circuits.

Author

Corradi, Laura and Filosa, Alessandro

Subjects

ANIMAL behavior, NEUROMODULATION, BRACHYDANIO, NEUROTRANSMITTERS

Abstract

Animals adapt their behaviors to their ever-changing needs. Internal states, such as hunger, fear, stress, and arousal are important behavioral modulators controlling the way an organism perceives sensory stimuli and reacts to them. The translucent zebrafish larva is an ideal model organism for studying neuronal circuits regulating brain states, owning to the possibility of easy imaging and manipulating activity of genetically identified neurons while the animal performs stereotyped and well-characterized behaviors. The main neuromodulatory circuits present in mammals can also be found in the larval zebrafish brain, with the advantage that they contain small numbers of neurons. Importantly, imaging and behavioral techniques can be combined with methods for generating targeted genetic modifications to reveal the molecular underpinnings mediating the functions of such circuits. In this review we discuss how studying the larval zebrafish brain has contributed to advance our understanding of circuits and molecular mechanisms regulating neuromodulation and behavioral flexibility. [ABSTRACT FROM AUTHOR]

Published

2021

50. Neural circuits and activity dynamics underlying sex-specific effects of chronic social isolation stress

Author

Tao Tan, Wei Wang, Tiaotiao Liu, Ping Zhong, Megan Conrow-Graham, Xin Tian, and Zhen Yan

Subjects

social isolation stress, aggression, social withdrawal, in vivo recording, chemogenetics, neuronal circuits, Biology (General), QH301-705.5

Abstract

Summary: Exposure to prolonged stress in critical developmental periods induces heightened vulnerability to psychiatric disorders, which may have sex-specific consequences. Here we investigate the neuronal circuits mediating behavioral changes in mice after chronic adolescent social isolation stress. Escalated aggression is exhibited in stressed males, while social withdrawal is shown in stressed females. In vivo multichannel recordings of free-moving animals indicate that pyramidal neurons in prefrontal cortex (PFC) from stressed males exhibit the significantly decreased spike activity during aggressive attacks, while PFC pyramidal neurons from stressed females show a blunted increase of discharge rates during sociability tests. Chemogenetic and electrophysiological evidence shows that PFC hypofunctioning and BLA principal neuron hyperactivity contribute to the elevated aggression in stressed males, while PFC hypofunctioning and VTA dopamine neuron hypoactivity contribute to the diminished sociability in stressed females. These results establish a framework for understanding the circuit and physiological mechanisms underlying sex-specific divergent effects of stress.

Published

2021