Your search keyword '"in vivo calcium imaging"' showing total 192 results

1. The NKCC1 inhibitor bumetanide restores cortical feedforward inhibition and lessens sensory hypersensitivity in early postnatal fragile X mice.

Author

Kourdougli, Nazim, Nomura, Toshihiro, Wu, Michelle, Heuvelmans, Anouk, Dobler, Zoë, Contractor, Anis, and Portera-Cailliau, Carlos

Subjects

Biomedical and Clinical Sciences, Neurosciences, Rare Diseases, Intellectual and Developmental Disabilities (IDD), Behavioral and Social Science, Brain Disorders, Basic Behavioral and Social Science, Mental Health, Genetics, Pediatric, Fragile X Syndrome, Neurological, Autism spectrum disorders, Bumetanide, Fragile X syndrome, In vivo calcium imaging, Intellectual disability, Interneuron, NKCC1, Somatosensory cortex, Two-photon, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry, Biological sciences, Biomedical and clinical sciences, Psychology

Abstract

BackgroundExaggerated responses to sensory stimuli, a hallmark of Fragile X syndrome (FXS), contribute to anxiety and learning challenges. Sensory hypersensitivity is recapitulated in the Fmr1 knockout (KO) mouse model of FXS. Recent studies in Fmr1 KO mice have demonstrated differences in activity of cortical interneurons and a delayed switch in the polarity of GABA signaling during development. Previously, we reported that blocking the chloride transporter NKCC1 with the diuretic bumetanide, could rescue synaptic circuit phenotypes in primary somatosensory cortex (S1) of Fmr1 KO mice. However, it remains unknown whether bumetanide can rescue earlier circuit phenotypes or sensory hypersensitivity in Fmr1 KO mice.MethodsWe used acute and chronic systemic administration of bumetanide in Fmr1 KO mice and performed in vivo 2-photon calcium imaging to record neuronal activity, while tracking mouse behavior with high-resolution videos.ResultsWe demonstrate that layer (L) 2/3 pyramidal neurons in S1 of Fmr1 KO mice show a higher frequency of synchronous events at postnatal day (P) 6 compared to wild-type controls. This was reversed by acute administration of bumetanide. Furthermore, chronic bumetanide treatment (P5-P14) restored S1 circuit differences in Fmr1 KO mice, including reduced neuronal adaptation to repetitive whisker stimulation, and ameliorated tactile defensiveness. Bumetanide treatment also rectified the reduced feedforward inhibition of L2/3 neurons in S1 and boosted the circuit participation of parvalbumin interneurons.ConclusionsThis further supports the notion that synaptic, circuit, and sensory behavioral phenotypes in Fmr1 KO can be mitigated by inhibitors of NKCC1, such as the FDA-approved diuretic bumetanide.

Published

2024

2. Cadmium inhibits calcium activity in hippocampal CA1 neurons of freely moving mice.

Author

Matsushita, Megumi T and Xia, Zhengui

Subjects

*CADMIUM, *NEURONS, *CALCIUM ions, *HEAVY metals, *HIPPOCAMPUS (Brain)

Abstract

Cadmium (Cd) is a ubiquitous toxic heavy metal and a potential neurotoxicant due to its wide use in industrial manufacturing processes and commercial products, including fertilizers. The general population is exposed to Cd through food and smoking due to high transfer rates of Cd from contaminated soil. Cd has been shown to mimic calcium ions (Ca2+) and interfere with intracellular Ca2+ levels and Ca2+ signaling in in vitro studies. However, nothing is known about Cd's effects on Ca2+ activity in neurons in live animals. This study aimed to determine if Cd disrupts Ca2+ transients of neurons in CA1 region of the hippocampus during an associative learning paradigm. We utilized in vivo Ca2+ imaging in awake, freely moving C57BL/6 mice to measure Ca2+ activity in CA1 excitatory neurons expressing genetically encoded Ca2+ sensor GCaMP6 during an associative learning paradigm. We found that a smaller proportion of neurons are activated in Cd-treated groups compared with control during fear conditioning, suggesting that Cd may contribute to learning and memory deficit by reducing the activity of neurons. We observed these effects at Cd exposure levels that result in blood Cd levels comparable with the general U.S. population levels. This provides a possible molecular mechanism for Cd interference of learning and memory at exposure levels relevant to U.S. adults. To our knowledge, our study is the first to describe Cd effects on brain Ca2+ activity in vivo in freely behaving mice. This study provides evidence for impairment of neuronal calcium activity in hippocampal CA1 excitatory neurons in freely moving mice following cadmium exposure. [ABSTRACT FROM AUTHOR]

Published

2024

3. Experimental Approaches Used to Investigate Voluntary Behavioral Thermoregulatory Responses

Author

Ido, Airi, Kanai, Minami, Hitora-Imamura, Natsuko, Nomura, Hiroshi, Minami, Masabumi, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Steinlein, Ortrud, Series Editor, Xiao, Junjie, Series Editor, Rosenhouse-Dantsker, Avia, Editorial Board Member, Tominaga, Makoto, editor, and Takagi, Masahiro, editor

Published

2024

4. Assessing spontaneous sensory neuron activity using in vivo calcium imaging.

Author

Ingram, Sonia, Chisholm, Kim I., Feng Wang, De Koninck, Yves, Denk, Franziska, and Goodwin, George L.

Subjects

*SENSORY neurons, *MACHINE learning, *DORSAL root ganglia, *CALCIUM, *EXPERIMENTAL arthritis, *ADJUVANT arthritis

Abstract

Heightened spontaneous activity in sensory neurons is often reported in individuals living with chronic pain. It is possible to study this activity in rodents using electrophysiology, but these experiments require great skill and can be prone to bias. Here, we have examined whether in vivo calcium imaging with GCaMP6s can be used as an alternative approach. We show that spontaneously active calcium transients can be visualised in the fourth lumbar dorsal root ganglion (L4 DRG) through in vivo imaging in a mouse model of inflammatory pain. Application of lidocaine to the nerve, between the inflamed site and the DRG, silenced spontaneous firing and revealed the true baseline level of calcium for spontaneously active neurons. We used these data to train a machine learning algorithm to predict when a neuron is spontaneously active. We show that our algorithm is accurate in 2 different models of pain: intraplantar complete Freund adjuvant and antigen-induced arthritis, with accuracies of 90.0% ±1.2 and 85.9% ±2.1, respectively, assessed against visual inspection by an experienced observer. The algorithm can also detect neuronal activity in imaging experiments generated in a different laboratory using a different microscope configuration (accuracy = 94.0% ±2.2). We conclude that in vivo calcium imaging can be used to assess spontaneous activity in sensory neurons and provide a Google Colaboratory Notebook to allow anyone easy access to our novel analysis tool, for the assessment of spontaneous neuronal activity in their own imaging setups. [ABSTRACT FROM AUTHOR]

Published

2024

5. A pharynx-to-brain axis controls pharyngeal inflammation-induced anxiety.

Author

Wan Zhao, Ke Zhang, Wan-Ying Dong, Hao-Di Tang, Jia-Qiang Sun, Ji-Ye Huang, Guang-Lun Wan, Rui-Rui Guan, Xiao-Tao Guo, Ping-Kai Cheng, Ran Tao, Jing-Wu Sun, Zhi Zhang, and Xia Zhu

Subjects

*SOLITARY nucleus, *SENSORY neurons, *ANXIETY

Abstract

Anxiety is a remarkably common condition among patients with pharyngitis, but the relationship between these disorders has received little research attention, and the underlying neural mechanisms remain unknown. Here, we show that the densely innervated pharynx transmits signals induced by pharyngeal inflammation to glossopharyngeal and vagal sensory neurons of the nodose/jugular/petrosal (NJP) superganglia in mice. Specifically, the NJP superganglia project to norepinephrinergic neurons in the nucleus of the solitary tract (NTSNE). These NTSNE neurons project to the ventral bed nucleus of the stria terminalis (vBNST) that induces anxiety-like behaviors in a murine model of pharyngeal inflammation. Inhibiting this pharynx→NJP→NTSNE→VBNST circuit can alleviate anxiety-like behaviors associated with pharyngeal inflammation. This study thus defines a pharynx-to-brain axis that mechanistically links pharyngeal inflammation and emotional response. [ABSTRACT FROM AUTHOR]

Published

2024

6. Loosely synchronized activation of anterior cingulate cortical neurons for scratching response during histamine-induced itch

Author

Chiwoo Lee, Jihae Oh, Jae-Hyung Lee, Bong-Kiun Kaang, and Hyoung-Gon Ko

Subjects

Anterior cingulate cortex, Itch, In vivo calcium imaging, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Itch is a distinctive sensation that causes a specific affection and scratching reaction. The anterior cingulate cortex (ACC) has been linked to itch sensation in numerous studies; however, its precise function in processing pruritic inputs remains unknown. Distinguishing the precise role of the ACC in itch sensation can be challenging because of its capacity to conduct heterologous neurophysiological activities. Here, we used in vivo calcium imaging to examine how ACC neurons in free-moving mice react to pruritogenic histamine. In particular, we focused on how the activity of the ACC neurons varied before and after the scratching response. We discovered that although the change in neuronal activity was not synchronized with the scratching reaction, the overall activity of itch-responsive neurons promptly decreased after the scratching response. These findings suggest that the ACC does not directly elicit the feeling of itchiness.

Published

2023

7. Mesoscale calcium imaging in vivo: evolution and contribution to developmental neuroscience.

Author

Guillamón-Vivancos, Teresa, Vandael, Dorien, Torres, Daniel, López-Bendito, Guillermina, and Martini, Francisco J.

Subjects

CALCIUM, NEURAL development, NEUROSCIENCES, NEURAL circuitry, BRAIN imaging

Abstract

Calcium imaging is commonly used to visualize neural activity in vivo. In particular, mesoscale calcium imaging provides large fields of view, allowing for the simultaneous interrogation of neuron ensembles across the neuraxis. In the field of Developmental Neuroscience, mesoscopic imaging has recently yielded intriguing results that have shed new light on the ontogenesis of neural circuits from the first stages of life. We summarize here the technical approaches, basic notions for data analysis and the main findings provided by this technique in the last few years, with a focus on brain development in mouse models. As new tools develop to optimize calcium imaging in vivo, basic principles of neural development should be revised from a mesoscale perspective, that is, taking into account widespread activation of neuronal ensembles across the brain. In the future, combining mesoscale imaging of the dorsal surface of the brain with imaging of deep structures would ensure a more complete understanding of the construction of circuits. Moreover, the combination of mesoscale calcium imaging with other tools, like electrophysiology or high-resolution microscopy, will make up for the spatial and temporal limitations of this technique. [ABSTRACT FROM AUTHOR]

Published

2023

8. Loosely synchronized activation of anterior cingulate cortical neurons for scratching response during histamine-induced itch.

Author

Lee, Chiwoo, Oh, Jihae, Lee, Jae-Hyung, Kaang, Bong-Kiun, and Ko, Hyoung-Gon

Subjects

*ITCHING, *CINGULATE cortex, *NEURONS, *SENSES, *HISTAMINE

Abstract

Itch is a distinctive sensation that causes a specific affection and scratching reaction. The anterior cingulate cortex (ACC) has been linked to itch sensation in numerous studies; however, its precise function in processing pruritic inputs remains unknown. Distinguishing the precise role of the ACC in itch sensation can be challenging because of its capacity to conduct heterologous neurophysiological activities. Here, we used in vivo calcium imaging to examine how ACC neurons in free-moving mice react to pruritogenic histamine. In particular, we focused on how the activity of the ACC neurons varied before and after the scratching response. We discovered that although the change in neuronal activity was not synchronized with the scratching reaction, the overall activity of itch-responsive neurons promptly decreased after the scratching response. These findings suggest that the ACC does not directly elicit the feeling of itchiness. [ABSTRACT FROM AUTHOR]

Published

2023

9. Principles of nociceptive coding in the anterior cingulate cortex.

Author

Acuña, Mario A., Kasanetz, Fernando, De Luna, Paolo, Falkowska, Marta, and Nevian, Thomas

Subjects

*CINGULATE cortex, *HYPNOTISM, *PERIPHERAL nervous system, *NEURALGIA, *CELL imaging, *INTRACELLULAR calcium

Abstract

The perception of pain is a multidimensional sensory and emotional/affective experience arising from distributed brain activity. However, the involved brain regions are not specific for pain. Thus, how the cortex distinguishes nociception from other aversive and salient sensory stimuli remains elusive. Additionally, the resulting consequences of chronic neuropathic pain on sensory processing have not been characterized. Using in vivo miniscope calcium imaging with cellular resolution in freely moving mice, we elucidated the principles of nociceptive and sensory coding in the anterior cingulate cortex, a region essential for pain processing. We found that population activity, not single-cell responses, allowed discriminating noxious from other sensory stimuli, ruling out the existence of nociception-specific neurons. Additionally, single-cell stimulus selectivity was highly dynamic over time, but stimulus representation at the population level remained stable. Peripheral nerve injury-induced chronic neuropathic pain led to dysfunctional encoding of sensory events by exacerbation of responses to innocuous stimuli and impairment of pattern separation and stimulus classification, which were restored by analgesic treatment. These findings provide a novel interpretation for altered cortical sensory processing in chronic neuropathic pain and give insights into the effects of systemic analgesic treatment in the cortex. [ABSTRACT FROM AUTHOR]

Published

2023

10. Reduced activity of parvalbumin-positive interneurons in the posterior parietal cortex causes visually dominant multisensory decisions in freely navigating mice

Author

Ilsong Choi and Seung-Hee Lee

Subjects

Multisensory integration, Posterior parietal cortex, Parvalbumin-positive neurons, In vivo calcium imaging, Optogenetics, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Multisensory integration is vital for animals to make optimal decisions in a complicated sensory environment. However, the neural mechanisms for flexible multisensory behaviors are not well understood. Here, we found that mice exhibit auditory-dominant decisions in the head-fixed and stationary state and switch to make visual-dominant decisions in the freely navigating state to resolve audiovisual conflicts. To understand the neural mechanism of the state-dependent switch in multisensory decisions, we performed in vivo calcium imaging of parvalbumin-expressing (PV+) inhibitory neurons in the posterior parietal cortex (PPC), which are known to mediate auditory dominance in the resolution of audiovisual conflicts, in mice on the treadmill. In the stationary state, the PPC PV+ neurons showed similar amounts of evoked activity in responses to auditory and visual stimuli and enhanced responses to the multisensory audiovisual stimuli. Conversely, when mice were running on a treadmill, the PV+ neurons lost auditory responses and did not show any multisensory enhancement in their activity. When we optogenetically activated the PPC PV+ neurons in mice freely navigating the T-maze, the mice made more auditory-dominant decisions without changes in unisensory decisions. Our data demonstrate that the PPC PV+ neurons lost their ability to integrate auditory information with the visual one during active navigation. This modulation of the PPC PV+ neuron activity is critical for animals to make adaptive multisensory decisions according to their behavioral states.

Published

2022

11. Mesoscale calcium imaging in vivo: evolution and contribution to developmental neuroscience

Author

Teresa Guillamón-Vivancos, Dorien Vandael, Daniel Torres, Guillermina López-Bendito, and Francisco J. Martini

Subjects

mesoscale imaging, in vivo calcium imaging, neural development, circuit development, mouse, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Calcium imaging is commonly used to visualize neural activity in vivo. In particular, mesoscale calcium imaging provides large fields of view, allowing for the simultaneous interrogation of neuron ensembles across the neuraxis. In the field of Developmental Neuroscience, mesoscopic imaging has recently yielded intriguing results that have shed new light on the ontogenesis of neural circuits from the first stages of life. We summarize here the technical approaches, basic notions for data analysis and the main findings provided by this technique in the last few years, with a focus on brain development in mouse models. As new tools develop to optimize calcium imaging in vivo, basic principles of neural development should be revised from a mesoscale perspective, that is, taking into account widespread activation of neuronal ensembles across the brain. In the future, combining mesoscale imaging of the dorsal surface of the brain with imaging of deep structures would ensure a more complete understanding of the construction of circuits. Moreover, the combination of mesoscale calcium imaging with other tools, like electrophysiology or high-resolution microscopy, will make up for the spatial and temporal limitations of this technique.

Published

2023

12. Arginine-vasopressin-expressing neurons in the murine suprachiasmatic nucleus exhibit a circadian rhythm in network coherence in vivo.

Author

Stowie, Adam, Zhimei Qiao, Buonfiglio, Daniella Do Carmo, Beckner, Delaney M., Ehlen, J Christopher, Benveniste, Morris, and Davidson, Alec J.

Subjects

*SUPRACHIASMATIC nucleus, *CIRCADIAN rhythms, *GABAERGIC neurons, *NEURONS, *VASOPRESSIN

Abstract

The suprachiasmatic nucleus (SCN) is composed of functionally distinct subpopulations of GABAergic neurons which form a neural network responsible for synchronizing most physiological and behavioral circadian rhythms in mammals. To date, little is known regarding which aspects of SCN rhythmicity are generated by individual SCN neurons, and which aspects result from neuronal interaction within a network. Here, we utilize in vivo miniaturized microscopy to measure fluorescent GCaMP-reported calcium dynamics in arginine vasopressin (AVP)-expressing neurons in the intact SCN of awake, behaving mice. We report that SCN AVP neurons exhibit periodic, slow calcium waves which we demonstrate, using in vivo electrical recordings, likely reflect burst firing. Further, we observe substantial heterogeneity of function in that AVP neurons exhibit unstable rhythms, and relatively weak rhythmicity at the population level. Network analysis reveals that correlated cellular behavior, or coherence, among neuron pairs also exhibited stochastic rhythms with about 33% of pairs rhythmic at any time. Unlike single-cell variables, coherence exhibited a strong rhythm at the population level with time of maximal coherence among AVP neuronal pairs at CT/ZT 6 and 9, coinciding with the timing of maximal neuronal activity for the SCN as a whole. These results demonstrate robust circadian variation in the coordination between stochastically rhythmic neurons and that interactions between AVP neurons in the SCN may be more influential than single-cell activity in the regulation of circadian rhythms. Furthermore, they demonstrate that cells in this circuit, like those in many other circuits, exhibit profound heterogenicity of function over time and space. [ABSTRACT FROM AUTHOR]

Published

2023

13. Reduced activity of parvalbumin-positive interneurons in the posterior parietal cortex causes visually dominant multisensory decisions in freely navigating mice.

Author

Choi, Ilsong and Lee, Seung-Hee

Subjects

*INTERNEURONS, *PARIETAL lobe, *AUDITORY evoked response, *AUDITORY neurons, *AUDITORY perception, *VISUAL perception

Abstract

Multisensory integration is vital for animals to make optimal decisions in a complicated sensory environment. However, the neural mechanisms for flexible multisensory behaviors are not well understood. Here, we found that mice exhibit auditory-dominant decisions in the head-fixed and stationary state and switch to make visual-dominant decisions in the freely navigating state to resolve audiovisual conflicts. To understand the neural mechanism of the state-dependent switch in multisensory decisions, we performed in vivo calcium imaging of parvalbumin-expressing (PV+) inhibitory neurons in the posterior parietal cortex (PPC), which are known to mediate auditory dominance in the resolution of audiovisual conflicts, in mice on the treadmill. In the stationary state, the PPC PV+ neurons showed similar amounts of evoked activity in responses to auditory and visual stimuli and enhanced responses to the multisensory audiovisual stimuli. Conversely, when mice were running on a treadmill, the PV+ neurons lost auditory responses and did not show any multisensory enhancement in their activity. When we optogenetically activated the PPC PV+ neurons in mice freely navigating the T-maze, the mice made more auditory-dominant decisions without changes in unisensory decisions. Our data demonstrate that the PPC PV+ neurons lost their ability to integrate auditory information with the visual one during active navigation. This modulation of the PPC PV+ neuron activity is critical for animals to make adaptive multisensory decisions according to their behavioral states. [ABSTRACT FROM AUTHOR]

Published

2022

14. CalTrig: A GUI-Based Machine Learning Approach for Decoding Neuronal Calcium Transients in Freely Moving Rodents.

Author

Lange MA, Chen Y, Fu H, Korada A, Guo C, and Ma YY

Abstract

Advances in in vivo C a 2 + imaging using miniatured microscopes have enabled researchers to study single-neuron activity in freely moving animals. Tools such as MiniAN and CalmAn have been developed to convert C a 2 + visual signals to numerical information, collectively referred to as CalV2N. However, substantial challenges remain in analyzing the large datasets generated by CalV2N, particularly in integrating data streams, evaluating CalV2N output quality, and reliably and efficiently identifying Ca2+ transients. In this study, we introduce CalTrig, an open-source graphical user interface (GUI) tool designed to address these challenges at the post-CalV2N stage of data processing. CalTrig integrates multiple data streams, including C a 2 + imaging, neuronal footprints, C a 2 + traces, and behavioral tracking, and offers capabilities for evaluating the quality of CalV2N outputs. It enables synchronized visualization and efficient C a 2 + transient identification. We evaluated four machine learning models (i.e., GRU, LSTM, Transformer, and Local Transformer) for C a 2 + transient detection. Our results indicate that the GRU model offers the highest predictability and computational efficiency, achieving stable performance across training sessions, different animals and even among different brain regions. The integration of manual, parameter-based, and machine learning-based detection methods in CalTrig provides flexibility and accuracy for various research applications. The user-friendly interface and low computing demands of CalTrig make it accessible to neuroscientists without programming expertise. We further conclude that CalTrig enables deeper exploration of brain function, supports hypothesis generation about neuronal mechanisms, and opens new avenues for understanding neurological disorders and developing treatments.

Published

2024

15. MeCP2 Deficiency Alters the Response Selectivity of Prefrontal Cortical Neurons to Different Social Stimuli.

Author

Boyle N, Li Y, Sun X, Xu P, Lai CH, Betts S, Guo D, Simha R, Zeng C, Du J, and Lu H

Subjects

Animals, Male, Social Behavior, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons physiology, Neurons metabolism, Disease Models, Animal, Action Potentials physiology, Social Interaction, Female, Prefrontal Cortex physiology, Prefrontal Cortex metabolism, Methyl-CpG-Binding Protein 2 deficiency, Methyl-CpG-Binding Protein 2 genetics, Rett Syndrome physiopathology, Rett Syndrome genetics, Pyramidal Cells physiology

Abstract

Rett syndrome (RTT), a severe neurodevelopmental disorder caused by mutations in the MeCP2 gene, is characterized by cognitive and social deficits. Previous studies have noted hypoactivity in the medial prefrontal cortex (mPFC) pyramidal neurons of MeCP2-deficient mice (RTT mice) in response to both social and nonsocial stimuli. To further understand the neural mechanisms behind the social deficits of RTT mice, we monitored excitatory pyramidal neurons in the prelimbic region of the mPFC during social interactions in mice. These neurons' activity was closely linked to social preference, especially in wild-type mice. However, RTT mice showed reduced social interest and corresponding hypoactivity in these neurons, indicating that impaired mPFC activity contributes to their social deficits. We identified six mPFC neural ensembles selectively tuned to various stimuli, with RTT mice recruiting fewer neurons to ensembles responsive to social interactions and consistently showing lower stimulus-ON ensemble transient rates. Despite these lower rates, RTT mice exhibited an increase in the percentage of social-ON neurons in later sessions, suggesting a compensatory mechanism for the decreased firing rate. This highlights the limited plasticity in the mPFC caused by MeCP2 deficiency and offers insights into the neural dynamics of social encoding. The presence of multifunctional neurons and those specifically responsive to social or object stimuli in the mPFC emphasizes its crucial role in complex behaviors and cognitive functions, with selective neuron engagement suggesting efficiency in neural activation that optimizes responses to environmental stimuli., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Boyle et al.)

Published

2024

16. Chronic Ca2+ imaging of cortical neurons with long-term expression of GCaMP-X

Author

Jinli Geng, Yingjun Tang, Zhen Yu, Yunming Gao, Wenxiang Li, Yitong Lu, Bo Wang, Huiming Zhou, Ping Li, Nan Liu, Ping Wang, Yubo Fan, Yaxiong Yang, Zengcai V Guo, and Xiaodong Liu

Subjects

genetically encoded calcium indicators, cortical neurons, calmodulin, calcium oscillations, in vivo calcium imaging, neurite outgrowth, Medicine, Science, Biology (General), QH301-705.5

Abstract

Dynamic Ca2+ signals reflect acute changes in membrane excitability, and also mediate signaling cascades in chronic processes. In both cases, chronic Ca2+ imaging is often desired, but challenged by the cytotoxicity intrinsic to calmodulin (CaM)-based GCaMP, a series of genetically-encoded Ca2+ indicators that have been widely applied. Here, we demonstrate the performance of GCaMP-X in chronic Ca2+ imaging of cortical neurons, where GCaMP-X by design is to eliminate the unwanted interactions between the conventional GCaMP and endogenous (apo)CaM-binding proteins. By expressing in adult mice at high levels over an extended time frame, GCaMP-X showed less damage and improved performance in two-photon imaging of sensory (whisker-deflection) responses or spontaneous Ca2+ fluctuations, in comparison with GCaMP. Chronic Ca2+ imaging of one month or longer was conducted for cultured cortical neurons expressing GCaMP-X, unveiling that spontaneous/local Ca2+ transients progressively developed into autonomous/global Ca2+ oscillations. Along with the morphological indices of neurite length and soma size, the major metrics of oscillatory Ca2+, including rate, amplitude and synchrony were also examined. Dysregulations of both neuritogenesis and Ca2+ oscillations became discernible around 2–3 weeks after virus injection or drug induction to express GCaMP in newborn or mature neurons, which were exacerbated by stronger or prolonged expression of GCaMP. In contrast, neurons expressing GCaMP-X were significantly less damaged or perturbed, altogether highlighting the unique importance of oscillatory Ca2+ to neural development and neuronal health. In summary, GCaMP-X provides a viable solution for Ca2+ imaging applications involving long-time and/or high-level expression of Ca2+ probes.

Published

2022

17. Regulation of Neural Circuitry under General Anesthesia: New Methods and Findings.

Author

Zhang, Kai, Pan, Jiacheng, and Yu, Yonghao

Subjects

*GENERAL anesthesia, *NEURAL pathways, *NEURAL circuitry, *LOSS of consciousness, *OPTOGENETICS

Abstract

General anesthesia has been widely utilized since the 1840s, but its underlying neural circuits remain to be completely understood. Since both general anesthesia and sleep are reversible losses of consciousness, studies on the neural-circuit mechanisms affected by general anesthesia have mainly focused on the neural nuclei or the pathways known to regulate sleep. Three advanced technologies commonly used in neuroscience, in vivo calcium imaging, chemogenetics, and optogenetics, are used to record and modulate the activity of specific neurons or neural circuits in the brain areas of interest. Recently, they have successfully been used to study the neural nuclei and pathways of general anesthesia. This article reviews these three techniques and their applications in the brain nuclei or pathways affected by general anesthesia, to serve as a reference for further and more accurate exploration of other neural circuits under general anesthesia and to contribute to other research fields in the future. [ABSTRACT FROM AUTHOR]

Published

2022

18. Breaking trade-offs: Development of fast, high-resolution, wide-field two-photon microscopes to reveal the computational principles of the brain.

Author

Ota, Keisuke, Uwamori, Hiroyuki, Ode, Takahiro, and Murayama, Masanori

Subjects

*MICROSCOPES, *OPTICAL resolution, *CEREBRAL cortex

Abstract

Information in the brain is represented by the collective and coordinated activity of single neurons. Activity is determined by a large amount of dynamic synaptic inputs from neurons in the same and/or distant brain regions. Therefore, the simultaneous recording of single neurons across several brain regions is critical for revealing the interactions among neurons that reflect the computational principles of the brain. Recently, several wide-field two-photon (2P) microscopes equipped with sizeable objective lenses have been reported. These microscopes enable large-scale in vivo calcium imaging and have the potential to make a significant contribution to the elucidation of information-processing mechanisms in the cerebral cortex. This review discusses recent reports on wide-field 2P microscopes and describes the trade-offs encountered in developing wide-field 2P microscopes. Large-scale imaging of neural activity allows us to test hypotheses proposed in theoretical neuroscience, and to identify rare but influential neurons that have potentially significant impacts on the whole-brain system. • Trade-offs among FOV, optical resolution, frame rate, and SNR are obstacles in developing 2P microscopes. • Aberration-free large objective lenses break the trade-off, resulting in the development of fast and wide-field 2P microscopes. • Wide-field 2P microscopes achieve neural activity recordings across multiple brain regions. • Large-scale imaging enables testing hypotheses proposed in theoretical neuroscience. [ABSTRACT FROM AUTHOR]

Published

2022

19. Anxiety Cells in a Hippocampal-Hypothalamic Circuit

Author

Jimenez, Jessica, Su, Katy, Goldberg, Alexander, Luna, Victor, Ordek, Gokhan, Zhou, Pengcheng, Ong, Samantha, Pena, Stephanie, Zweifel, Larry, Paninski, Liam, Hen, Rene, and Kheirbek, Mazen

Subjects

in vivo Calcium Imaging, Ventral Hippocampus, Anxiety, Lateral Hypothalamus, Basolateral Amygdala, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry

Published

2017

20. Evaluation of Recombinant Botulinum Neurotoxin Type A1 Efficacy in Peripheral Inflammatory Pain in Mice.

Author

Oehler, Beatrice, Périer, Cindy, Martin, Vincent, Fisher, Amy, Lezmi, Stéphane, Kalinichev, Mikhail, and McMahon, Stephen B.

Subjects

BOTULINUM toxin, DORSAL root ganglia, SPINAL cord, NEUROMUSCULAR diseases, MYONEURAL junction, MYASTHENIA gravis

Abstract

Well-established efficacy of botulinum neurotoxin type A (BoNT/A) in aesthetic dermatology and neuromuscular hyperactivity disorders relies on canonical interruption of acetylcholine neurotransmission at the neuromuscular junction at the site of the injection. The mechanisms and the site of activity of BoNT/A in pain, on the other hand, remain elusive. Here, we explored analgesic activity of recombinant BoNT/A1 (rBoNT/A1; IPN10260) in a mouse model of inflammatory pain to investigate the potential role of peripheral sensory afferents in this activity. After confirming analgesic efficacy of rBoNT/A1 on CFA-induced mechanical hypersensitivity in C57Bl6J mice, we used GCaMP6s to perform in vivo calcium imaging in the ipsilateral dorsal root ganglion (DRG) neurons in rBoNT/A1 vs. vehicle-treated mice at baseline and following administration of a range of mechanical and thermal stimuli. Additionally, immunohisochemical studies were performed to detect cleaved SNAP25 in the skin, DRGs and the spinal cord. Injection of CFA resulted in reduced mechanical sensitivity threshold and increased calcium fluctuations in the DRG neurons. While rBoNT/A1 reduced mechanical hypersensitivity, calcium fluctuations in the DRG of rBoNT/A1- and vehicle-treated animals were similar. Cleaved SNAP25 was largely absent in the skin and the DRG but present in the lumbar spinal cord of rBoNT/A1-treated animals. Taken together, rBoNT/A1 ameliorates mechanical hypersensitivity related to inflammation, while the signal transmission from the peripheral sensory afferents to the DRG remained unchanged. This strengthens the possibility that spinal, rather than peripheral, mechanisms play a role in the mediation of analgesic efficacy of BoNT/A in inflammatory pain. [ABSTRACT FROM AUTHOR]

Published

2022

21. Evaluation of Recombinant Botulinum Neurotoxin Type A1 Efficacy in Peripheral Inflammatory Pain in Mice

Author

Beatrice Oehler, Cindy Périer, Vincent Martin, Amy Fisher, Stéphane Lezmi, Mikhail Kalinichev, and Stephen B. McMahon

Subjects

inflammation, nociception, analgesia, GCaMP, in vivo calcium imaging, hyperalgesia, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Well-established efficacy of botulinum neurotoxin type A (BoNT/A) in aesthetic dermatology and neuromuscular hyperactivity disorders relies on canonical interruption of acetylcholine neurotransmission at the neuromuscular junction at the site of the injection. The mechanisms and the site of activity of BoNT/A in pain, on the other hand, remain elusive. Here, we explored analgesic activity of recombinant BoNT/A1 (rBoNT/A1; IPN10260) in a mouse model of inflammatory pain to investigate the potential role of peripheral sensory afferents in this activity. After confirming analgesic efficacy of rBoNT/A1 on CFA-induced mechanical hypersensitivity in C57Bl6J mice, we used GCaMP6s to perform in vivo calcium imaging in the ipsilateral dorsal root ganglion (DRG) neurons in rBoNT/A1 vs. vehicle-treated mice at baseline and following administration of a range of mechanical and thermal stimuli. Additionally, immunohisochemical studies were performed to detect cleaved SNAP25 in the skin, DRGs and the spinal cord. Injection of CFA resulted in reduced mechanical sensitivity threshold and increased calcium fluctuations in the DRG neurons. While rBoNT/A1 reduced mechanical hypersensitivity, calcium fluctuations in the DRG of rBoNT/A1- and vehicle-treated animals were similar. Cleaved SNAP25 was largely absent in the skin and the DRG but present in the lumbar spinal cord of rBoNT/A1-treated animals. Taken together, rBoNT/A1 ameliorates mechanical hypersensitivity related to inflammation, while the signal transmission from the peripheral sensory afferents to the DRG remained unchanged. This strengthens the possibility that spinal, rather than peripheral, mechanisms play a role in the mediation of analgesic efficacy of BoNT/A in inflammatory pain.

Published

2022

22. Innervation modulates the functional connectivity between pancreatic endocrine cells

Author

Yu Hsuan Carol Yang, Linford JB Briant, Christopher A Raab, Sri Teja Mullapudi, Hans-Martin Maischein, Koichi Kawakami, and Didier YR Stainier

Subjects

pancreatic islet, innervation, homotypic coupling, heterotypic coupling, in vivo calcium imaging, optogenetics, Medicine, Science, Biology (General), QH301-705.5

Abstract

The importance of pancreatic endocrine cell activity modulation by autonomic innervation has been debated. To investigate this question, we established an in vivo imaging model that also allows chronic and acute neuromodulation with genetic and optogenetic tools. Using the GCaMP6s biosensor together with endocrine cell fluorescent reporters, we imaged calcium dynamics simultaneously in multiple pancreatic islet cell types in live animals in control states and upon changes in innervation. We find that by 4 days post fertilization in zebrafish, a stage when islet architecture is reminiscent of that in adult rodents, prominent activity coupling between beta cells is present in basal glucose conditions. Furthermore, we show that both chronic and acute loss of nerve activity result in diminished beta–beta and alpha–beta activity coupling. Pancreatic nerves are in contact with all islet cell types, but predominantly with beta and delta cells. Surprisingly, a subset of delta cells with detectable peri-islet neural activity coupling had significantly higher homotypic coupling with other delta cells suggesting that some delta cells receive innervation that coordinates their output. Overall, these data show that innervation plays a vital role in the maintenance of homotypic and heterotypic cellular connectivity in pancreatic islets, a process critical for islet function.

Published

2022

23. The NKCC1 Inhibitor Bumetanide Restores Cortical Feedforward Inhibition and Lessens Sensory Hypersensitivity in Early Postnatal Fragile X Mice.

Author

Kourdougli N, Nomura T, Wu MW, Heuvelmans A, Dobler Z, Contractor A, and Portera-Cailliau C

Abstract

Background: Exaggerated responses to sensory stimuli, a hallmark of fragile X syndrome, contribute to anxiety and learning challenges. Sensory hypersensitivity is recapitulated in the Fmr1 knockout (KO) mouse model of fragile X syndrome. Recent studies in Fmr1 KO mice have demonstrated differences in the activity of cortical interneurons and a delayed switch in the polarity of GABA (gamma-aminobutyric acid) signaling during development. Previously, we reported that blocking the chloride transporter NKCC1 with the diuretic bumetanide could rescue synaptic circuit phenotypes in the primary somatosensory cortex (S1) of Fmr1 KO mice. However, it remains unknown whether bumetanide can rescue earlier circuit phenotypes or sensory hypersensitivity in Fmr1 KO mice., Methods: We used acute and chronic systemic administration of bumetanide in Fmr1 KO mice and performed in vivo 2-photon calcium imaging to record neuronal activity, while tracking mouse behavior with high-resolution videos., Results: We demonstrated that layer 2/3 pyramidal neurons in the S1 of Fmr1 KO mice showed a higher frequency of synchronous events on postnatal day 6 than wild-type controls. This was reversed by acute administration of bumetanide. Furthermore, chronic bumetanide treatment (postnatal days 5-14) restored S1 circuit differences in Fmr1 KO mice, including reduced neuronal adaptation to repetitive whisker stimulation, and ameliorated tactile defensiveness. Bumetanide treatment also rectified the reduced feedforward inhibition of layer 2/3 neurons in the S1 and boosted the circuit participation of parvalbumin interneurons., Conclusions: This further supports the notion that synaptic, circuit, and sensory behavioral phenotypes in Fmr1 KO can be mitigated by inhibitors of NKCC1, such as the Food and Drug Administration-approved diuretic bumetanide., (Copyright © 2024 Society of Biological Psychiatry. Published by Elsevier Inc. All rights reserved.)

Published

2024

24. Circuit Investigation of Social Interaction and Substance Use Disorder Using Miniscopes.

Author

Beacher, Nicholas J., Washington, Kayden A., Werner, Craig T., Zhang, Yan, Barbera, Giovanni, Li, Yun, and Lin, Da-Ting

Subjects

SUBSTANCE abuse, SOCIAL interaction, BRAIN anatomy, REWARD (Psychology), ANIMAL behavior

Abstract

Substance use disorder (SUD) is comorbid with devastating health issues, social withdrawal, and isolation. Successful clinical treatments for SUD have used social interventions. Neurons can encode drug cues, and drug cues can trigger relapse. It is important to study how the activity in circuits and embedded cell types that encode drug cues develop in SUD. Exploring shared neurobiology between social interaction (SI) and SUD may explain why humans with access to social treatments still experience relapse. However, circuitry remains poorly characterized due to technical challenges in studying the complicated nature of SI and SUD. To understand the neural correlates of SI and SUD, it is important to: (1) identify cell types and circuits associated with SI and SUD, (2) record and manipulate neural activity encoding drug and social rewards over time, (3) monitor unrestrained animal behavior that allows reliable drug self-administration (SA) and SI. Miniaturized fluorescence microscopes (miniscopes) are ideally suited to meet these requirements. They can be used with gradient index (GRIN) lenses to image from deep brain structures implicated in SUD. Miniscopes can be combined with genetically encoded reporters to extract cell-type specific information. In this mini-review, we explore how miniscopes can be leveraged to uncover neural components of SI and SUD and advance potential therapeutic interventions. [ABSTRACT FROM AUTHOR]

Published

2021

25. Modality-Specific Modulation of Temperature Representations in the Spinal Cord after Injury.

Author

Chen Ran, Kamalani, Gabrielle N. A., and Xiaoke Chen

Subjects

*SPINAL cord injuries, *SENSORY neurons, *SPINAL cord, *MICE genetics, *SOFT tissue injuries

Abstract

Different types of tissue injury, such as inflammatory and neuropathic conditions, cause modality-specific alternations on temperature perception. There are profound changes in peripheral sensory neurons after injury, but how patterned neuronal activities in the CNS encode injury-induced sensitization to temperature stimuli is largely unknown. Using in vivo calcium imaging and mouse genetics, we show that formalin- and prostaglandin E2-induced inflammation dramatically increase spinal responses to heating and decrease responses to cooling in male and female mice. The reduction of cold response is largely eliminated on ablation of TRPV1-expressing primary sensory neurons, indicating a crossover inhibition of cold response from the hyperactive heat inputs in the spinal cord. Interestingly, chemotherapy medication oxaliplatin can rapidly increase spinal responses to cooling and suppress responses to heating. Together, our results suggest a push-pull mechanism in processing cold and heat inputs and reveal a synergic mechanism to shift thermosensation after injury. [ABSTRACT FROM AUTHOR]

Published

2021

26. Circuit Investigation of Social Interaction and Substance Use Disorder Using Miniscopes

Author

Nicholas J. Beacher, Kayden A. Washington, Craig T. Werner, Yan Zhang, Giovanni Barbera, Yun Li, and Da-Ting Lin

Subjects

miniature fluorescence microscopy, miniscope, in vivo calcium imaging, longitudinal imaging, substance use disorder, social interaction, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Substance use disorder (SUD) is comorbid with devastating health issues, social withdrawal, and isolation. Successful clinical treatments for SUD have used social interventions. Neurons can encode drug cues, and drug cues can trigger relapse. It is important to study how the activity in circuits and embedded cell types that encode drug cues develop in SUD. Exploring shared neurobiology between social interaction (SI) and SUD may explain why humans with access to social treatments still experience relapse. However, circuitry remains poorly characterized due to technical challenges in studying the complicated nature of SI and SUD. To understand the neural correlates of SI and SUD, it is important to: (1) identify cell types and circuits associated with SI and SUD, (2) record and manipulate neural activity encoding drug and social rewards over time, (3) monitor unrestrained animal behavior that allows reliable drug self-administration (SA) and SI. Miniaturized fluorescence microscopes (miniscopes) are ideally suited to meet these requirements. They can be used with gradient index (GRIN) lenses to image from deep brain structures implicated in SUD. Miniscopes can be combined with genetically encoded reporters to extract cell-type specific information. In this mini-review, we explore how miniscopes can be leveraged to uncover neural components of SI and SUD and advance potential therapeutic interventions.

Published

2021

27. 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

28. Regulation of Neural Circuitry under General Anesthesia: New Methods and Findings

Author

Kai Zhang, Jiacheng Pan, and Yonghao Yu

Subjects

general anesthesia, neural nuclei and circuits, in vivo calcium imaging, chemogenetics, optogenetics, Microbiology, QR1-502

Abstract

General anesthesia has been widely utilized since the 1840s, but its underlying neural circuits remain to be completely understood. Since both general anesthesia and sleep are reversible losses of consciousness, studies on the neural-circuit mechanisms affected by general anesthesia have mainly focused on the neural nuclei or the pathways known to regulate sleep. Three advanced technologies commonly used in neuroscience, in vivo calcium imaging, chemogenetics, and optogenetics, are used to record and modulate the activity of specific neurons or neural circuits in the brain areas of interest. Recently, they have successfully been used to study the neural nuclei and pathways of general anesthesia. This article reviews these three techniques and their applications in the brain nuclei or pathways affected by general anesthesia, to serve as a reference for further and more accurate exploration of other neural circuits under general anesthesia and to contribute to other research fields in the future.

Published

2022

29. Deficiency of Inositol Monophosphatase Activity Decreases Phosphoinositide Lipids and Enhances TRPV1 Function In Vivo.

Author

Caires, Rebeca, Bell, Briar, Jungsoo Lee, Romero, Luis O., Vásquez, Valeria, and Cordero-Morales, Julio F.

Subjects

*TRPV cation channels, *INFLAMMATORY mediators, *LIPIDS, *INOSITOL, *CAENORHABDITIS elegans

Abstract

Membrane remodeling by inflammatory mediators influences the function of sensory ion channels. The capsaicin- and heat-activated transient receptor potential vanilloid 1 (TRPV1) channel contributes to neurogenic inflammation and pain hypersensitivity, in part because of its potentiation downstream of phospholipase C-coupled receptors that regulate phos-phoinositide lipid content. Here, we determined the effect of phosphoinositide lipids on TRPV1 function by combining genetic dissection, diet supplementation, and behavioral, biochemical, and functional analyses in Caenorhabditis elegans. As capsaicin elicits heat and pain sensations in mammals, transgenic TRPV1 worms exhibit an aversive response to capsaicin. TRPV1 worms with low levels of phosphoinositide lipids display an enhanced response to capsaicin, whereas phosphoinositide lipid supplementation reduces TRPV1-mediated responses. A worm carrying a TRPV1 construct lacking the distal C-terminal domain features an enhanced response to capsaicin, independent of the phosphoinositide lipid content. Our results demonstrate that TRPV1 activity is enhanced when the phosphoinositide lipid content is reduced, and the C-terminal domain is key to determining agonist response in vivo. [ABSTRACT FROM AUTHOR]

Published

2021

30. Midbrain dopaminergic degeneration differentially modulates primary motor cortex activity and motor behavior in hemi-parkinsonian rats.

Author

Boschen SL, Seethaler J, Wang S, Lujan WD, Silvernail JL, Carter RE, Chang SY, and Lujan JL

Abstract

Parkinson's disease (PD) is marked by degeneration in the nigrostriatal dopaminergic pathway, affecting motor control via complex changes in the cortico-basal ganglia-thalamic motor network, including the primary motor cortex (M1). The modulation of M1 neuronal activity by dopaminergic inputs, particularly from the ventral tegmental area (VTA) and substantia nigra pars compacta (SNc), plays a crucial role in PD pathophysiology. This study investigates how nigrostriatal dopaminergic degeneration influences M1 neuronal activity in rats using in vivo calcium imaging. Histological analysis confirmed dopaminergic lesion severity, with high lesion level rats showing significant motor deficits. Levodopa treatment improved fine motor abilities, particularly in high lesion level rats. Analysis of M1 calcium signals based on dopaminergic lesion severity revealed distinct M1 activity patterns. Animals with low dopaminergic lesion showed increased calcium events, while high lesion level rats exhibited decreased activity, partially restored by levodopa. These findings suggest that M1 activity is more sensitive to transient fluctuations in dopaminergic transmission, rather than to chronic high or low dopaminergic signaling. This study underscores the complex interplay between dopaminergic signaling and M1 neuronal activity in PD symptoms development. Further research integrating behavioral and calcium imaging data can elucidate mechanisms underlying motor deficits and therapeutic responses in PD., Competing Interests: Conflict of Interest The authors declare no competing interests.

Published

2024

31. A pharynx-to-brain axis controls pharyngeal inflammation-induced anxiety.

Author

Zhao W, Zhang K, Dong WY, Tang HD, Sun JQ, Huang JY, Wan GL, Guan RR, Guo XT, Cheng PK, Tao R, Sun JW, Zhang Z, and Zhu X

Subjects

Humans, Animals, Mice, Anxiety, Brain, Sensory Receptor Cells, Inflammation, Pharynx, Pharyngitis

Abstract

Anxiety is a remarkably common condition among patients with pharyngitis, but the relationship between these disorders has received little research attention, and the underlying neural mechanisms remain unknown. Here, we show that the densely innervated pharynx transmits signals induced by pharyngeal inflammation to glossopharyngeal and vagal sensory neurons of the nodose/jugular/petrosal (NJP) superganglia in mice. Specifically, the NJP superganglia project to norepinephrinergic neurons in the nucleus of the solitary tract (NTS NE ). These NTS NE neurons project to the ventral bed nucleus of the stria terminalis (vBNST) that induces anxiety-like behaviors in a murine model of pharyngeal inflammation. Inhibiting this pharynx→NJP→NTS NE →vBNST circuit can alleviate anxiety-like behaviors associated with pharyngeal inflammation. This study thus defines a pharynx-to-brain axis that mechanistically links pharyngeal inflammation and emotional response., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

32. Microglial repopulation model reveals a robust homeostatic process for replacing CNS myeloid cells

Author

Varvel, Nicholas H, Grathwohl, Stefan A, Baumann, Frank, Liebig, Christian, Bosch, Andrea, Brawek, Bianca, Thal, Dietmar R, Charo, Israel F, Heppner, Frank L, Aguzzi, Adriano, Garaschuk, Olga, Ransohoff, Richard M, and Jucker, Mathias

Subjects

Medical Physiology, Biomedical and Clinical Sciences, Neurosciences, Stem Cell Research - Nonembryonic - Non-Human, Bioengineering, Stem Cell Research, Hematology, 2.1 Biological and endogenous factors, Aetiology, Neurological, Adenosine Triphosphate, Animals, Central Nervous System, Homeostasis, Mice, Microglia, Thymidine Kinase, chemokines, myeloid cell heterogeneity, neuroinflammation, in vivo calcium imaging

Abstract

Under most physiological circumstances, monocytes are excluded from parenchymal CNS tissues. When widespread monocyte entry occurs, their numbers decrease shortly after engraftment in the presence of microglia. However, some disease processes lead to focal and selective loss, or dysfunction, of microglia, and microglial senescence typifies the aged brain. In this regard, the long-term engraftment of monocytes in the microglia-depleted brain remains unknown. Here, we report a model in which a niche for myeloid cells was created through microglia depletion. We show that microglia-depleted brain regions of CD11b-HSVTK transgenic mice are repopulated with new Iba-1-positive cells within 2 wk. The engrafted cells expressed high levels of CD45 and CCR2 and appeared in a wave-like pattern frequently associated with blood vessels, suggesting the engrafted cells were peripheral monocytes. Although two times more numerous and morphologically distinct from resident microglia up to 27 wk after initial engraftment, the overall distribution of the engrafted cells was remarkably similar to that of microglia. Two-photon in vivo imaging revealed that the engrafted myeloid cells extended their processes toward an ATP source and displayed intracellular calcium transients. Moreover, the engrafted cells migrated toward areas of kainic acid-induced neuronal death. These data provide evidence that circulating monocytes have the potential to occupy the adult CNS myeloid niche normally inhabited by microglia and identify a strong homeostatic drive to maintain the myeloid component in the mature brain.

Published

2012

33. Cortical and Striatal Circuits in Huntington’s Disease

Author

Sonja Blumenstock and Irina Dudanova

Subjects

Huntington’s disease, cortex, basal ganglia, neural circuits, genetic mouse models, in vivo calcium imaging, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Huntington’s disease (HD) is a hereditary neurodegenerative disorder that typically manifests in midlife with motor, cognitive, and/or psychiatric symptoms. The disease is caused by a CAG triplet expansion in exon 1 of the huntingtin gene and leads to a severe neurodegeneration in the striatum and cortex. Classical electrophysiological studies in genetic HD mouse models provided important insights into the disbalance of excitatory, inhibitory and neuromodulatory inputs, as well as progressive disconnection between the cortex and striatum. However, the involvement of local cortical and striatal microcircuits still remains largely unexplored. Here we review the progress in understanding HD-related impairments in the cortical and basal ganglia circuits, and outline new opportunities that have opened with the development of modern circuit analysis methods. In particular, in vivo imaging studies in mouse HD models have demonstrated early structural and functional disturbances within the cortical network, and optogenetic manipulations of striatal cell types have started uncovering the causal roles of certain neuronal populations in disease pathogenesis. In addition, the important contribution of astrocytes to HD-related circuit defects has recently been recognized. In parallel, unbiased systems biology studies are providing insights into the possible molecular underpinnings of these functional defects at the level of synaptic signaling and neurotransmitter metabolism. With these approaches, we can now reach a deeper understanding of circuit-based HD mechanisms, which will be crucial for the development of effective and targeted therapeutic strategies.

Published

2020

34. Visualization and correction of social abnormalities-associated neural ensembles in adult MECP2 duplication mice.

Author

Sun, Le, Chen, Ruiguo, Li, Long, Yuan, Bo, Song, Kun, Pan, Na, Cheng, Tian-Lin, Chang, Shiyang, Lin, Kunzhang, He, Xiaobin, Wu, Qian, Xu, Fuqiang, Qiu, Zilong, and Wang, Xiaoqun

Subjects

*TRANSGENIC mice, *MICE, *NEURAL circuitry, *CRISPRS, *VISUALIZATION

Abstract

Duplications of MECP2 -containing genomic segments led to severe autistic symptoms in male. Transgenic mice overexpressing the human MECP2 gene exhibit autistic-like behaviors. Neural circuits underlying social defects in MECP2 transgenic (MECP2 -TG) mice remain unknown. To observe neural activity of MECP2 -TG mice in vivo , we performed calcium imaging by implantation of microendoscope in the hippocampal CA1 regions of MECP2 -TG and wild type (WT) mice. We identified neurons whose activities were tightly associated with social interaction, which activity patterns were compromised in MECP2 -TG mice. Strikingly, we rescued the social-related neural activity in CA1 and social defects in MECP2 -TG mice by deleting the human MECP2 transgene using the CRISPR/Cas9 method during adulthood. Our data points to the neural circuitry responsible for social interactions and provides potential therapeutic targets for autism in adulthood. [ABSTRACT FROM AUTHOR]

Published

2020

35. Cortical and Striatal Circuits in Huntington's Disease.

Author

Blumenstock, Sonja and Dudanova, Irina

Subjects

HUNTINGTON disease, BASAL ganglia, PATHOLOGY, SYSTEMS biology, NEURODEGENERATION, EXCITATORY postsynaptic potential, CEREBRAL cortex, NEURAL circuitry

Abstract

Huntington's disease (HD) is a hereditary neurodegenerative disorder that typically manifests in midlife with motor, cognitive, and/or psychiatric symptoms. The disease is caused by a CAG triplet expansion in exon 1 of the huntingtin gene and leads to a severe neurodegeneration in the striatum and cortex. Classical electrophysiological studies in genetic HD mouse models provided important insights into the disbalance of excitatory, inhibitory and neuromodulatory inputs, as well as progressive disconnection between the cortex and striatum. However, the involvement of local cortical and striatal microcircuits still remains largely unexplored. Here we review the progress in understanding HD-related impairments in the cortical and basal ganglia circuits, and outline new opportunities that have opened with the development of modern circuit analysis methods. In particular, in vivo imaging studies in mouse HD models have demonstrated early structural and functional disturbances within the cortical network, and optogenetic manipulations of striatal cell types have started uncovering the causal roles of certain neuronal populations in disease pathogenesis. In addition, the important contribution of astrocytes to HD-related circuit defects has recently been recognized. In parallel, unbiased systems biology studies are providing insights into the possible molecular underpinnings of these functional defects at the level of synaptic signaling and neurotransmitter metabolism. With these approaches, we can now reach a deeper understanding of circuit-based HD mechanisms, which will be crucial for the development of effective and targeted therapeutic strategies. [ABSTRACT FROM AUTHOR]

Published

2020

36. Mesoscale calcium imaging in vivo: evolution and contribution to developmental neuroscience

Author

European Commission, European Research Council, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia e Innovación (España), Fundación la Caixa, Generalitat Valenciana, Guillamón-Vivancos, Teresa, Vandael, Dorien, Torres, Daniel, López-Bendito, Guillermina, Martini, Francisco J., European Commission, European Research Council, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia e Innovación (España), Fundación la Caixa, Generalitat Valenciana, Guillamón-Vivancos, Teresa, Vandael, Dorien, Torres, Daniel, López-Bendito, Guillermina, and Martini, Francisco J.

Abstract

Calcium imaging is commonly used to visualize neural activity in vivo. In particular, mesoscale calcium imaging provides large fields of view, allowing for the simultaneous interrogation of neuron ensembles across the neuraxis. In the field of Developmental Neuroscience, mesoscopic imaging has recently yielded intriguing results that have shed new light on the ontogenesis of neural circuits from the first stages of life. We summarize here the technical approaches, basic notions for data analysis and the main findings provided by this technique in the last few years, with a focus on brain development in mouse models. As new tools develop to optimize calcium imaging in vivo, basic principles of neural development should be revised from a mesoscale perspective, that is, taking into account widespread activation of neuronal ensembles across the brain. In the future, combining mesoscale imaging of the dorsal surface of the brain with imaging of deep structures would ensure a more complete understanding of the construction of circuits. Moreover, the combination of mesoscale calcium imaging with other tools, like electrophysiology or high-resolution microscopy, will make up for the spatial and temporal limitations of this technique.

Published

2023

37. Maturation of Cerebellar Purkinje Cell Population Activity during Postnatal Refinement of Climbing Fiber Network

Author

Jean-Marc Good, Michael Mahoney, Taisuke Miyazaki, Kenji F. Tanaka, Kenji Sakimura, Masahiko Watanabe, Kazuo Kitamura, and Masanobu Kano

Subjects

cerebellum, Purkinje cell, climbing fiber, postnatal development, in vivo calcium imaging, 2-photon microscopy, population activity, synapse elimination, Biology (General), QH301-705.5

Abstract

Neural circuits undergo massive refinements during postnatal development. In the developing cerebellum, the climbing fiber (CF) to Purkinje cell (PC) network is drastically reshaped by eliminating early-formed redundant CF to PC synapses. To investigate the impact of CF network refinement on PC population activity during postnatal development, we monitored spontaneous CF responses in neighboring PCs and the activity of populations of nearby CF terminals using in vivo two-photon calcium imaging. Population activity is highly synchronized in newborn mice, and the degree of synchrony gradually declines during the first postnatal week in PCs and, to a lesser extent, in CF terminals. Knockout mice lacking P/Q-type voltage-gated calcium channel or glutamate receptor δ2, in which CF network refinement is severely impaired, exhibit an abnormally high level of synchrony in PC population activity. These results suggest that CF network refinement is a structural basis for developmental desynchronization and maturation of PC population activity.

Published

2017

38. Dorsal-CA1 Hippocampal Neuronal Ensembles Encode Nicotine-Reward Contextual Associations

Author

Li Xia, Stephanie K. Nygard, Gabe G. Sobczak, Nicholas J. Hourguettes, and Michael R. Bruchas

Subjects

nicotine, dorsal CA1 hippocampus, in vivo calcium imaging, place preference, Biology (General), QH301-705.5

Abstract

Natural and drug rewards increase the motivational valence of stimuli in the environment that, through Pavlovian learning mechanisms, become conditioned stimuli that directly motivate behavior in the absence of the original unconditioned stimulus. While the hippocampus has received extensive attention for its role in learning and memory processes, less is known regarding its role in drug-reward associations. We used in vivo Ca2+ imaging in freely moving mice during the formation of nicotine preference behavior to examine the role of the dorsal-CA1 region of the hippocampus in encoding contextual reward-seeking behavior. We show the development of specific neuronal ensembles whose activity encodes nicotine-reward contextual memories and that are necessary for the expression of place preference. Our findings increase our understanding of CA1 hippocampal function in general and as it relates to reward processing by identifying a critical role for CA1 neuronal ensembles in nicotine place preference.

Published

2017

39. Circuit Mechanisms of Neurodegenerative Diseases: A New Frontier With Miniature Fluorescence Microscopy

Author

Craig T. Werner, Christopher J. Williams, Mercedes R. Fermelia, Da-Ting Lin, and Yun Li

Subjects

neurodegenerative disorders, miniature fluorescence microscopy, miniscope, in vivo calcium imaging, deep brain imaging, longitudinal recording, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Neurodegenerative diseases (NDDs), such as Alzheimer’s disease (AD), Parkinson’s disease (PD), Huntington’s disease (HD), amyotrophic lateral sclerosis (ALS), and frontotemporal dementia (FTD), are devastating age-associated brain disorders. Significant efforts have been made to uncover the molecular and cellular pathogenic mechanisms that underlie NDDs. However, our understanding of the neural circuit mechanisms that mediate NDDs and associated symptomatic features have been hindered by technological limitations. Our inability to identify and track individual neurons longitudinally in subcortical brain regions that are preferentially targeted in NDDs has left gaping holes in our knowledge of NDDs. Recent development and advancement of the miniature fluorescence microscope (miniscope) has opened up new avenues for examining spatially and temporally coordinated activity from hundreds of cells in deep brain structures in freely moving rodents. In the present mini-review, we examine the capabilities of current and future miniscope tools and discuss the innovative applications of miniscope imaging techniques that can push the boundaries of our understanding of neural circuit mechanisms of NDDs into new territories.

Published

2019

40. Spontaneous Activity Patterns Are Altered in the Developing Visual Cortex of the Fmr1 Knockout Mouse

Author

Juliette E. Cheyne, Nawal Zabouri, David Baddeley, and Christian Lohmann

Subjects

fragile X mental retardation, in vivo calcium imaging, sensory integration, 2-photon microscopy, transgenic mouse, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Fragile X syndrome (FXS) is the most prevalent inherited cause of autism and is accompanied by behavioral and sensory deficits. Errors in the wiring of the brain during early development likely contribute to these deficits, but the underlying mechanisms are unclear. Spontaneous activity patterns, which are required for fine-tuning neuronal networks before the senses become active, are perturbed in rodent models of FXS. Here, we investigated spontaneous network activity patterns in the developing visual cortex of the Fmr1 knockout mouse using in vivo calcium imaging during the second postnatal week, before eye opening. We found that while the frequency, mean amplitude and duration of spontaneous network events were unchanged in the knockout mouse, pair-wise correlations between neurons were increased compared to wild type littermate controls. Further analysis revealed that interneuronal correlations were not generally increased, rather that low-synchronization events occurred relatively less frequently than high-synchronization events. Low-, but not high-, synchronization events have been associated with retinal inputs previously. Since we found that spontaneous retinal waves were normal in the knockout, our results suggest that peripherally driven activity is underrepresented in the Fmr1 KO visual cortex. Therefore, we propose that central gating of retinal inputs may be affected in FXS and that peripherally and centrally driven activity patterns are already unbalanced before eye opening in this disorder.

Published

2019

41. Endocannabinoid-mediated rescue of somatosensory cortex activity, plasticity and related behaviors following an early in life concussion.

Author

Badaut J, Hippauf L, Malinconi M, Noarbe BP, Obenaus A, and Dubois CJ

Abstract

Due to the assumed plasticity of immature brain, early in life brain alterations are thought to lead to better recoveries in comparison to the mature brain. Despite clinical needs, how neuronal networks and associated behaviors are affected by early in life brain stresses, such as pediatric concussions, have been overlooked. Here we provide first evidence in mice that a single early in life concussion durably increases neuronal activity in the somatosensory cortex into adulthood, disrupting neuronal integration while the animal is performing sensory-related tasks. This represents a previously unappreciated clinically relevant mechanism for the impairment of sensory-related behavior performance. Furthermore, we demonstrate that pharmacological modulation of the endocannabinoid system a year post-concussion is well-suited to rescue neuronal activity and plasticity, and to normalize sensory-related behavioral performance, addressing the fundamental question of whether a treatment is still possible once post-concussive symptoms have developed, a time-window compatible with clinical treatment.

Published

2024

42. Combined Experiments with in Vivo Fiber Photometry and Behavior Tests Can Facilitate the Measurement of Neuronal Activity in the Primary Somatosensory Cortex and Hyperalgesia in an Inflammatory Pain Mice Model.

Author

Ishikawa T, Uta D, Okuda H, Potapenko I, Hori K, Kume T, and Ozaki N

Subjects

Animals, Mice, Behavior Rating Scale, Calcium, Somatosensory Cortex, Calcium, Dietary, Disease Models, Animal, Neurons, Photometry, Hyperalgesia, Chronic Pain

Abstract

The pain matrix, which includes several brain regions that respond to pain sensation, contribute to the development of chronic pain. Thus, it is essential to understand the mechanism of causing chronic pain in the pain matrix such as anterior cingulate (ACC), or primary somatosensory (S1) cortex. Recently, combined experiment with the behavior tests and in vivo calcium imaging using fiber photometry revealed the interaction between the neuronal function in deep brain regions of the pain matrix including ACC and the phenotype of chronic pain. However, it remains unclear whether this combined experiment can identify the interaction between neuronal activity in S1, which receive pain sensation, and pain behaviors such as hyperalgesia or allodynia. In this study, to examine whether the interaction between change of neuronal activity in S1 and hyperalgesia in hind paw before and after causing inflammatory pain was detected from same animal, the combined experiment of in vivo fiber photometry system and von Frey hairs test was applied. This combined experiment detected that amplitude of calcium responses in S1 neurons increased and the mechanical threshold of hind paw decreased from same animals which have an inflammatory pain. Moreover, we found that the values between amplitude of calcium responses and mechanical thresholds were shifted to negative correlation after causing inflammatory pain. Thus, the combined experiment with fiber photometry and the behavior tests has a possibility that can simultaneously consider the interaction between neuronal activity in pain matrix and pain induced behaviors and the effects of analgesics or pain treatments.

Published

2024

43. Peripheral neural mechanism of visceral pain and acupoint sensitization in 2, 4, 6-trinitrobenzene sulfonic acid-induced colitis model mice.

Author

Gao XY, Zhang N, Liu K, Xi HQ, Liu Y, He X, Han S, and Zhu B

Subjects

Mice, Animals, Calcium, Acupuncture Points, Mice, Inbred C57BL, Trinitrobenzenes, Mice, Transgenic, Visceral Pain genetics, Colitis chemically induced, Colitis genetics, Colorectal Neoplasms

Abstract

Objectives: To explore the neural mechanism of visceral pain and related somatic (acupoints) sensitization by using in vivo calcium imaging of dorsal root ganglia (DRG) neurons., Methods: Eight BALB/c mice were randomly divided into control and model groups, with 4 mice in each group. The colitis model was induced by colorectal perfusion of 2, 4, 6-trinitrobenzene sulfonic acid (TNBS) once daily for 7 days. Mice of the control group received colorectal perfusion of normal saline once daily for 7 days. The location and area of the somatic neurogenic inflammation (cutaneous exudation of Evans blue ［EB］) of the 2 groups of mice were observed after intravenous injection of EB. For pain behavioral tests, sixteen C57BL/6J mice were randomly divided into control and model groups, with 8 mice in each group, and a Von Frey filament was used to stimulate the referred somatic reactive regions in colitis mice, and the number of avoidance and paw withdraw reaction within 10 tests was recorded. For in vivo DRG calcium imaging tests, 24 Pirt -GCaMP6s transgenic mice were randomly and equally divided into control group and colitis model group. The responses of the neurons in L6 or L4 DRG to colorectal distension (CRD), lower back brushing, or mechanical stimulation at the hindpaw were observed using confocal fluorescence microscope., Results: Compared with the control group, the area of EB exudation spot in the hindpaw and lower back regions was increased in the colitis model group ( P <0.05), and the avoidance or paw withdraw numbers induced by Von Frey stimulation at the lower back and hindpaw were increased ( P <0.01, P <0.05), indicating that colitis induced regional skin (acupoints) sensitization in the lower back and hindpaw regions. Compared with the control group, the percentage of L6 DRG neurons activated by 60 mm Hg CRD in the colitis model mice were apparently increased ( P <0.01), the activated neurons mainly involved the medium-sized DRG neurons ( P <0.01). In Pirt -GCaMP6s transgenic mice, following brushing the skin of the receptive field (lower back) of L6 DRG neurons, the fluorescence intensity of the brushing-activated DRG neurons and small, medium and large-sized neurons were significantly higher in the colitis model group than those in the control group ( P <0.001, P <0.01, P <0.05). After brushing and clamping the skin of the right hindpaw (receptive field of L4 DRG neurons), the percentages of the activated L4 DRG neurons were obviously higher in the colitis model group than those in the control group ( P <0.01, P <0.05), while there were no significant changes in the proportion of small, medium and large-sized neurons between the control and colitis model groups., Conclusions: Colitis may lead to body surface sensitization at the same and adjacent neuro-segments as well as to an increase of the number and activity of the responsive lumbar DRG neurons, among which the L6 DRG neurons at the same neuro-segment as the rectum colon showed an increase in the number of responders and intensity of calcium fluorescence signal while L4 DRG neurons at the level adjacent to the rectum colon showed an increase in the number of responders, suggesting that there may be different mechanisms of peripheral neural sensitization.

Published

2023

44. Circuit Mechanisms of Neurodegenerative Diseases: A New Frontier With Miniature Fluorescence Microscopy.

Author

Werner, Craig T., Williams, Christopher J., Fermelia, Mercedes R., Lin, Da-Ting, and Li, Yun

Subjects

FLUORESCENCE microscopy, NEURODEGENERATION, HUNTINGTON disease, NEURAL circuitry, AMYOTROPHIC lateral sclerosis

Abstract

Neurodegenerative diseases (NDDs), such as Alzheimer's disease (AD), Parkinson's disease (PD), Huntington's disease (HD), amyotrophic lateral sclerosis (ALS), and frontotemporal dementia (FTD), are devastating age-associated brain disorders. Significant efforts have been made to uncover the molecular and cellular pathogenic mechanisms that underlie NDDs. However, our understanding of the neural circuit mechanisms that mediate NDDs and associated symptomatic features have been hindered by technological limitations. Our inability to identify and track individual neurons longitudinally in subcortical brain regions that are preferentially targeted in NDDs has left gaping holes in our knowledge of NDDs. Recent development and advancement of the miniature fluorescence microscope (miniscope) has opened up new avenues for examining spatially and temporally coordinated activity from hundreds of cells in deep brain structures in freely moving rodents. In the present mini-review, we examine the capabilities of current and future miniscope tools and discuss the innovative applications of miniscope imaging techniques that can push the boundaries of our understanding of neural circuit mechanisms of NDDs into new territories. [ABSTRACT FROM AUTHOR]

Published

2019

45. Reward learning improves social signal processing in autism model mice.

Author

Kim, Joowon, Jung, Min Whan, and Lee, Doyun

Abstract

Social and reward signal processing and their association are critical elements of social motivation. Despite the use of reward learning to improve the social interactions of patients with autism spectrum disorder (ASD), the underlying neural mechanisms are unknown. Here, we found different yet conjunct neuronal representations of social and reward signals in the mouse medial prefrontal cortex (mPFC). We also found that social signal processing is selectively disrupted, whereas reward signal processing is intact in the mPFC of Shank2 -knockout mice, a mouse model of ASD. Furthermore, reward learning not only allows Shank2 -knockout mice to associate social stimuli with reward availability, but it also rescues the impaired social signal processing. These findings provide insights into the neural basis for the therapeutic use of reward learning in ASD. [Display omitted] • Social and reward signals are conjunctly represented in the mPFC • Reward signal processing is intact in the mPFC of Shank2 −/− mice • Social signal processing is disrupted in the mPFC of Shank2 −/− mice • Reward learning restores impaired mPFC social signal processing in Shank2 −/− mice Kim et al. demonstrate that reward learning can restore impaired social signal processing in the medial prefrontal cortex of Shank2 -knockout mice. This finding suggests that reward-based behavioral therapy for autism has potential to enhance social signal processing at the neuronal level. [ABSTRACT FROM AUTHOR]

Published

2023

46. Neuropeptide Y neurons in nucleus accumbens lead to food addiction by appetitive food experience memory.

Author

YU-BEEN KIM, DEOK-HYEON CHEON, SANG-HO JUNG, JAESUN HA, LESLIE, BEAK, SOLIN, and HYUNG JIN CHOI

Subjects

*NEUROPEPTIDE Y, *NUCLEUS accumbens, *COMPULSIVE eating, *NEURONS, *FOOD habits, *MEMORY

Abstract

Food addiction is caused by the accumulation of pleasant memories associated with palatable foods. The nucleus accumbens (NAc) has been recognized as a prime center for the reward and addiction. However, the mechanism by which neurons in NAc controls food-specific memory, especially for palatable food, remains unknown. Here, we demonstrated that neuropeptide Y (NPY) neurons in NAc encode palatable food memory acqusition. Using calcium imaging, we found that the NAc NPY neurons respond to eating behavior. This response depended on the palatability of the food. More interestingly, we further demonstrated that the neural activity of NAc NPY increased as the learned value of reward-associated cues increased. Using optogenetics, we discovered that the NAc NPY neuronal activation significantly increased palatable food intake. Optogenetic activation of NAc NPY neurons showed food-specific positive valence in real-time place preference test with palatable food context. Furthermore, optogenetic activation of NAc NPY neurons served as an unconditioned stimulus for the formation of palatable food memory. In conclusion, these experiments provide strong evidence that NAc NPY encodes positive memory for palatable food. Our findings could lead to the development of novel therapeutic strategies to prevent and treat obesity and food addiction. [ABSTRACT FROM AUTHOR]

Published

2023

47. Metformin reverses early cortical network dysfunction and behavior changes in Huntington’s disease

Author

Isabelle Arnoux, Michael Willam, Nadine Griesche, Jennifer Krummeich, Hirofumi Watari, Nina Offermann, Stephanie Weber, Partha Narayan Dey, Changwei Chen, Olivia Monteiro, Sven Buettner, Katharina Meyer, Daniele Bano, Konstantin Radyushkin, Rosamund Langston, Jeremy J Lambert, Erich Wanker, Axel Methner, Sybille Krauss, Susann Schweiger, and Albrecht Stroh

Subjects

Huntington disease, in vivo calcium imaging, cortical microcircuits, neuronal hyperactivity, metformin, Medicine, Science, Biology (General), QH301-705.5

Abstract

Catching primal functional changes in early, ‘very far from disease onset’ (VFDO) stages of Huntington’s disease is likely to be the key to a successful therapy. Focusing on VFDO stages, we assessed neuronal microcircuits in premanifest Hdh150 knock-in mice. Employing in vivo two-photon Ca2+ imaging, we revealed an early pattern of circuit dysregulation in the visual cortex - one of the first regions affected in premanifest Huntington’s disease - characterized by an increase in activity, an enhanced synchronicity and hyperactive neurons. These findings are accompanied by aberrations in animal behavior. We furthermore show that the antidiabetic drug metformin diminishes aberrant Huntingtin protein load and fully restores both early network activity patterns and behavioral aberrations. This network-centered approach reveals a critical window of vulnerability far before clinical manifestation and establishes metformin as a promising candidate for a chronic therapy starting early in premanifest Huntington’s disease pathogenesis long before the onset of clinical symptoms.

Published

2018

48. A Flp-dependent G-CaMP9a transgenic mouse for neuronal imaging in vivo

Author

00777865, Sakamoto, Masayuki, Inoue, Masatoshi, Takeuchi, Atsuya, Kobari, Shigetaka, Yokoyama, Tatsushi, Horigane, Shin-ichiro, Takemoto-Kimura, Sayaka, Abe, Manabu, Sakimura, Kenji, Kano, Masanobu, Kitamura, Kazuo, Fujii, Hajime, Bito, Haruhiko, 00777865, Sakamoto, Masayuki, Inoue, Masatoshi, Takeuchi, Atsuya, Kobari, Shigetaka, Yokoyama, Tatsushi, Horigane, Shin-ichiro, Takemoto-Kimura, Sayaka, Abe, Manabu, Sakimura, Kenji, Kano, Masanobu, Kitamura, Kazuo, Fujii, Hajime, and Bito, Haruhiko

Abstract

Genetically encoded calcium indicators (GECIs) are widely used to measure calcium transients in neuronal somata and processes, and their use enables the determination of action potential temporal series in a large population of neurons. Here, we generate a transgenic mouse line expressing a highly sensitive green GECI, G-CaMP9a, in a Flp-dependent manner in excitatory and inhibitory neuronal subpopulations downstream of a strong CAG promoter. Combining this reporter mouse with viral or mouse genetic Flp delivery methods produces a robust and stable G-CaMP9a expression in defined neuronal populations without detectable detrimental effects. In vivo two-photon imaging reveals spontaneous and sensory-evoked calcium transients in excitatory and inhibitory ensembles with cellular resolution. Our results show that this reporter line allows long-term, cell-type-specific investigation of neuronal activity with enhanced resolution in defined populations and facilitates dissecting complex dynamics of neural networks in vivo.

Published

2022

49. Sodium-calcium exchanger-3 regulates pain “wind-up” : From human psychophysics to spinal mechanisms

Author

Trendafilova, Teodora, Adhikari, Kaustubh, Schmid, Annina B., Patel, Ryan, Polgár, Erika, Chisholm, Kim I., Middleton, Steven J., Boyle, Kieran, Dickie, Allen C., Semizoglou, Evangelia, Perez-Sanchez, Jimena, Bell, Andrew M., Ramirez-Aristeguieta, Luis Miguel, Khoury, Samar, Ivanov, Aleksandar, Wildner, Hendrik, Ferris, Eleanor, Chacón-Duque, Juan-Camilo, Sokolow, Sophie, Saad Boghdady, Mohamed A., Herchuelz, André, Faux, Pierre, Poletti, Giovanni, Gallo, Carla, Rothhammer, Francisco, Bedoya, Gabriel, Zeilhofer, Hanns Ulrich, Diatchenko, Luda, McMahon, Stephen B., Todd, Andrew J., Dickenson, Anthony H., Ruiz-Linares, Andres, Bennett, David L., Trendafilova, Teodora, Adhikari, Kaustubh, Schmid, Annina B., Patel, Ryan, Polgár, Erika, Chisholm, Kim I., Middleton, Steven J., Boyle, Kieran, Dickie, Allen C., Semizoglou, Evangelia, Perez-Sanchez, Jimena, Bell, Andrew M., Ramirez-Aristeguieta, Luis Miguel, Khoury, Samar, Ivanov, Aleksandar, Wildner, Hendrik, Ferris, Eleanor, Chacón-Duque, Juan-Camilo, Sokolow, Sophie, Saad Boghdady, Mohamed A., Herchuelz, André, Faux, Pierre, Poletti, Giovanni, Gallo, Carla, Rothhammer, Francisco, Bedoya, Gabriel, Zeilhofer, Hanns Ulrich, Diatchenko, Luda, McMahon, Stephen B., Todd, Andrew J., Dickenson, Anthony H., Ruiz-Linares, Andres, and Bennett, David L.

Abstract

Repeated application of noxious stimuli leads to a progressively increased pain perception; this temporal summation is enhanced in and predictive of clinical pain disorders. Its electrophysiological correlate is “wind-up,” in which dorsal horn spinal neurons increase their response to repeated nociceptor stimulation. To understand the genetic basis of temporal summation, we undertook a GWAS of wind-up in healthy human volunteers and found significant association with SLC8A3 encoding sodium-calcium exchanger type 3 (NCX3). NCX3 was expressed in mouse dorsal horn neurons, and mice lacking NCX3 showed normal, acute pain but hypersensitivity to the second phase of the formalin test and chronic constriction injury. Dorsal horn neurons lacking NCX3 showed increased intracellular calcium following repetitive stimulation, slowed calcium clearance, and increased wind-up. Moreover, virally mediated enhanced spinal expression of NCX3 reduced central sensitization. Our study highlights Ca2+ efflux as a pathway underlying temporal summation and persistent pain, which may be amenable to therapeutic targeting.

Published

2022

50. Sodium-calcium exchanger-3 regulates pain 'wind-up': From human psychophysics to spinal mechanisms

Author

Teodora Trendafilova, Kaustubh Adhikari, Annina B. Schmid, Ryan Patel, Erika Polgár, Kim I. Chisholm, Steven J. Middleton, Kieran Boyle, Allen C. Dickie, Evangelia Semizoglou, Jimena Perez-Sanchez, Andrew M. Bell, Luis Miguel Ramirez-Aristeguieta, Samar Khoury, Aleksandar Ivanov, Hendrik Wildner, Eleanor Ferris, Juan-Camilo Chacón-Duque, Sophie Sokolow, Mohamed A. Saad Boghdady, André Herchuelz, Pierre Faux, Giovanni Poletti, Carla Gallo, Francisco Rothhammer, Gabriel Bedoya, Hanns Ulrich Zeilhofer, Luda Diatchenko, Stephen B. McMahon, Andrew J. Todd, Anthony H. Dickenson, Andres Ruiz-Linares, and David L. Bennett

Subjects

in vivo electrophysiology, General Neuroscience, Pain, spinal cord, central sensitization, in vivo calcium imaging, Sodium-Calcium Exchanger, Posterior Horn Cells, Mice, temporal summation, Psychophysics, wind-up, Animals, Humans, GWAS, Calcium, pain

Abstract

Repeated application of noxious stimuli leads to a progressively increased pain perception; this temporal summation is enhanced in and predictive of clinical pain disorders. Its electrophysiological correlate is “wind-up,” in which dorsal horn spinal neurons increase their response to repeated nociceptor stimulation. To understand the genetic basis of temporal summation, we undertook a GWAS of wind-up in healthy human volunteers and found significant association with SLC8A3 encoding sodium-calcium exchanger type 3 (NCX3). NCX3 was expressed in mouse dorsal horn neurons, and mice lacking NCX3 showed normal, acute pain but hypersensitivity to the second phase of the formalin test and chronic constriction injury. Dorsal horn neurons lacking NCX3 showed increased intracellular calcium following repetitive stimulation, slowed calcium clearance, and increased wind-up. Moreover, virally mediated enhanced spinal expression of NCX3 reduced central sensitization. Our study highlights Ca2+ efflux as a pathway underlying temporal summation and persistent pain, which may be amenable to therapeutic targeting., Neuron, 110 (16)

Published

2022