Collateral connectomes of Esr1-positive hypothalamic neurons modulate defensive behavior plasticity
2025-01-11, bioRxiv (10.1101/2025.01.10.632334) (online) (PDF)Veronika Csillag, Chiara Forastieri, Greta Martina Szucs, Ines Talaya Vidal, Marianne Bizzozzero Hiriart, Luke D. Lavis, Daniela Calvigioni, and Janos Fuzik (?)
The ventromedial hypothalamus (VMH) projects to the periaqueductal gray (PAG) and anterior hypothalamic nucleus (AHN), mediating freezing and escape behaviors, respectively. We investigated VMH collateral (VMH-coll) neurons, which innervate both PAG and AHN, to elucidate their role in postsynaptic processing and defensive behavior plasticity. Using all-optical voltage imaging of 22,151 postsynaptic neurons ex vivo, we found that VMH-coll neurons engage inhibitory mechanisms at both synaptic ends and can induce synaptic circuit plasticity. In vivo optogenetic activation of the VMH-coll somas induced escape behaviors. We identified an Esr1-expressing VMH-coll subpopulation with postsynaptic connectome resembling that of wild-type collaterals on the PAG side. Activation of Esr1+VMH-coll neurons evoked freezing and unexpected flattening behavior, previously not linked to the VMH. Neuropeptides such as PACAP and dynorphin modulated both Esr1+VMH-coll connectomes. In vivo kappa-opioid receptor antagonism impaired Esr1+VMH-coll-mediated defensive behaviors. These findings unveiled the central role of VMH-coll pathways in innate defensive behavior plasticity.
Added on Tuesday, January 14, 2025. Currently included in 1 curations.
0
FXR1 Deletion from Cortical Parvalbumin Interneurons Modifies their Excitatory Synaptic Responses.
2025-01-03, eNeuro (10.1523/ENEURO.0363-24.2024) (online)Katherine S Scheuer, Anna M Jansson, Minjie Shen, Xinyu Zhao, and Meyer B Jackson (?)
Fragile X autosomal homolog 1 (FXR1), a member of the fragile X messenger riboprotein 1 family, has been linked to psychiatric disorders including autism and schizophrenia. Parvalbumin (PV) interneurons play critical roles in cortical processing, and have been implicated in FXR1-linked mental illnesses. Targeted deletion of FXR1 from PV interneurons in mice has been shown to alter cortical excitability and elicit schizophrenia-like behavior. This indicates that FXR1 regulates behaviorally relevant electrophysiological functions in PV interneurons. We therefore expressed a genetically-encoded hybrid voltage sensor in PV interneurons, and used voltage imaging in slices of mouse somatosensory cortex to assess the impact of targeted FXR1 deletion. These experiments showed that PV interneurons lacking FXR1 had excitatory synaptic potentials with larger amplitudes and shorter latencies compared to wild type. Synaptic potential rise-times, decay-times, and half-widths were also impacted to degrees that varied between cortical layer and synaptic input. Thus, FXR1 modulates the responsiveness of PV interneurons to excitatory synaptic inputs. This will enable FXR1 to control cortical processing in subtle ways, with the potential to influence behavior and contribute to psychiatric dysfunction. Parvalbumin interneurons have been implicated in schizophrenia and autism. The RNA binding protein FXR1, a member of the fragile X protein family has been linked to mental illnesses and disabilities. Voltage imaging from parvalbumin interneurons in cortical slices revealed that targeted ablation of FXR1 from these neurons alters the amplitude and dynamics of their excitatory synaptic responses. These changes have the potential to alter circuit processing and behavior, and may be relevant to FXR1-linked mental illnesses.
Added on Friday, January 10, 2025. Currently included in 1 curations.
0
Photophysics-informed two-photon voltage imaging using FRET-opsin voltage indicators.
2025-01-08, Science Advances (10.1126/sciadv.adp5763) (online)F Phil Brooks, Daozheng Gong, Hunter C Davis, Pojeong Park, Yitong Qi, and Adam E Cohen (?)
Microbial rhodopsin-derived genetically encoded voltage indicators (GEVIs) are powerful tools for mapping bioelectrical dynamics in cell culture and in live animals. Förster resonance energy transfer (FRET)-opsin GEVIs use voltage-dependent quenching of an attached fluorophore, achieving high brightness, speed, and voltage sensitivity. However, the voltage sensitivity of most FRET-opsin GEVIs has been reported to decrease or vanish under two-photon (2P) excitation. Here, we investigated the photophysics of the FRET-opsin GEVIs Voltron1 and Voltron2. We found that the previously reported negative-going voltage sensitivities of both GEVIs came from photocycle intermediates, not from the opsin ground states. The voltage sensitivities of both GEVIs were nonlinear functions of illumination intensity; for Voltron1, the sensitivity reversed the sign under low-intensity illumination. Using photocycle-optimized 2P illumination protocols, we demonstrate 2P voltage imaging with Voltron2 in the barrel cortex of a live mouse. These results open the door to high-speed 2P voltage imaging of FRET-opsin GEVIs in vivo.
Added on Friday, January 10, 2025. Currently included in 1 curations.
0
Synchronous ensembles of hippocampal CA1 pyramidal neurons associated with theta but not ripple oscillations during novel exploration
2025-01-02, bioRxiv (10.1101/2024.02.07.579313) (online) (PDF)Eric R Schreiter, En-Li Chen, Tsai-Wen Chen, and Bei-Jung Lin (?)
Synchronous neuronal ensembles play a pivotal role in the consolidation of long-term memory in the hippocampus. However, their organization during the acquisition of spatial memory remains less clear. In this study, we used neuronal population voltage imaging to investigate the synchronization patterns of CA1 pyramidal neuronal ensembles during the exploration of a new environment, a critical phase for spatial memory acquisition. We found synchronous ensembles comprising approximately 40% of CA1 pyramidal neurons, firing simultaneously in brief windows (~25ms) during immobility and locomotion in novel exploration. Notably, these synchronous ensembles were not associated with ripple oscillations but were instead phase-locked to local field potential theta waves. Specifically, the subthreshold membrane potentials of neurons exhibited coherent theta oscillations with a depolarizing peak at the moment of synchrony. Among newly formed place cells, pairs with more robust synchronization during locomotion displayed more distinct place-specific activities. These findings underscore the role of synchronous ensembles in coordinating place cells of different place fields.
Added on Wednesday, January 8, 2025. Currently included in 1 curations.
0
Exploring Bioelectricity with Ace2N-mNeon during Zebrafish Embryogenesis
2024-12-17, bioRxiv (10.1101/2024.12.12.628143) (PDF)Zhenzhen Wu, Rui Oliveira Silva, Ruya Hoessein, Fabiola Marques Trujillo, Jordan Gotti, Srividya Ganapathy, Zhenyu Gao, and Daan Brinks (?)
Bioelectricity is a fundamental biophysical phenomenon present in all cells, playing a crucial role in embryogenesis by regulating processes such as neuronal signaling, pattern formation, and cancer suppression. Precise monitoring of bioelectric signals and their dynamic changes throughout development is vital for advancing our understanding of higher organisms. However, the lack of suitable techniques for mapping bioelectric signals during early development has greatly limited our ability to interpret these mechanisms. To address this challenge, we developed an Ace2N-mNeon expression library in zebrafish, which exhibits membrane localization from 4 hours post-fertilization to at least 5 days post-fertilization and broad expression across multiple cell types throughout development. We validated the use of this library for studying bioelectric changes via voltage imaging to record signals in neurons and cardiomyocytes at different development stages. Through this approach, we found evidence of synchronized neuronal activity during early embryogenesis and observed faster voltage dynamics in cardiomyocytes as development progressed. Our results show that the Ace2N-mNeon library is a valuable tool for developmental bioelectric studies supporting advanced techniques such as voltage imaging and fluorescence lifetime imaging (FLIM). These methods enable non-invasive, dynamic monitoring of bioelectric signals across diverse cell types throughout development, significantly surpassing the capabilities of current electrophysiological techniques.
Added on Wednesday, December 18, 2024. Currently included in 1 curations.
0
Page 1
< older
Progress in Voltage Imaging
Curated by Matthijs Dorst, University of Oslo
Updates continuously
RSS feed:
Copied to clipboard!
Recent advances in the field of Voltage Imaging, with a special focus on new constructs and novel implementations.
There are 17 articles included in this curation. |
subscribe
|
This curation is public. Please feel free to share it!