Our new #preprint on #ThreePhoton in vivo #imaging of #neurons and #glia 🔬 in the medial prefrontal cortex (#mPFC) 🧠with sub-cellular resolution 🔍 is out! Check it out on #biorxiv:
🌍 https://www.biorxiv.org/content/10.1101/2024.08.28.610026v1
#Neuroscience #multiphoton #3p vs. #2p #twophoton #hippocampus #drosophila #MouseModel #DeepImaging #preprintalert #DZNE @dzne
🔬 Tobias Rose (@trose_neuro) has an exciting open #PhDPosition. Research "Encoding Landmark Stability & Stability of Landmark Encoding" with cutting-edge miniature #TwoPhoton Ca2+ imaging. Uncover #NeuronalRepresentation during #behavior for robust #navigation.
From:
https://neuromatch.social/@trose_neuro/110865622824073881
Hi all, Our research group “Circuit Mechanisms of Behavior” at the University Hospital Bonn (lab Tobias Rose) invites applications for a full-time (38.5 hours/week) position as: Postdoctoral Researcher (m/f/d): Detailed description here: https://www.nature.com/naturecareers/job/12803739/postdoctoral-researcher-mfd Closing date: 31st of August 2023 Start date: flexible Contact: Tobias Rose, [email protected] The selected candidate will investigate the "Encoding of Landmark Stability and Stability of Landmark Encoding”: You will study visual landmark encoding at the intersection of hippocampal, thalamic, and cortical inputs to retrosplenial cortex. You will use cutting-edge miniature two-photon Ca2+ imaging (https://tinyurl.com/mini2pCA1), enabling you to longitudinally record activity in defined, large neuronal populations and long-range afferents in freely moving animals. You will carry out rigorous neuronal and behavioral analyses within the confines of automatized closed-loop tasks tailored for visual navigation. This will involve the application of advanced tools for dense behavioral quantification, including multi-angle videography, inertial motion sensing, and egocentric recording with head-mounted cameras for the reconstruction of retinal input. Our aim is to gain a comprehensive understanding of the immediate and sustained multi-area neuronal representation of visual landmarks during unrestricted behavior. We aim to elucidate the mechanisms through which stable visual landmarks are encoded and the processes by which these representations are stabilized to facilitate robust allocentric navigation. Ideal candidates for this position should hold a doctorate in neuroscience, engineering, physics, or a related discipline, and should be deeply committed to rigorous neuroethology and technical development. We seek individuals with a "tinkering spirit", i.e., a strong penchant for problem-solving and creativity. Essential competencies include the demonstrated ability to design and carry out complex neuroscience experiments, robust programming capabilities, and a foundational knowledge of machine learning methodologies. Valuable experience would include a familiarity with rodent behavior, both in freely moving and head-fixed contexts. Although not mandatory, a background in visual neuroscience or navigation neuroscience would be viewed favorably. We are looking for a driven candidate with a solid record of accomplishment who is enthusiastic about interdisciplinary research. The successful candidate will be prepared to bring their skills and experience to our innovative and collaborative research environment. While this role is tailored towards a specific project, we are equally enthusiastic about supporting the development of your individual research pursuits. Applicants should send their application in a single pdf file, including a cover letter explaining your research interests and motivation for joining the team, CV, and contact information for two references. Applications will be shortlisted based on the above selection criteria. Please send your formal application to Prof. Tobias Rose via email until 31.08.2023. The Expected start date is September 2023 or at the earliest possible date thereafter. Informal enquires about the post are welcome. For more information on our research, please visit www.troselab.de (mastodon: @trose_neuro, twitter: @trose_neuro).
Equipment question for those of you doing #twophoton imaging: anyone using a fixed wavelength laser from Axon / Toptica / Spark Lasers? Any recommendations / horror stories would be most welcome, as would boosts. I really don't want to ask over there. Maybe @MatteoCarandini @sls? Thx!
If you have no idea what I'm talking about:
https://www.coherent.com/lasers/oscillators/axon
https://www.toptica.com/products/psfs-fiber-lasers/femtofiber-ultra/femtofiber-ultra-920
https://spark-lasers.com/produit/alcor/
are #lasers for #biology #microscopy
"Functional cell types in the mouse superior colliculus", Li & Meister 2023 at #eLife @eLife
"we recorded from mouse superficial SC neurons under a battery of visual stimuli including those used for classification of RGCs [retinal ganglion cells]. An unsupervised clustering algorithm identified 24 functional types based on their visual responses."
"Compared to the retina, the visual representation in the SC has lower dimensionality, consistent with a sifting process along the visual pathway."
"Our understanding of thymic blood vascular hemodynamics is limited due to technical challenges associated with accessing the native thymus in live mice. To overcome this challenge, we developed an intravital two-photon imaging method to visualize the native thymus in vivo and investigated functional changes to the vascular system following sublethal irradiation."
#Preprint
#Immunology #TwoPhoton #Intravital
https://www.biorxiv.org/content/10.1101/2023.04.10.536267v1?med=mas
🔥​​🔥​🔥​ PREPRINT ALERT 🔥​🔥​🔥​
https://doi.org/10.1101/2023.03.09.531869
We used dual-colour in vivo #twophoton #imaging and #optogenetics to learn what information the #brain ’s dorsal #hippocampus sends to #NucleusAccumbens while mice navigated to a learned #reward site. What did we learn…?
While we often like to think of memories as abstract mental states, they actually serve a key role for our survival and that of our ancient ancestors: Remember where there’s a dangerous place and you can avoid it; remember where there’s food and you won’t go hungry.
But how do we go from the memory of a food location to actually approaching it when we’re hungry? We know that dorsal hippocampus (dHPC) is one of the main “memory storage” sites in the brain and important for navigation, but who sits on the receiving end of this information?
Many great colleagues (like @[email protected], @marisosa @[email protected],…) have highlighted the role of projections into the nucleus accumbens (NAc), part of the basal ganglia (BG). The BG’s role revolves around action selection, while the NAc largely deals w/ reward processing.
So we know that this dHPC>NAc pathway is needed for linking rewards with locations, but what does the HPC actually tell the NAc? What would we see if we could listen in on their private conversations? As it turns out, this is technically quite challenging because we need to combine cell identity (NAc-projecting or not) with cell activity. To achieve this, we turned to dual-colour two-photon calcium imaging. We labelled NAc-projecting neurons in red and used a pan-neuronal green calcium indicator to see live neural activity in dHPC.
We trained mice to lick in a reward zone on a cued linear treadmill to receive condensed milk which they absolutely love. After 5 days, they expertly slowed down and licked ahead of this reward zone, showing us they learned this space~reward association.
So what happens inside dHPC while mice navigate to this reward location? We hypothesised that either dHPC>NAc cells would be mostly active at the reward zone, or that they would show no spatial bias. As it turned out, neither were true…
Instead, we found that dHPC>NAc neurons showed stronger spatial tuning compared to those dHPC neurons projecting elsewhere (dHPC-). They were also more strongly modulated by the texture cues we provided, suggesting privileged spatial information routing to the NAc.
What about the reward zone though? Many previous studies found place cells clustering near reward zones. When we first looked at the data, we saw little evidence of this (sad emoji), but we noticed some mice performed better than others. When we separated high- from low-success trials, we could see the reward zone being overrepresented by place cells – this effect was particularly pronounced for dHPC>NAc neurons. We could also show that these projection neurons are better at decoding the spatial location ahead of the reward zone.
This suggests that it may be less the sensory environment that determines neural coding but the behaviour with which the mouse engages with it. This is a realisation that has swept across the neurosciences: neural activity in most brain regions seems modulated by behaviour.
Better performance usually goes in hand with deceleration as mice approach the reward zone. So do neurons “care” about speed? We found neurons that were either positively (acceleration) or negatively (deceleration) modulated by speed, as others before us. Interestingly, negatively speed-modulated neurons were overrepresented in the dHPC>NAc population, suggestive of a role in reward approach. To actually obtain the reward, mice not only needed to remember the reward zone but also needed to lick there. Strikingly, we saw that dHPC>NAc neurons became very active around the time of appetitive (but not consummatory) licking. Also, if we zoom in on the activity of individual neurons, we saw a larger proportion of dHPC>NAc neurons tuned to appetitive licking.
Does this mean that dHPC>NAc projections could “guide” the mouse’s lick activity, or do they simply receive a motor signal from elsewhere? To test this, we optogenetically activated excitatory dHPC axons in NAc after mice learned to lick for rewards.
We found that upon stimulation of this projection, mice actually started to engage in appetitive licking. This suggests that dHPC>NAc projections seem to indeed be in the driver’s seat for reward-seeking behaviours.
How can we reconcile this with our previous findings of enhanced spatial and (negative) velocity tuning? Are there separate populations for each of these aspects or do we have “multi-tasker” neurons that can do it all?
Answering this question is not trivial because, as mice approached the reward zone (space), they tended to slow down (speed) and start licking, resulting in a lot of “collinearity” in the behavioural data. To tackle this, we built computational models (GLMs) to predict neural activity based on space, speed, and lick data. We then randomly shuffled each behavioural variable to see if our models got worse. With this approach, we found that indeed dHPC>NAc neurons were more heavily tuned to space, speed, and licking, but we also found many neurons that encoded multiple behavioural features. Indeed, among the dHPC>NAc population, this seemed to be the norm rather than the exception. We tend to cherish those one-on-one relationships like position~activity (place cells) or speed~activity (speed cells), but computationally, such mixed selectivity or conjunctive coding has been suggested to help downstream brain regions to decode action-relevant stimuli. We show that the dHPC routes a strongly conjunctive code to the action-selection relevant basal ganglia (specifically, NAc).
Indeed, we find that conjunctive coding neurons improve the performance of a linear decoder tasked with identifying the reward zone. This raises the possibility that the dHPC routes enhanced conjunctive information to action-specific brain regions such as the NAc.
Overall, we show that dHPC routes an enhanced conjunctive code of space, speed, and lick information to NAc, and that this code can guide goal-directed appetitive behaviour such as licking.
I was fortunate to be joined in this work by @petra_moce and for the unwavering support from @[email protected] and @dzne @[email protected], and @[email protected], as well as funding from @ERC_Research @dfg_public and #sfb_1089. Feel free to send comments and questions! 25/25
Also, if you're coming to NWG in Göttingen next week, please feel free to hit me up at poster ***T25-19A*** Wednesday 1-1:45pm (or write me to meet up).
Genetically encoded calcium indicators are becoming available in social insects.
After the first expression in honeybees (https://www.biorxiv.org/content/10.1101/2022.04.22.489138v2), now the first GCaMP-expressing ants have been created and used to study the coding of alarm pheromones in the antennal lobe.
#GECIs #GCaMP #twophoton #neuroscience #ants #olfaction #antennallobe #pheromones
đź‘‹
I do #NeuroScience and am interested in the #Circuit dynamics of adaptive but reliable visually guided #Behavior.
In our group at the University of #Bonn, we study
- the stabilization of the neural code in #Vision, #Perception, #Learning, and #Memory
- the pathway-specific processing of #Sensory and #SelfMotion signals
We emphasize ethologically relevant behavior, longitudinal #Optophysiology, and miniaturized and benchtop #TwoPhoton microscopy.
www.troselab.de
🫡
"NIT: an open-source tool for information theoretic analysis of neural population data"
https://www.biorxiv.org/content/10.1101/2022.12.11.519966v1
#Neuroscience #Neuro #Brain #DataAnalysis #InformationTheory #TwoPhoton #CalciumImaging
Fabrizio Musacchio
David Schoppik
Albert Cardona
Thiago Carvalho
Oliver Barnstedt
NeurophysicsLab Albrecht Haase
Tobias Rose
Dominic Boutet
Simon Schultz