Your search keyword '"Olivier Gschwend"' showing total 8 results

1. Disruption of Kcc2-dependent inhibition of olfactory bulb output neurons suggests its importance in odour discrimination

Author

Kathrin Gödde, Olivier Gschwend, Dmytro Puchkov, Carsten K. Pfeffer, Alan Carleton, and Thomas J. Jentsch

Subjects

Science

Abstract

Synaptic inhibition in the olfactory bulb (OB) is believed to play a role in odour processing. Here, the authors use a Pcdh21-driven Cre-line to disrupt KCC2 expression in OB mitral cells and find altered synaptic connectivity along with disrupted separation of odour-induced activity patterns.

Published

2016

2. Encoding odorant identity by spiking packets of rate-invariant neurons in awake mice.

Author

Olivier Gschwend, Jonathan Beroud, and Alan Carleton

Subjects

Medicine, Science

Abstract

How do neural networks encode sensory information? Following sensory stimulation, neural coding is commonly assumed to be based on neurons changing their firing rate. In contrast, both theoretical works and experiments in several sensory systems showed that neurons could encode information as coordinated cell assemblies by adjusting their spike timing and without changing their firing rate. Nevertheless, in the olfactory system, there is little experimental evidence supporting such model.To study these issues, we implanted tetrodes in the olfactory bulb of awake mice to record the odorant-evoked activity of mitral/tufted (M/T) cells. We showed that following odorant presentation, most M/T neurons do not significantly change their firing rate over a breathing cycle but rather respond to odorant stimulation by redistributing their firing activity within respiratory cycles. In addition, we showed that sensory information can be encoded by cell assemblies composed of such neurons, thus supporting the idea that coordinated populations of globally rate-invariant neurons could be efficiently used to convey information about the odorant identity. We showed that different coding schemes can convey high amount of odorant information for specific read-out time window. Finally we showed that the optimal readout time window corresponds to the duration of gamma oscillations cycles.We propose that odorant can be encoded by population of cells that exhibit fine temporal tuning of spiking activity while displaying weak or no firing rate change. These cell assemblies may transfer sensory information in spiking packets sequence using the gamma oscillations as a clock. This would allow the system to reach a tradeoff between rapid and accurate odorant discrimination.

Published

2012

3. Prefrontal top-down projections control context-dependent strategy selection

Author

Olivier Gschwend, Tao Yang, Daniëlle van de Lisdonk, Xian Zhang, Radhashree Sharma, and Bo Li

Abstract

The rules governing behavior often vary with behavioral contexts. As a consequence, an action rewarded in one context may be discouraged in another. Animals and humans are capable of switching between behavioral strategies under different contexts and acting adaptively according to the variable rules, a flexibility that is thought to be mediated by the prefrontal cortex (PFC)1–4. However, how the PFC orchestrates context-dependent switch of strategies remains unclear. Here we show that pathway-specific projection neurons in the medial PFC (mPFC) differentially contribute to context-instructed strategy selection. In a decision-making task in which mice have been trained to flexibly switch between a previously established rule and a newly learned rule in a context-dependent manner, the activity of mPFC neurons projecting to the dorsomedial striatum encodes the contexts, and further represents decision strategies conforming to the old and new rules. Moreover, the activity of these neuron is required for context-instructed strategy selection. In contrast, the activity of mPFC neurons projecting to the ventral midline thalamus does not discriminate between the contexts, and represents the old rule even if mice have adopted the new one; furthermore, these neurons act to prevent the strategy switch under the new rule. Our results suggest that the mPFC→striatum pathway promotes flexible strategy selection guided by contexts, whereas the mPFC→thalamus pathway favors fixed strategy selection by preserving old rules. Balanced activity between the two pathways may be critical for adaptive behaviors.

Published

2021

4. The claustrum-medial prefrontal cortex network controls attentional set-shifting

Author

Roberta Leone, Rodrigo F. Salazar, Kazadi Ekundayo, Jean-Rodolphe Renfer, Chieko Huber, Alan Carleton, Sophie Mutel, Leon Fodoulian, Ivan Rodriguez, and Olivier Gschwend

Subjects

0303 health sciences, integumentary system, food and beverages, Cognition, Claustrum, Attentional set, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, nervous system, Cortex (anatomy), medicine, Excitatory postsynaptic potential, lipids (amino acids, peptides, and proteins), Psychology, Prefrontal cortex, Neuroscience, Nucleus, psychological phenomena and processes, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SUMMARYIn various mental disorders, dysfunction of the prefrontal cortex contributes to cognitive deficits. Here we studied how the claustrum (CLA), a nucleus sharing reciprocal connections with the cortex, may participate in these cognitive impairments. We show that specific ensembles of CLA and of medial prefrontal cortex (mPFC) neurons are activated during a task requiring cognitive control such as attentional set-shifting, i.e. the ability to shift attention towards newly relevant stimulus-reward associations while disengaging from irrelevant ones. CLA neurons exert a direct excitatory input on mPFC pyramidal cells, and chemogenetic inhibition of CLA neurons suppresses the formation of specific mPFC assemblies during attentional set-shifting. Furthermore, impairing the recruitment of specific CLA assemblies through opto/chemogenetic manipulations prevents attentional set-shifting. In conclusion, we propose that the CLA controls the reorganization of mPFC ensembles to enable attentional set-shifting, emphasizing a potential role of the CLA-mPFC network in attentional dysfunctions.

Published

2020

5. Neuronal pattern separation in the olfactory bulb improves odor discrimination learning

Author

Frédéric Begnaud, Samuel Lagier, Nixon M. Abraham, Olivier Gschwend, Ivan Rodriguez, and Alan Carleton

Subjects

Male, Olfactory system, Sensory processing, medicine.medical_treatment, Sensory system, Optogenetics, Article, Discrimination Learning, Mice, ddc:590, medicine, Animals, Learning, optogenetics, Behavior, Microscopy, Confocal, head-restrained behavior, General Neuroscience, Odor discrimination, Olfactory Pathways, in-vivo extracellular recording, Olfactory Perception, Immunohistochemistry, Olfactory Bulb, Olfaction, Olfactory stimulus, ddc:616.8, Olfactory bulb, Mice, Inbred C57BL, Chemogenetic, Population coding, odorant mixture, Pattern separation, GABAergic, Optogenetic, Psychology, Neuroscience

Abstract

Neuronal pattern separation is thought to enable the brain to disambiguate sensory stimuli with overlapping features, thereby extracting valuable information. In the olfactory system, it remains unknown whether pattern separation acts as a driving force for sensory discrimination and the learning thereof. We found that overlapping odor-evoked input patterns to the mouse olfactory bulb (OB) were dynamically reformatted in the network on the timescale of a single breath, giving rise to separated patterns of activity in an ensemble of output neurons, mitral/tufted (M/T) cells. Notably, the extent of pattern separation in M/T assemblies predicted behavioral discrimination performance during the learning phase. Furthermore, exciting or inhibiting GABAergic OB interneurons, using optogenetics or pharmacogenetics, altered pattern separation and thereby odor discrimination learning in a bidirectional way. In conclusion, we propose that the OB network can act as a pattern separator facilitating olfactory stimulus distinction, a process that is sculpted by synaptic inhibition.

Published

2015

6. Dense encoding of natural odorants by ensembles of sparsely activated neurons in the olfactory bulb

Author

Olivier Gschwend, Ivan Rodriguez, Roberto Vincis, Jonathan Beroud, and Alan Carleton

Subjects

0301 basic medicine, Male, Sensory Receptor Cells, Speech recognition, T cell, Population, Sensory system, Receptors, Odorant, Article, Tonic (physiology), 03 medical and health sciences, Mice, 0302 clinical medicine, Olfactory bulb, ddc:590, medicine, Animals, education, Tetrode (biology), Evoked Potentials, education.field_of_study, Multidisciplinary, Chemistry, Coding, musculoskeletal, neural, and ocular physiology, Olfactory Perception, Olfactory Bulb, ddc:616.8, 030104 developmental biology, medicine.anatomical_structure, Rate change, Odorants, Biophysics, Cell assembly, 030217 neurology & neurosurgery, psychological phenomena and processes

Abstract

Sensory information undergoes substantial transformation along sensory pathways, usually encompassing sparsening of activity. In the olfactory bulb, though natural odorants evoke dense glomerular input maps, mitral and tufted (M/T) cells tuning is considered to be sparse because of highly odor-specific firing rate change. However, experiments used to draw this conclusion were either based on recordings performed in anesthetized preparations or used monomolecular odorants presented at arbitrary concentrations. In this study, we evaluated the lifetime and population sparseness evoked by natural odorants by capturing spike temporal patterning of neuronal assemblies instead of individual M/T tonic activity. Using functional imaging and tetrode recordings in awake mice, we show that natural odorants at their native concentrations are encoded by broad assemblies of M/T cells. While reducing odorant concentrations, we observed a reduced number of activated glomeruli representations and consequently a narrowing of M/T tuning curves. We conclude that natural odorants at their native concentrations recruit M/T cells with phasic rather than tonic activity. When encoding odorants in assemblies, M/T cells carry information about a vast number of odorants (lifetime sparseness). In addition, each natural odorant activates a broad M/T cell assembly (population sparseness).

Published

2016

7. Temporal Coding in Olfaction

Author

Brice Bathellier, Olivier Gschwend, and Alan Carleton

Subjects

0303 health sciences, 03 medical and health sciences, 0302 clinical medicine, 030217 neurology & neurosurgery, 030304 developmental biology, ddc:616.8

Abstract

Knowledge about the molecular organization principles of the sense of smell in different species has greatly improved in the last decade (Bargmann 2006; Mombaerts 2004a, 2004b; Rodriguez 2007). It is now well established that in many species, odorant molecules are detected by large families of G-protein-coupled receptors (Buck and Axel 1991), whose molecular sequence and structure may vary across species and phyla, but that essentially implement the same function (Bargmann 2006). Interestingly, the insect olfactory receptors display a unique and unconventional membrane topology in comparison to the mammalian receptors, questioning the existence of a coupling with G-proteins (Benton et al. 2006; Vosshall and Stocker 2007). Nevertheless, understanding how odorant information generated by these large arrays of receptors is interpreted by the brain to produce a great variety of behaviors will be the challenge of the next decade. A few questions, which may appear basic with regard to the complexity of the entire olfactory system, are still not answered. Among these, how olfactory information is encoded in brain networks downstream to receptors, remains poorly understood. In recent years, there have been strong debates on this question and it seems that the answer is not as simple as recording from the neurons of these networks. The ambition of this chapter is not to provide a definitive answer, but to present the most relevant results on this question and put them in perspective, helping the reader to appreciate where the field stands in terms of olfactory coding. Since a certain similarity in the olfactory system organization has been observed across species (Kay and Stopfer 2006), we will endeavor to compare between different animal models. Our focus will primarily be on temporal coding, as temporal dynamics, in our opinion, are currently the main aspect of neuronal activity in the olfactory system that is difficult to integrate in a convincing and unanimously recognized theory of olfactory coding.

Published

2010

8. A population of glomerular glutamatergic neurons controls sensory information transfer in the mouse olfactory bulb

Author

Ivan Rodriguez, Roberta Tatti, Alan Carleton, Robert H. Edwards, Olivier Gschwend, Rebecca P. Seal, and Khaleel Bhaukaurally

Subjects

Olfactory perception, Olfactory system, Sensory Receptor Cells, Amino Acid Transport Systems, Acidic, Population, Sensation, General Physics and Astronomy, Sensory system, vesicular glutamate transporter, Mice, Transgenic, Biology, General Biochemistry, Genetics and Molecular Biology, Mouse Olfactory Bulb, Article, Glutamatergic, Mice, channelrhodopsin, ddc:590, parasitic diseases, Transgenic mice, Animals, GABAergic Neurons, education, education.field_of_study, Multidisciplinary, General Chemistry, Anatomy, Olfactory Pathways, Olfactory Perception, Olfaction, Olfactory Bulb, ddc:616.8, Olfactory bulb, serotonin, Electrophysiological Phenomena, Mice, Inbred C57BL, nervous system, Vesicular glutamate transporter, Odorants, external tufted cells, Optogenetic, Neuroscience, olfaction

Abstract

In sensory systems, peripheral organs convey sensory inputs to relay networks where information is shaped by local microcircuits before being transmitted to cortical areas. In the olfactory system, odorants evoke specific patterns of sensory neuron activity which are transmitted to output neurons in olfactory bulb glomeruli. How sensory information is transferred and shaped at this level remains still unclear. Here we employ mouse genetics, 2-photon microscopy, electrophysiology and optogenetics, to identify a novel population of glutamatergic neurons (VGLUT3+) in the glomerular layer of the adult mouse olfactory bulb as well as several of their synaptic targets. Both peripheral and serotoninergic inputs control VGLUT3+ neurons firing. Furthermore, we show that VGLUT3+ neurons photostimulation in vivo strongly suppresses both spontaneous and odor-evoked firing of bulbar output neurons. In conclusion, we identify and characterize here a microcircuit controlling the transfer of sensory information at an early stage of the olfactory pathway.

Published

2014