Your search keyword '"Oberlaender, Marcel"' showing total 5 results

1. Circuit-selective cell-autonomous regulation of inhibition in pyramidal neurons by Ste20-like kinase.

Author

Royero, Pedro, Quatraccioni, Anne, Früngel, Rieke, Silva, Mariella Hurtado, Bast, Arco, Ulas, Thomas, Beyer, Marc, Opitz, Thoralf, Schultze, Joachim L., Graham, Mark E., Oberlaender, Marcel, Becker, Albert, Schoch, Susanne, and Beck, Heinz

Abstract

Maintaining an appropriate balance between excitation and inhibition is critical for neuronal information processing. Cortical neurons can cell-autonomously adjust the inhibition they receive to individual levels of excitatory input, but the underlying mechanisms are unclear. We describe that Ste20-like kinase (SLK) mediates cell-autonomous regulation of excitation-inhibition balance in the thalamocortical feedforward circuit, but not in the feedback circuit. This effect is due to regulation of inhibition originating from parvalbumin-expressing interneurons, while inhibition via somatostatin-expressing interneurons is unaffected. Computational modeling shows that this mechanism promotes stable excitatory-inhibitory ratios across pyramidal cells and ensures robust and sparse coding. Patch-clamp RNA sequencing yields genes differentially regulated by SLK knockdown, as well as genes associated with excitation-inhibition balance participating in transsynaptic communication and cytoskeletal dynamics. These data identify a mechanism for cell-autonomous regulation of a specific inhibitory circuit that is critical to ensure that a majority of cortical pyramidal cells participate in information coding. [Display omitted] • SLK regulates excitation-inhibition balance cell-autonomously • SLK in cortical neurons regulates feedforward but not feedback inhibition • SLK selectively regulates inhibition by parvalbumin-expressing interneurons Royero et al. identify a mechanism relying on Ste20-like kinase that allows single cortical neurons to cell-autonomously adjust feedforward inhibition they receive to the cell-specific levels of excitatory input. They propose that this mechanism is critical to ensure that a majority of cortical pyramidal cells participate in information coding. [ABSTRACT FROM AUTHOR]

Published

2022

2. The impact of neuron morphology on cortical network architecture.

Author

Udvary, Daniel, Harth, Philipp, Macke, Jakob H., Hege, Hans-Christian, de Kock, Christiaan P.J., Sakmann, Bert, and Oberlaender, Marcel

Abstract

The neurons in the cerebral cortex are not randomly interconnected. This specificity in wiring can result from synapse formation mechanisms that connect neurons, depending on their electrical activity and genetically defined identity. Here, we report that the morphological properties of the neurons provide an additional prominent source by which wiring specificity emerges in cortical networks. This morphologically determined wiring specificity reflects similarities between the neurons' axo-dendritic projections patterns, the packing density, and the cellular diversity of the neuropil. The higher these three factors are, the more recurrent is the topology of the network. Conversely, the lower these factors are, the more feedforward is the network's topology. These principles predict the empirically observed occurrences of clusters of synapses, cell type-specific connectivity patterns, and nonrandom network motifs. Thus, we demonstrate that wiring specificity emerges in the cerebral cortex at subcellular, cellular, and network scales from the specific morphological properties of its neuronal constituents. [Display omitted] • Neuronal network architectures reflect the morphologies of their constituents • Morphology predicts nonrandom connectivity from subcellular to network scales • Morphology predicts connectivity patterns consistent with those observed empirically • Neuron morphology is a major source for wiring specificity in the cerebral cortex Udvary et al. reveal four basic principles by which the morphological properties of the neurons shape the specific architecture of the networks they form. These principles can account for nonrandom connectivity patterns that are observed empirically between the neurons in the cerebral cortex at subcellular, cellular, and network scales. [ABSTRACT FROM AUTHOR]

Published

2022

3. Automated three-dimensional detection and counting of neuron somata

Author

Oberlaender, Marcel, Dercksen, Vincent J., Egger, Robert, Gensel, Maria, Sakmann, Bert, and Hege, Hans-Christian

Subjects

*SOMATOSENSORY evoked potentials, *BRAIN imaging, *NEURONS, *GAUSSIAN distribution, *BRAIN function localization, *NEUROSCIENCES

Abstract

Abstract: We present a novel approach for automated detection of neuron somata. A three-step processing pipeline is described on the example of confocal image stacks of NeuN-stained neurons from rat somato-sensory cortex. It results in a set of position landmarks, representing the midpoints of all neuron somata. In the first step, foreground and background pixels are identified, resulting in a binary image. It is based on local thresholding and compensates for imaging and staining artifacts. Once this pre-processing guarantees a standard image quality, clusters of touching neurons are separated in the second step, using a marker-based watershed approach. A model-based algorithm completes the pipeline. It assumes a dominant neuron population with Gaussian distributed volumes within one microscopic field of view. Remaining larger objects are hence split or treated as a second neuron type. A variation of the processing pipeline is presented, showing that our method can also be used for co-localization of neurons in multi-channel images. As an example, we process 2-channel stacks of NeuN-stained somata, labeling all neurons, counterstained with GAD67, labeling GABAergic interneurons, using an adapted pre-processing step for the second channel. The automatically generated landmark sets are compared to manually placed counterparts. A comparison yields that the deviation in landmark position is negligible and that the difference between the numbers of manually and automatically counted neurons is less than 4%. In consequence, this novel approach for neuron counting is a reliable and objective alternative to manual detection. [Copyright &y& Elsevier]

Published

2009

4. 3D reconstruction and standardization of the rat facial nucleus for precise mapping of vibrissal motor networks.

Author

Guest, Jason M., Seetharama, Mythreya M., Wendel, Elizabeth S., Strick, Peter L., and Oberlaender, Marcel

Subjects

*FACIAL motor nucleus, *MOTOR neurons, *TACTILE sensors, *WHISKERS, *BRAIN stem

Abstract

The rodent facial nucleus (FN) comprises motoneurons (MNs) that control the facial musculature. In the lateral part of the FN, populations of vibrissal motoneurons (vMNs) innervate two groups of muscles that generate movements of the whiskers. Vibrissal MNs thus represent the terminal point of the neuronal networks that generate rhythmic whisking during exploratory behaviors and that modify whisker movements based on sensory–motor feedback during tactile-based perception. Here, we combined retrograde tracer injections into whisker-specific muscles, with large-scale immunohistochemistry and digital reconstructions to generate an average model of the rat FN. The model incorporates measurements of the FN geometry, its cellular organization and a whisker row-specific map formed by vMNs. Furthermore, the model provides a digital 3D reference frame that allows registering structural data – obtained across scales and animals – into a common coordinate system with a precision of ∼60 µm. We illustrate the registration method by injecting replication competent rabies virus into the muscle of a single whisker. Retrograde transport of the virus to vMNs enabled reconstruction of their dendrites. Subsequent trans-synaptic transport enabled mapping the presynaptic neurons of the reconstructed vMNs. Registration of these data to the FN reference frame provides a first account of the morphological and synaptic input variability within a population of vMNs that innervate the same muscle. [ABSTRACT FROM AUTHOR]

Published

2018

5. Simulation of signal flow in 3D reconstructions of an anatomically realistic neural network in rat vibrissal cortex

Author

Lang, Stefan, Dercksen, Vincent J., Sakmann, Bert, and Oberlaender, Marcel

Subjects

*NEUROANATOMY, *ARTIFICIAL neural networks, *NEURAL circuitry, *EXCITATION (Physiology), *CELLULAR signal transduction, *SYNAPSES, *COMPUTER simulation, *THREE-dimensional imaging, *IMAGE reconstruction, *CEREBRAL cortex, *LABORATORY rats

Abstract

Abstract: The three-dimensional (3D) structure of neural circuits represents an essential constraint for information flow in the brain. Methods to directly monitor streams of excitation, at subcellular and millisecond resolution, are at present lacking. Here, we describe a pipeline of tools that allow investigating information flow by simulating electrical signals that propagate through anatomically realistic models of average neural networks. The pipeline comprises three blocks. First, we review tools that allow fast and automated acquisition of 3D anatomical data, such as neuron soma distributions or reconstructions of dendrites and axons from in vivo labeled cells. Second, we introduce NeuroNet, a tool for assembling the 3D structure and wiring of average neural networks. Finally, we introduce a simulation framework, NeuroDUNE, to investigate structure–function relationships within networks of full-compartmental neuron models at subcellular, cellular and network levels. We illustrate the pipeline by simulations of a reconstructed excitatory network formed between the thalamus and spiny stellate neurons in layer 4 (L4ss) of a cortical barrel column in rat vibrissal cortex. Exciting the ensemble of L4ss neurons with realistic input from an ensemble of thalamic neurons revealed that the location-specific thalamocortical connectivity may result in location-specific spiking of cortical cells. Specifically, a radial decay in spiking probability toward the column borders could be a general feature of signal flow in a barrel column. Our simulations provide insights of how anatomical parameters, such as the subcellular organization of synapses, may constrain spiking responses at the cellular and network levels. [Copyright &y& Elsevier]

Published

2011