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1. A transcriptional constraint mechanism limits the homeostatic response to activity deprivation in mammalian neocortex

Author

Vera Valakh, Derek Wise, Xiaoyue Aelita Zhu, Mingqi Sha, Jaidyn Fok, Stephen D Van Hooser, Robin Schectman, Isabel Cepeda, Ryan Kirk, Sean M O'Toole, and Sacha B Nelson

Subjects
homeostatic plasticity, synapse, neocortex, mouse, neuron, Medicine, Science, Biology (General), QH301-705.5
Abstract

Healthy neuronal networks rely on homeostatic plasticity to maintain stable firing rates despite changing synaptic drive. These mechanisms, however, can themselves be destabilizing if activated inappropriately or excessively. For example, prolonged activity deprivation can lead to rebound hyperactivity and seizures. While many forms of homeostasis have been described, whether and how the magnitude of homeostatic plasticity is constrained remains unknown. Here, we uncover negative regulation of cortical network homeostasis by the PARbZIP family of transcription factors. In cortical slice cultures made from knockout mice lacking all three of these factors, the network response to prolonged activity withdrawal measured with calcium imaging is much stronger, while baseline activity is unchanged. Whole-cell recordings reveal an exaggerated increase in the frequency of miniature excitatory synaptic currents reflecting enhanced upregulation of recurrent excitatory synaptic transmission. Genetic analyses reveal that two of the factors, Hlf and Tef, are critical for constraining plasticity and for preventing life-threatening seizures. These data indicate that transcriptional activation is not only required for many forms of homeostatic plasticity but is also involved in restraint of the response to activity deprivation.

Published
2023
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2. Cortical RORβ is required for layer 4 transcriptional identity and barrel integrity

Author

Erin A Clark, Michael Rutlin, Lucia S Capano, Samuel Aviles, Jordan R Saadon, Praveen Taneja, Qiyu Zhang, James B Bullis, Timothy Lauer, Emma Myers, Anton Schulmann, Douglas Forrest, and Sacha B Nelson

Subjects
neocortex, barrel cortex, layer 4, thalamocortical, somatosensory, Medicine, Science, Biology (General), QH301-705.5
Abstract

Retinoic acid-related orphan receptor beta (RORβ) is a transcription factor (TF) and marker of layer 4 (L4) neurons, which are distinctive both in transcriptional identity and the ability to form aggregates such as barrels in rodent somatosensory cortex. However, the relationship between transcriptional identity and L4 cytoarchitecture is largely unknown. We find RORβ is required in the cortex for L4 aggregation into barrels and thalamocortical afferent (TCA) segregation. Interestingly, barrel organization also degrades with age in wildtype mice. Loss of RORβ delays excitatory input and disrupts gene expression and chromatin accessibility, with down-regulation of L4 and up-regulation of L5 genes, suggesting a disruption in cellular specification. Expression and binding site accessibility change for many other TFs, including closure of neurodevelopmental TF binding sites and increased expression and binding capacity of activity-regulated TFs. Lastly, a putative target of RORβ, Thsd7a, is down-regulated without RORβ, and Thsd7a knock-out alone disrupts TCA organization in adult barrels.

Published
2020
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3. Deletion of Stk11 and Fos in mouse BLA projection neurons alters intrinsic excitability and impairs formation of long-term aversive memory

Author

David Levitan, Chenghao Liu, Tracy Yang, Yasuyuki Shima, Jian-You Lin, Joseph Wachutka, Yasmin Marrero, Ramin Ali Marandi Ghoddousi, Eduardo da Veiga Beltrame, Troy A Richter, Donald B Katz, and Sacha B Nelson

Subjects
Stk11, fos, excitability, memory, basolateral amygdala, Medicine, Science, Biology (General), QH301-705.5
Abstract

Conditioned taste aversion (CTA) is a form of one-trial learning dependent on basolateral amygdala projection neurons (BLApn). Its underlying cellular and molecular mechanisms remain poorly understood. RNAseq from BLApn identified changes in multiple candidate learning-related transcripts including the expected immediate early gene Fos and Stk11, a master kinase of the AMP-related kinase pathway with important roles in growth, metabolism and development, but not previously implicated in learning. Deletion of Stk11 in BLApn blocked memory prior to training, but not following it and increased neuronal excitability. Conversely, BLApn had reduced excitability following CTA. BLApn knockout of a second learning-related gene, Fos, also increased excitability and impaired learning. Independently increasing BLApn excitability chemogenetically during CTA also impaired memory. STK11 and C-FOS activation were independent of one another. These data suggest key roles for Stk11 and Fos in CTA long-term memory formation, dependent at least partly through convergent action on BLApn intrinsic excitability.

Published
2020
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4. Mapping the transcriptional diversity of genetically and anatomically defined cell populations in the mouse brain

Author

Ken Sugino, Erin Clark, Anton Schulmann, Yasuyuki Shima, Lihua Wang, David L Hunt, Bryan M Hooks, Dimitri Tränkner, Jayaram Chandrashekar, Serge Picard, Andrew L Lemire, Nelson Spruston, Adam W Hantman, and Sacha B Nelson

Subjects
neuronal diversity, cell types, RNA-seq, homeobox transcription factors, long genes, Medicine, Science, Biology (General), QH301-705.5
Abstract

Understanding the principles governing neuronal diversity is a fundamental goal for neuroscience. Here, we provide an anatomical and transcriptomic database of nearly 200 genetically identified cell populations. By separately analyzing the robustness and pattern of expression differences across these cell populations, we identify two gene classes contributing distinctly to neuronal diversity. Short homeobox transcription factors distinguish neuronal populations combinatorially, and exhibit extremely low transcriptional noise, enabling highly robust expression differences. Long neuronal effector genes, such as channels and cell adhesion molecules, contribute disproportionately to neuronal diversity, based on their patterns rather than robustness of expression differences. By linking transcriptional identity to genetic strains and anatomical atlases, we provide an extensive resource for further investigation of mouse neuronal cell types.

Published
2019
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5. A Mammalian enhancer trap resource for discovering and manipulating neuronal cell types

Author

Yasuyuki Shima, Ken Sugino, Chris Martin Hempel, Masami Shima, Praveen Taneja, James B Bullis, Sonam Mehta, Carlos Lois, and Sacha B Nelson

Subjects
enhancer trap, cell type, transgenic animals, Medicine, Science, Biology (General), QH301-705.5
Abstract

There is a continuing need for driver strains to enable cell-type-specific manipulation in the nervous system. Each cell type expresses a unique set of genes, and recapitulating expression of marker genes by BAC transgenesis or knock-in has generated useful transgenic mouse lines. However, since genes are often expressed in many cell types, many of these lines have relatively broad expression patterns. We report an alternative transgenic approach capturing distal enhancers for more focused expression. We identified an enhancer trap probe often producing restricted reporter expression and developed efficient enhancer trap screening with the PiggyBac transposon. We established more than 200 lines and found many lines that label small subsets of neurons in brain substructures, including known and novel cell types. Images and other information about each line are available online (enhancertrap.bio.brandeis.edu).

Published
2016
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6. Convergence of pontine and proprioceptive streams onto multimodal cerebellar granule cells

Author

Cheng-Chiu Huang, Ken Sugino, Yasuyuki Shima, Caiying Guo, Suxia Bai, Brett D Mensh, Sacha B Nelson, and Adam W Hantman

Subjects
cerebellum, corollary discharge, proprioception, Medicine, Science, Biology (General), QH301-705.5
Abstract

Cerebellar granule cells constitute the majority of neurons in the brain and are the primary conveyors of sensory and motor-related mossy fiber information to Purkinje cells. The functional capability of the cerebellum hinges on whether individual granule cells receive mossy fiber inputs from multiple precerebellar nuclei or are instead unimodal; this distinction is unresolved. Using cell-type-specific projection mapping with synaptic resolution, we observed the convergence of separate sensory (upper body proprioceptive) and basilar pontine pathways onto individual granule cells and mapped this convergence across cerebellar cortex. These findings inform the long-standing debate about the multimodality of mammalian granule cells and substantiate their associative capacity predicted in the Marr-Albus theory of cerebellar function. We also provide evidence that the convergent basilar pontine pathways carry corollary discharges from upper body motor cortical areas. Such merging of related corollary and sensory streams is a critical component of circuit models of predictive motor control.

Published
2013
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7. A quantitative comparison of cell-type-specific microarray gene expression profiling methods in the mouse brain.

Author

Benjamin W Okaty, Ken Sugino, and Sacha B Nelson

Subjects
Medicine, Science
Abstract

Expression profiling of restricted neural populations using microarrays can facilitate neuronal classification and provide insight into the molecular bases of cellular phenotypes. Due to the formidable heterogeneity of intermixed cell types that make up the brain, isolating cell types prior to microarray processing poses steep technical challenges that have been met in various ways. These methodological differences have the potential to distort cell-type-specific gene expression profiles insofar as they may insufficiently filter out contaminating mRNAs or induce aberrant cellular responses not normally present in vivo. Thus we have compared the repeatability, susceptibility to contamination from off-target cell-types, and evidence for stress-responsive gene expression of five different purification methods--Laser Capture Microdissection (LCM), Translating Ribosome Affinity Purification (TRAP), Immunopanning (PAN), Fluorescence Activated Cell Sorting (FACS), and manual sorting of fluorescently labeled cells (Manual). We found that all methods obtained comparably high levels of repeatability, however, data from LCM and TRAP showed significantly higher levels of contamination than the other methods. While PAN samples showed higher activation of apoptosis-related, stress-related and immediate early genes, samples from FACS and Manual studies, which also require dissociated cells, did not. Given that TRAP targets actively translated mRNAs, whereas other methods target all transcribed mRNAs, observed differences may also reflect translational regulation.

Published
2011
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17. A transcriptional constraint mechanism limits the homeostatic response to activity deprivation in mammalian neocortex

Author

Vera Valakh, Derek Wise, Xiaoyue Aelita Zhu, Mingqi Sha, Jaidyn Fok, Stephen D. Van Hooser, Robin Schectman, Isabel Cepeda, Ryan Kirk, Sean O’Toole, and Sacha B. Nelson

Subjects
Neocortex, General Immunology and Microbiology, Excitatory synaptic transmission, Mechanism (biology), General Neuroscience, General Medicine, Biology, General Biochemistry, Genetics and Molecular Biology, medicine.anatomical_structure, Downregulation and upregulation, Cortical network, Homeostatic plasticity, medicine, Neuroscience, Transcription factor, Homeostasis
Abstract

Healthy neuronal networks rely on homeostatic plasticity to maintain stable firing rates despite changing synaptic drive. These mechanisms, however, can themselves be destabilizing if activated inappropriately or excessively. For example, prolonged activity deprivation can lead to rebound hyperactivity and seizures. While many forms of homeostasis have been described, whether and how the magnitude of homeostatic plasticity is constrained remains unknown. Here, we uncover negative regulation of cortical network homeostasis by the PARbZIP family of transcription factors. In cortical slice cultures made from knockout mice lacking all three of these factors, the network response to prolonged activity withdrawal measured with calcium imaging is much stronger, while baseline activity is unchanged. Whole-cell recordings reveal an exaggerated increase in the frequency of miniature excitatory synaptic currents reflecting enhanced upregulation of recurrent excitatory synaptic transmission. Genetic analyses reveal that two of the factors, Hlf and Tef, are critical for constraining plasticity and for preventing life-threatening seizures. These data indicate that transcriptional activation is not only required for many forms of homeostatic plasticity but is also involved in restraint of the response to activity deprivation.

Published
2021
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22. Single and population coding of taste in the gustatory cortex of awake mice

Author

David Levitan, Narendra Mukherjee, Jian-You Lin, Sacha B. Nelson, Donald B. Katz, and Joseph Wachutka

Subjects
Cerebral Cortex, Male, Neurons, Taste, Physiology, General Neuroscience, Models, Neurological, Action Potentials, Taste Perception, Biology, Frontal Lobe, Mice, Inbred C57BL, Animals, Female, Gustatory cortex, Neural coding, Neuroscience, Research Article
Abstract

Electrophysiological analysis has revealed much about the broad coding and neural ensemble dynamics that characterize gustatory cortical (GC) taste processing in awake rats and about how these dynamics relate to behavior. With regard to mice, however, data concerning cortical taste coding have largely been restricted to imaging, a technique that reveals average levels of neural responsiveness but that (currently) lacks the temporal sensitivity necessary for evaluation of fast response dynamics; furthermore, the few extant studies have thus far failed to provide consensus on basic features of coding. We have recorded the spiking activity of ensembles of GC neurons while presenting representatives of the basic taste modalities (sweet, salty, sour, and bitter) to awake mice. Our first central result is the identification of similarities between rat and mouse taste processing: most mouse GC neurons (~66%) responded distinctly to multiple (3–4) tastes; temporal coding analyses further reveal, for the first time, that single mouse GC neurons sequentially code taste identity and palatability, the latter responses emerging ~0.5 s after the former, with whole GC ensembles transitioning suddenly and coherently from coding taste identity to coding taste palatability. The second finding is that spatial location plays very little role in any aspect of taste responses: neither between- (anterior-posterior) nor within-mouse (dorsal-ventral) mapping revealed anatomic regions with narrow or temporally simple taste responses. These data confirm recent results showing that mouse cortical taste responses are not “gustotopic” but also go beyond these imaging results to show that mice process tastes through time. NEW & NOTEWORTHY Here, we analyzed taste-related spiking activity in awake mouse gustatory cortical (GC) neural ensembles, revealing deep similarities between mouse cortical taste processing and that repeatedly demonstrated in rat: mouse GC ensembles code multiple aspects of taste in a coarse-coded, time-varying manner that is essentially invariant across the spatial extent of GC. These data demonstrate that, contrary to some reports, cortical network processing is distributed, rather than being separated out into spatial subregion.

Published
2019
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23. A repeated molecular architecture across thalamic pathways

Author

Brett D. Mensh, Joshua T. Dudman, Jayaram Chandrashekar, Johan Winnubst, Chenghao Liu, James W Phillips, Wyatt Korff, Erina Hara, Andrew L. Lemire, Brenda C Shields, Lihua Wang, Anton Schulmann, Adam W. Hantman, Vera Valakh, and Sacha B. Nelson

Subjects
0301 basic medicine, Thalamus, Action Potentials, Mice, Transgenic, Sensory system, Biology, Article, Transcriptome, Mice, 03 medical and health sciences, Atlases as Topic, 0302 clinical medicine, Neural Pathways, medicine, Animals, Humans, Cerebral Cortex, Extramural, General Neuroscience, Motor control, 030104 developmental biology, Mouse Thalamus, medicine.anatomical_structure, nervous system, Cerebral cortex, Forebrain, Neuroscience, 030217 neurology & neurosurgery
Abstract

The thalamus is the central communication hub of the forebrain and provides the cerebral cortex with inputs from sensory organs, subcortical systems and the cortex itself. Multiple thalamic regions send convergent information to each cortical region, but the organizational logic of thalamic projections has remained elusive. Through comprehensive transcriptional analyses of retrogradely labeled thalamic neurons in adult mice, we identify three major profiles of thalamic pathways. These profiles exist along a continuum that is repeated across all major projection systems, such as those for vision, motor control and cognition. The largest component of gene expression variation in the mouse thalamus is topographically organized, with features conserved in humans. Transcriptional differences between these thalamic neuronal identities are tied to cellular features that are critical for function, such as axonal morphology and membrane properties. Molecular profiling therefore reveals covariation in the properties of thalamic pathways serving all major input modalities and output targets, thus establishing a molecular framework for understanding the thalamus.

Published
2019
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24. Loss of Stk11 in basolateral amygdalar projection neurons impairs taste aversion learning by altering the temporal pattern of taste response plasticity in gustatory cortex

Author

Seneca J. Scott, David Levitan, Sacha B. Nelson, Donald B. Katz, Thomas J Murdy, and Roshan Nanu

Subjects
Taste, medicine.anatomical_structure, Tongue, Taste aversion, medicine, Palatability, Biology, medicine.symptom, Association (psychology), Gustatory cortex, Neuroscience, Malaise, Basolateral amygdala
Abstract

Gustatory cortex (GC) responds to tastes on the tongue with dynamic ensemble activity that represents first the presence, then the identity, and finally the hedonic value (palatability) of tastes. This final state of the taste response is uniquely altered by conditioned taste aversion (CTA) – a powerful one-trial learning paradigm in which a taste becomes aversive after association with gastric malaise – a process requiring coordination between GC and basolateral amygdala (BLA). Previously, we found that one key requirement for learning in this circuit is expression of the serine/threonine kinase 11 (Stk11) gene (a tumor suppression gene which has only recently been associated with learning; Levitan et al., 2020). When Stk11 is knocked out in BLA projection neurons (BLApn), CTA learning fails to occur. Here we have examined how learning-related response plasticity in GC taste responses is impacted by the knockout of Stk11 in BLApn. Contrary to the commonly held assumption that a lack of learning means a lack of such plasticity, but consistent with the fact that Stk11KO has been shown to increase the excitability of BLApn, our data reveal that the knockout of Stk11 in BLApn does not eliminate plasticity; rather, it shifts the impact of CTA training on GC taste responses to an earlier, learning-inappropriate epoch. Even naïve taste representations are altered—specifically, the pattern of similarities and differences among the different taste responses are rendered abnormal by Stk11 KO, and these relationships fail to change with training. Finally, the latency of behavior-related dynamic ensemble features of the GC taste response, which is also abnormal in naïve KO mice, is rendered disorganized by CTA. Together, these results suggest that Stk11 plays a role in governing the coordination of GC activity by BLA, and demonstrate that alterations in the function of BLApn caused by Stk11KO inhibit learning not by inhibiting plasticity but by changing its temporal properties.

Published
2021
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30. Cortical RORβ is required for layer 4 transcriptional identity and barrel integrity

Author

Qiyu Zhang, Lucia Capano, Praveen Taneja, Jordan R. Saadon, Michael Rutlin, James B. Bullis, Sacha B. Nelson, Erin A. Clark, Douglas Forrest, Timothy Lauer, Emma Myers, Samuel Aviles, and Anton Schulmann

Subjects
Male, 0301 basic medicine, Mouse, Mice, 0302 clinical medicine, Thalamus, Gene expression, neocortex, Biology (General), Mice, Knockout, Neurons, Orphan receptor, Neocortex, thalamocortical, Chemistry, General Neuroscience, Nuclear Receptor Subfamily 1, Group F, Member 2, General Medicine, Cell biology, Chromatin, medicine.anatomical_structure, Antigens, Surface, Medicine, barrel cortex, Female, Research Article, QH301-705.5, Science, Biology, General Biochemistry, Genetics and Molecular Biology, somatosensory, 03 medical and health sciences, Downregulation and upregulation, medicine, Animals, Binding site, Beta (finance), Transcription factor, General Immunology and Microbiology, Membrane Proteins, Somatosensory Cortex, Barrel cortex, layer 4, Cortex (botany), 030104 developmental biology, Transcriptome, 030217 neurology & neurosurgery, Neuroscience, Transcription Factors
Abstract

Retinoic Acid-Related Orphan Receptor Beta (RORβ) is a transcription factor (TF) and marker of layer 4 (L4) neurons, which are distinctive both in transcriptional identity and the ability to form aggregates such as barrels in rodent somatosensory cortex. However, the relationship between transcriptional identity and L4 cytoarchitecture is largely unknown. We find RORβ is required in the cortex for L4 aggregation into barrels and thalamocortical afferent (TCA) segregation. Interestingly, barrel organization also degrades with age. Loss of RORβ delays excitatory input and disrupts gene expression and chromatin accessibility, with downregulation of L4 and upregulation of L5 genes, suggesting a shift in cellular identity. Expression and binding site accessibility change for many other TFs, including closure of neurodevelopmental TF binding sites and increased expression and binding capacity of activity-regulated TFs. Lastly, a putative target of RORβ, Thsd7a, is downregulated without RORβ, and Thsd7a knockout alone disrupts TCA organization in adult barrels.

Published
2020
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36. The role of the gustatory cortex in incidental experience-evoked enhancement of later taste learning

Author

Sacha B. Nelson, David Levitan, Veronica L Flores, Narendra Mukherjee, Tamar Parmet, and Donald B. Katz

Subjects
0301 basic medicine, Cognitive Neuroscience, Gene Expression, Sodium Chloride, Stimulus (physiology), Optogenetics, Citric Acid, Malaise, Random Allocation, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Dietary Sucrose, medicine, Animals, Learning, Rats, Long-Evans, 030304 developmental biology, Cerebral Cortex, 0303 health sciences, Research, Taste Perception, Immunohistochemistry, Associative learning, Multiple factors, 030104 developmental biology, Neuropsychology and Physiological Psychology, Taste aversion, Conditioning, Female, medicine.symptom, Psychology, Gustatory cortex, Proto-Oncogene Proteins c-fos, Neuroscience, Immediate early gene, 030217 neurology & neurosurgery
Abstract

The strength of learned associations between pairs of stimuli is affected by multiple factors, the most extensively studied of which is prior experience with the stimuli themselves. In contrast, little data is available regarding how experience with incidental stimuli (independent of any conditioning situation) impacts later learning. This lack of research is striking given the importance of incidental experience to survival. We have recently begun to fill this void using conditioned taste aversion (CTA), wherein an animal learns to avoid a taste that has been associated with malaise. We previously demonstrated that incidental exposure to salty and sour tastes (taste pre-exposure—TPE) enhances aversions learned later to sucrose. Here, we investigate the neurobiology underlying this phenomenon. First, we use immediate early gene (c-Fos) expression to identify gustatory cortex (GC) as a site at which TPE specifically increases the neural activation caused by taste-malaise pairing (i.e., TPE did not change c-Fos induced by either stimulus in isolation). Next, we use site-specific infection with the optical silencer Archaerhodopsin-T to show that GC inactivation during TPE inhibits the expected enhancements of both learning and CTA-related c-Fos expression, a full day later. Thus, we conclude that GC is almost certainly a vital part of the circuit that integrates incidental experience into later associative learning.

Published
2018
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37. Prenatal thalamic waves regulate cortical area size prior to sensory processing

Author

Noelia Antón-Bolaños, Miguel Valdeolmillos, Olivier Schaad, Rafael Susín, Michael Rutlin, Henrik Gezelius, Takuji Iwasato, Anton Filipchuk, Cecilia Mezzera, Verónica Moreno-Juan, Guillermina López-Bendito, Luis Rodríguez-Malmierca, Belén Andrés, Sebastien Ducret, Sacha B. Nelson, Filippo M. Rijli, and Roland Schüle

Subjects
0301 basic medicine, Sensory processing, medicine.medical_treatment, Science, Thalamus, Gene Expression, General Physics and Astronomy, Mice, Transgenic, Sensory system, Biology, Somatosensory system, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Pregnancy, Cortex (anatomy), Neuroplasticity, medicine, Animals, Humans, Vision, Ocular, Ventral Thalamic Nuclei, Neuronal Plasticity, Multidisciplinary, Gap Junctions, Somatosensory Cortex, General Chemistry, Anatomy, Orphan Nuclear Receptors, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Cerebral cortex, Calcium, Female, Nucleus, Neuroscience, 030217 neurology & neurosurgery
Abstract

The cerebral cortex is organized into specialized sensory areas, whose initial territory is determined by intracortical molecular determinants. Yet, sensory cortical area size appears to be fine tuned during development to respond to functional adaptations. Here we demonstrate the existence of a prenatal sub-cortical mechanism that regulates the cortical areas size in mice. This mechanism is mediated by spontaneous thalamic calcium waves that propagate among sensory-modality thalamic nuclei up to the cortex and that provide a means of communication among sensory systems. Wave pattern alterations in one nucleus lead to changes in the pattern of the remaining ones, triggering changes in thalamic gene expression and cortical area size. Thus, silencing calcium waves in the auditory thalamus induces Rorβ upregulation in a neighbouring somatosensory nucleus preluding the enlargement of the barrel-field. These findings reveal that embryonic thalamic calcium waves coordinate cortical sensory area patterning and plasticity prior to sensory information processing., How sensory maps are formed in the brain is only partially understood. Here the authors describe spontaneous calcium waves that propagate across different sensory nuclei in the embryonic thalamus; disrupting the wave pattern triggers thalamic gene expression changes and eventually alters the size of cortical areas.

Published
2017

42. Editorial overview: Neuronal Identity

Author

Sacha B. Nelson and Oliver Hobert

Subjects
Psychoanalysis, General Neuroscience, Identity (social science), Sociology, Neuroscience
Published
2019

43. Mapping the transcriptional diversity of genetically and anatomically defined cell populations in the mouse brain

Author

David L Hunt, Anton Schulmann, Yasuyuki Shima, Serge Picard, Erin A. Clark, Sacha B. Nelson, Lihua Wang, Jayaram Chandrashekar, Dimitri Tränkner, Andrew L. Lemire, Ken Sugino, Nelson Spruston, Bryan M. Hooks, and Adam W. Hantman

Subjects
0301 basic medicine, Cell type, Mouse, QH301-705.5, Science, Biology, homeobox transcription factors, General Biochemistry, Genetics and Molecular Biology, Transcriptome, 03 medical and health sciences, Mice, 0302 clinical medicine, medicine, Animals, Biology (General), Transcription factor, Gene, long genes, Neurons, General Immunology and Microbiology, Effector, General Neuroscience, Gene Expression Profiling, Robustness (evolution), Brain, General Medicine, neuronal diversity, medicine.disease, Tools and Resources, 030104 developmental biology, nervous system, Evolutionary biology, Homeobox, Medicine, RNA-seq, cell types, 030217 neurology & neurosurgery, Transcriptional noise, Neuroscience
Abstract

Understanding the principles governing neuronal diversity is a fundamental goal for neuroscience. Here, we provide an anatomical and transcriptomic database of nearly 200 genetically identified cell populations. By separately analyzing the robustness and pattern of expression differences across these cell populations, we identify two gene classes contributing distinctly to neuronal diversity. Short homeobox transcription factors distinguish neuronal populations combinatorially, and exhibit extremely low transcriptional noise, enabling highly robust expression differences. Long neuronal effector genes, such as channels and cell adhesion molecules, contribute disproportionately to neuronal diversity, based on their patterns rather than robustness of expression differences. By linking transcriptional identity to genetic strains and anatomical atlases, we provide an extensive resource for further investigation of mouse neuronal cell types.

Published
2019

44. Author response: Mapping the transcriptional diversity of genetically and anatomically defined cell populations in the mouse brain

Author

Serge Picard, Adam W. Hantman, Nelson Spruston, Andrew L. Lemire, Bryan M. Hooks, Ken Sugino, Yasuyuki Shima, David L Hunt, Jayaram Chandrashekar, Lihua Wang, Dimitri Tränkner, Sacha B. Nelson, Erin A. Clark, and Anton Schulmann

Subjects
medicine.anatomical_structure, Evolutionary biology, media_common.quotation_subject, Cell, medicine, Biology, Diversity (politics), media_common
Published
2019
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45. ATAC-seq on Sorted Adult Mouse Neurons

Author

Erin A. Clark, Yasuyuki Shima, and Sacha B. Nelson

Subjects
Cell type, Strategy and Management, Mechanical Engineering, Cell, Metals and Alloys, ATAC-seq, Computational biology, Biology, Genome, Industrial and Manufacturing Engineering, Chromatin, medicine.anatomical_structure, Methods Article, medicine, Transcriptional regulation, Neuron, Transposase
Abstract

Transcription regulation is a key aspect of cellular identity established during development and maintained into adulthood. Molecular and biochemical assays that probe the genome are critical tools in exploring mechanisms of transcription regulation and cell type identity. The mammalian brain is composed of a huge diversity of cell types with distinct properties and functions. To understand these specific roles, it is necessary to selectively target cell populations for study. However, the need to selectively study restricted cell populations poses a challenge in neurobiology. It is often difficult to collect sufficient cellular input for many standard biochemical and molecular assays. Recently, important advances have been made to scale assays down, opening up new frontiers to explore molecular mechanisms in neurons. Concurrently, methodologies for preparing neurons for such assays has advanced taking into consideration specific methods to preserve the cell biology meant to be assayed. Here we describe a method for preparing live neurons from adult brain tissue for the Assay for Transposase Accessible Chromatin (ATAC).

Published
2019
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46. Upregulation of μ3A Drives Homeostatic Plasticity by Rerouting AMPAR into the Recycling Endosomal Pathway

Author

Chris M. Hempel, Celine C. Steinmetz, Sacha B. Nelson, Mary E. Lambo, Heather Lin, Yasuyuki Shima, Benjamin W. Okaty, Ken Sugino, Gina G. Turrigiano, Anne Joseph, Michael Rutlin, Vedakumar Tatavarty, Suzanne Paradis, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, and Lambo, Mary E.

Subjects
0301 basic medicine, Adaptor Protein Complex 3, Endosome, Protein subunit, Nerve Tissue Proteins, Endosomes, AMPA receptor, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Discs Large Homolog 1 Protein, Mice, 03 medical and health sciences, Downregulation and upregulation, Homeostatic plasticity, Animals, Homeostasis, Receptors, AMPA, lcsh:QH301-705.5, Adaptor Proteins, Signal Transducing, Neuronal Plasticity, Synaptic scaling, Pyramidal Cells, musculoskeletal, neural, and ocular physiology, Glutamate receptor, Signal transducing adaptor protein, Dendrites, Endocytosis, Adaptor Protein Complex mu Subunits, Up-Regulation, Cell biology, 030104 developmental biology, lcsh:Biology (General), nervous system, Gene Knockdown Techniques, Synapses, Transcriptome
Abstract

SummarySynaptic scaling is a form of homeostatic plasticity driven by transcription-dependent changes in AMPA-type glutamate receptor (AMPAR) trafficking. To uncover the pathways involved, we performed a cell-type-specific screen for transcripts persistently altered during scaling, which identified the μ subunit (μ3A) of the adaptor protein complex AP-3A. Synaptic scaling increased μ3A (but not other AP-3 subunits) in pyramidal neurons and redistributed dendritic μ3A and AMPAR to recycling endosomes (REs). Knockdown of μ3A prevented synaptic scaling and this redistribution, while overexpression (OE) of full-length μ3A or a truncated μ3A that cannot interact with the AP-3A complex was sufficient to drive AMPAR to REs. Finally, OE of μ3A acted synergistically with GRIP1 to recruit AMPAR to the dendritic membrane. These data suggest that excess μ3A acts independently of the AP-3A complex to reroute AMPAR to RE, generating a reservoir of receptors essential for the regulated recruitment to the synaptic membrane during scaling up.

Published
2016
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48. A single spectrum of neuronal identities across thalamus

Author

Erina Hara, Anton Schulmann, Brenda C. Shields, Adam W. Hantman, Lihua Wang, Wyatt Korff, Andrew L. Lemire, Chenghao Liu, James W Phillips, Joshua T. Dudman, and Sacha B. Nelson

Subjects
Electrophysiology, Thalamus, Forebrain, Motor system, Single axis, Sensory system, Common logic, Biology, Mammalian brain, Neuroscience
Abstract

Uncovering common principles by which diverse modalities of information are processed is a fundamental goal in neuroscience. In mammalian brain, thalamus is the central processing station for inputs from sensory systems, subcortical motor systems, and cortex; a function subserved by over 30 defined nuclei1,2. Multiple thalamic nuclei send convergent information to each region of the forebrain, but whether there is a conserved architecture across the set of thalamic pathways projecting to each forebrain area has remained unresolved3–5. To uncover organizational principles of thalamic pathways, we produced a near-comprehensive transcriptomic atlas of thalamus. This revealed a common logic for thalamic nuclei serving all major cortical modalities. We found that almost all nuclei belong to one of three major profiles, with a given cortical area getting input from each of these profiles. These profiles lie on a single axis of variance aligned with the mediolateral axis of thalamus, and this axis is strongly enriched in genes encoding receptors and ion channels. We further show that each projection profile exhibits different electrophysiological signatures. Single-cell profiling revealed that rather than forming discrete classes, thalamic neurons lie on a spectrum, with intermediate cells existing between profiles. Thus, in contrast to canonical models of thalamus that suggest it is a switchboard primarily concerned with routing distinct modalities of information to distinct cortical regions, we show that the thalamocortical system is more akin to a molecularly-defined ‘filter bank’ repeatedly applied across modality. Together, we reveal striking covariation in the organization of thalamic pathways serving all input modalities and output targets, establishing a simple and comprehensive thalamic functional architecture.

Published
2017
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49. The Transcriptional Logic of Mammalian Neuronal Diversity

Author

Andrew L. Lemire, David L Hunt, Lihua Wang, Ken Sugino, Serge Picard, Nelson Spruston, Adam W. Hantman, Yasuyuki Shima, Dimitri Tränkner, Bryan M. Hooks, Jayaram Chandrashekar, Anton Schulmann, Erin A. Clark, and Sacha B. Nelson

Subjects
Genetics, Cell type, Interspersed repeat, Intron, Homeobox, Computational biology, Biology, Mobile genetic elements, Genome, Gene, Transcription factor
Abstract

The mammalian nervous system is constructed of many neuronal cell types, but the principles underlying this diversity are poorly understood. To begin to assess brain-wide transcriptional diversity, we sequenced the transcriptomes of the largest collection of genetically and/or anatomically identified neuronal classes from throughout the central nervous system. Using improved expression metrics that distinguish information content from signal-to-noise-ratio, we found that homeobox transcription factors contain the highest information about cell types and have the lowest noise. Non-transcription factors that contribute the most to neuronal diversity tend to be long, due to large introns, and are enriched in genes specifically involved in neuronal function. Genome accessibility measurements reveal that long genes have more candidate regulatory elements arrayed in more distinct patterns. These candidate regulatory elements frequently overlap interspersed repeats and the pattern of repeats is predictive of gene expression. Elongation of neuronal genes by insertions of mobile elements and the resulting new regulatory sites may be an evolutionary force enhancing nervous system complexity.

Published
2017
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50. Cell-Type-Specific Repression by Methyl-CpG-Binding Protein 2 Is Biased toward Long Genes

Author

Benjamin W. Okaty, Saori Kato, Hannah A. Arnson, Vardhan S. Dani, Sacha B. Nelson, Ken Sugino, and Chris M. Hempel

Subjects
Male, congenital, hereditary, and neonatal diseases and abnormalities, Cell signaling, Microarray, Methyl-CpG-Binding Protein 2, Down-Regulation, Mice, Transgenic, Rett syndrome, Cell Communication, Biology, MECP2, Mice, mental disorders, Gene expression, Cell Adhesion, Rett Syndrome, medicine, Animals, Gene, Psychological repression, Oligonucleotide Array Sequence Analysis, Mice, Knockout, Neurons, Genetics, Gene Expression Profiling, General Neuroscience, Articles, medicine.disease, nervous system diseases, Gene expression profiling, Disease Models, Animal, Organ Specificity
Abstract

Mutations in methyl-CpG-binding protein 2 (MeCP2) cause Rett syndrome and related autism spectrum disorders (Amir et al., 1999). MeCP2 is believed to be required for proper regulation of brain gene expression, but prior microarray studies in Mecp2 knock-out mice using brain tissue homogenates have revealed only subtle changes in gene expression (Tudor et al., 2002; Nuber et al., 2005; Jordan et al., 2007; Chahrour et al., 2008). Here, by profiling discrete subtypes of neurons we uncovered more dramatic effects of MeCP2 on gene expression, overcoming the “dilution problem” associated with assaying homogenates of complex tissues. The results reveal misregulation of genes involved in neuronal connectivity and communication. Importantly, genes upregulated following loss of MeCP2 are biased toward longer genes but this is not true for downregulated genes, suggesting MeCP2 may selectively repress long genes. Because genes involved in neuronal connectivity and communication, such as cell adhesion and cell–cell signaling genes, are enriched among longer genes, their misregulation following loss of MeCP2 suggests a possible etiology for altered circuit function in Rett syndrome.

Published
2014
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