Your search keyword '"Dylan I. Lee"' showing total 9 results

1. St18 specifies globus pallidus projection neuron identity in MGE lineage

Author

Luke F. Nunnelly, Melissa Campbell, Dylan I. Lee, Patrick Dummer, Guoqiang Gu, Vilas Menon, and Edmund Au

Subjects

Science

Abstract

The medial ganglionic eminence produces both interneurons and projection neurons, though how this fate choice is made is not well established. Here they show that St18 regulates migration and morphology of MGE neurons, inducing projection neuron fates.

Published

2022

2. A harmonized atlas of mouse spinal cord cell types and their spatial organization

Author

Daniel E. Russ, Ryan B. Patterson Cross, Li Li, Stephanie C. Koch, Kaya J. E. Matson, Archana Yadav, Mor R. Alkaslasi, Dylan I. Lee, Claire E. Le Pichon, Vilas Menon, and Ariel J. Levine

Subjects

Science

Abstract

Single-cell profiling has led to the identification of diverse cell types. Here, the authors generate a harmonized cell atlas of the mouse post-natal spinal cord. They also provide spatial analysis of the distribution of the identified cell types and an open-source cell type classifier.

Published

2021

3. Author Correction: A harmonized atlas of mouse spinal cord cell types and their spatial organization

Author

Daniel E. Russ, Ryan B. Patterson Cross, Li Li, Stephanie C. Koch, Kaya J. E. Matson, Archana Yadav, Mor R. Alkaslasi, Dylan I. Lee, Claire E. Le Pichon, Vilas Menon, and Ariel J. Levine

Subjects

Science

Published

2022

4. A Cellular Taxonomy of the Adult Human Spinal Cord

Author

Archana Yadav, Kaya J.E. Matson, Li Li, Isabelle Hua, Joana Petrescu, Kristy Kang, Mor R. Alkaslasi, Dylan I. Lee, Saadia Hasan, Ahmad Galuta, Annemarie Dedek, Sara Ameri, Jessica Parnell, Mohammad M. Alshardan, Feras Abbas Qumqumji, Saud M. Alhamad, Alick Pingbei Wang, Gaetan Poulen, Nicolas Lonjon, Florence Vachiery-Lahaye, Pallavi Gaur, Mike A. Nalls, Yue A. Qi, Michael E. Ward, Michael E. Hildebrand, Pierre-Francois Mery, Emmanuel Bourinet, Luc Bauchet, Eve C. Tsai, Hemali Phatnani, Claire E. Le Pichon, Vilas Menon, Ariel J. Levine, Columbia University [New York], National Institutes of Health [Bethesda] (NIH), Ottawa Hospital Research Institute [Ottawa] (OHRI), Carleton University, CHU Montpellier, Centre Hospitalier Régional Universitaire [Montpellier] (CHRU Montpellier), Institut de Génomique Fonctionnelle (IGF), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM), and bourinet, emmanuel

Subjects

[SDV] Life Sciences [q-bio], [SDV]Life Sciences [q-bio], [SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC], [SDV.NEU] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]

Abstract

The mammalian spinal cord functions as a community of glial and neuronal cell types to accomplish sensory processing, autonomic control, and movement; conversely, the dysfunction of these cell types following spinal cord injury or disease states can lead to chronic pain, paralysis, and death. While we have made great strides in understanding spinal cellular diversity in animal models, it is crucial to characterize human biology directly to uncover specialized features of basic function and to illuminate human pathology. Here, we present a cellular taxonomy of the adult human spinal cord using single nucleus RNA-sequencing with spatial transcriptomics and antibody validation. We observed 29 glial clusters, including rare cell types such as ependymal cells, and 35 neuronal clusters, which we found are organized principally by anatomical location. To demonstrate the potential of this resource for understanding human disease, we analyzed the transcriptome of spinal motoneurons that are prone to degeneration in amyotrophic lateral sclerosis (ALS) and other diseases. We found that, compared with all other spinal neurons, human motoneurons are defined by genes related to cell size, cytoskeletal structure, and ALS, thereby supporting a model of a specialized motoneuron molecular repertoire that underlies their selective vulnerability to disease. We include a publicly available browsable web resource with this work, in the hope that it will catalyze future discoveries about human spinal cord biology.

Published

2022

5. Cell type-specific changes identified by single-cell transcriptomics in Alzheimer's disease

Author

Tain Luquez, Pallavi Gaur, Ivy M Kosater, Matti Lam, Dylan I Lee, Jason Mares, Fahad Paryani, Archana Yadav, and Vilas Menon

Subjects

Alzheimer Disease, Genetics, Molecular Medicine, Humans, Brain, Cognitive Dysfunction, Autopsy, Transcriptome, Molecular Biology, Genetics (clinical)

Abstract

The rapid advancement of single-cell transcriptomics in neurology has allowed for profiling of post-mortem human brain tissue across multiple diseases. Over the past 3 years, several studies have examined tissue from donors with and without diagnoses of Alzheimer’s disease, highlighting key changes in cell type composition and molecular signatures associated with pathology and, in some cases, cognitive decline. Although all of these studies have generated single-cell/nucleus RNA-seq or ATAC-seq data from the full array of major cell classes in the brain, they have each focused on changes in specific cell types. Here, we synthesize the main findings from these studies and contextualize them in the overall space of large-scale omics studies of Alzheimer’s disease. Finally, we touch upon new horizons in the field, in particular advancements in high-resolution spatial interrogation of tissue and multi-modal efforts—and how they are likely to further advance mechanistic and target-selection studies on Alzheimer’s disease.

Published

2022

6. A cellular taxonomy of the adult human spinal cord

Author

Archana Yadav, Kaya J.E. Matson, Li Li, Isabelle Hua, Joana Petrescu, Kristy Kang, Mor R. Alkaslasi, Dylan I. Lee, Saadia Hasan, Ahmad Galuta, Annemarie Dedek, Sara Ameri, Jessica Parnell, Mohammad M. Alshardan, Feras Abbas Qumqumji, Saud M. Alhamad, Alick Pingbei Wang, Gaetan Poulen, Nicolas Lonjon, Florence Vachiery-Lahaye, Pallavi Gaur, Mike A. Nalls, Yue A. Qi, Dragan Maric, Michael E. Ward, Michael E. Hildebrand, Pierre-Francois Mery, Emmanuel Bourinet, Luc Bauchet, Eve C. Tsai, Hemali Phatnani, Claire E. Le Pichon, Vilas Menon, and Ariel J. Levine

Subjects

General Neuroscience

Published

2023

7. A harmonized atlas of mouse spinal cord cell types and their spatial organization

Author

Ryan B. Patterson Cross, Li Li, Claire E. Le Pichon, Kaya J.E. Matson, Archana Yadav, Stephanie C. Koch, Ariel J. Levine, Daniel E. Russ, Mor R. Alkaslasi, Vilas Menon, and Dylan I. Lee

Subjects

Cell type, Lineage (genetic), Science, Cell, Datasets as Topic, General Physics and Astronomy, Computational biology, Biology, Molecular neuroscience, General Biochemistry, Genetics and Molecular Biology, Article, Transcriptome, Mice, Atlases as Topic, Cellular neuroscience, medicine, Animals, RNA-Seq, Transcriptomics, Cell Nucleus, Neurons, Spatial Analysis, Spinal cord, Multidisciplinary, General Chemistry, medicine.anatomical_structure, Identification (biology), Single-Cell Analysis, Classifier (UML)

Abstract

Single-cell RNA sequencing data can unveil the molecular diversity of cell types. Cell type atlases of the mouse spinal cord have been published in recent years but have not been integrated together. Here, we generate an atlas of spinal cell types based on single-cell transcriptomic data, unifying the available datasets into a common reference framework. We report a hierarchical structure of postnatal cell type relationships, with location providing the highest level of organization, then neurotransmitter status, family, and finally, dozens of refined populations. We validate a combinatorial marker code for each neuronal cell type and map their spatial distributions in the adult spinal cord. We also show complex lineage relationships among postnatal cell types. Additionally, we develop an open-source cell type classifier, SeqSeek, to facilitate the standardization of cell type identification. This work provides an integrated view of spinal cell types, their gene expression signatures, and their molecular organization., Single-cell profiling has led to the identification of diverse cell types. Here, the authors generate a harmonized cell atlas of the mouse post-natal spinal cord. They also provide spatial analysis of the distribution of the identified cell types and an open-source cell type classifier.

Published

2021

8. St18 specifies globus pallidus projection neuron identity in MGE lineage

Author

Dylan I. Lee, Melissa Campbell, Luke F. Nunnelly, Vilas Menon, Edmund Au, and Guoqiang Gu

Subjects

medicine.anatomical_structure, Lineage (genetic), Globus pallidus, nervous system, Ganglionic eminence, Effector, medicine, Subventricular zone, Biology, Projection (set theory), Neuroscience, Cortex (botany), Progenitor

Abstract

The medial ganglionic eminence (MGE) is a progenitor domain in the subpallium that produces both locally-projecting interneurons which undergo tangential migration in structures such as the cortex as well as long-range projection neurons that occupy subcortical nuclei. Very little is known about the transcriptional mechanisms specifying the migratory behavior and axonal projection patterns of these two broad classes of MGE-derived neurons. In this study, we identify St18 as a novel transcriptional determinant specifying projection neuron fate in the MGE lineage. St18 is transiently expressed in the MGE subventricular zone (SVZ) and mantle, and we assessed its function using an ES cell-based model of MGE development. Induction of St18 is sufficient to direct ES-derived MGE neurons to adopt a projection neuron-like identity as defined by migration and morphology. Using genetic loss-of-function in mice, we find that St18 is required for the production of globus pallidus pars externa (GPe) prototypic projection neurons. Single cell RNA sequencing revealed that St18 regulates MGE output of specific neuronal populations: in the absence of St18, we observe a large expansion of cortical interneurons at the expense of putative GPe neurons. Through gene expression analysis we identified a downstream effector of St18, Cbx7, which is a component of Polycomb repressor complex 1. We find that Cbx7 is essential for projection neuron-like migration and is not involved in St18-mediated projection neuron-like morphology. Our results characterize a novel transcriptional determinant that directs GPe prototypic projection neuron identity. Further, we identified a downstream target of St18, Cbx7, which regulates only the migratory behavior of long-range projection neurons, suggesting that specific features of MGE projection neuron identity may be governed in a compartmentalized fashion by distinct transcriptional modules downstream of St18.

Published

2021

9. St18 specifies globus pallidus projection neuron identity in MGE lineage

Author

Luke F. Nunnelly, Melissa Campbell, Dylan I. Lee, Patrick Dummer, Guoqiang Gu, Vilas Menon, and Edmund Au

Subjects

Cerebral Cortex, Neurons, Mice, Multidisciplinary, Cell Movement, Interneurons, General Physics and Astronomy, Animals, General Chemistry, Globus Pallidus, General Biochemistry, Genetics and Molecular Biology

Abstract

The medial ganglionic eminence (MGE) produces both locally-projecting interneurons, which migrate long distances to structures such as the cortex as well as projection neurons that occupy subcortical nuclei. Little is known about what regulates the migratory behavior and axonal projections of these two broad classes of neurons. We find that St18 regulates the migration and morphology of MGE neurons in vitro. Further, genetic loss-of-function of St18 in mice reveals a reduction in projection neurons of the globus pallidus pars externa. St18 functions by influencing cell fate in MGE lineages as we observe a large expansion of nascent cortical interneurons at the expense of putative GPe neurons in St18 null embryos. Downstream of St18, we identified Cbx7, a component of Polycomb repressor complex 1, and find that it is essential for projection neuron-like migration but not morphology. Thus, we identify St18 as a key regulator of projection neuron vs. interneuron identity.

Published

2021