Enhancer viruses and a transgenic platform for combinatorial cell subclass-specific labeling

Graybuck, Lucas T.; Daigle, Tanya L.; Sedeño-Cortés, Adriana E.; Walker, Miranda; Kalmbach, Brian; Lenz, Garreck H.; Nguyen, Thuc Nghi; Garren, Emma; Kim, Tae Kyung; Sieverts, La'Akea; Bendrick, Jacqueline L.; Zhou, Thomas; Mortrud, Marty; Yao, Shenqin; Çetin, Ali; Larsen, Rachael; Esposito, Luke; Gore, Bryan B.; Szelenyi, Eric R.; Morin, Elyse; Mich, John K.; Dee, Nick; Goldy, Jeff; Smith, Kimberly A.; Yao, Zizhen; Gradinaru, Viviana; Sunkin, Susan M.; Lein, Ed; Levi, Boaz P.; Ting, Jonathan T.; Zeng, Hongkui; Tasic, Bosiljka

doi:10.1101/525014

Cited by 36 publications

(41 citation statements)

References 84 publications

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“…In order to determine the fidelity of organoids as a model for the epigenomic landscape of the developing brain, functional characterization of conserved and non-conserved chromatin features in vivo and in vitro will be required. In addition to serving as a reference for evaluating in vitro models of human brain development, our data will enable scalable prediction of candidate cell type specific regulatory elements that could facilitate the development of enhancer-based tools for accessing molecularly-defined cell types [57][58][59] .…”

Section: Discussionmentioning

confidence: 99%

Single cell epigenomic atlas of the developing human brain and organoids

Rs¹,

Wilfert

et al. 2019

Preprint

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31Dynamic changes in chromatin accessibility coincide with important aspects of neuronal differentiation, such as 32 fate specification and arealization and confer cell type-specific associations to neurodevelopmental disorders. 33However, studies of the epigenomic landscape of the developing human brain have yet to be performed at single-34 cell resolution. Here, we profiled chromatin accessibility of >75,000 cells from eight distinct areas of developing 35human forebrain using single cell ATAC-seq (scATACseq). We identified thousands of loci that undergo 36 extensive cell type-specific changes in accessibility during corticogenesis. Chromatin state profiling also reveals 37 novel distinctions between neural progenitor cells from different cortical areas not seen in transcriptomic profiles 38 and suggests a role for retinoic acid signaling in cortical arealization. Comparison of the cell type-specific 39 chromatin landscape of cerebral organoids to primary developing cortex found that organoids establish broad 40 cell type-specific enhancer accessibility patterns similar to the developing cortex, but lack many putative 41 regulatory elements identified in homologous primary cell types. Together, our results reveal the important 42 contribution of chromatin state to the emerging patterns of cell type diversity and cell fate specification and 43 provide a blueprint for evaluating the fidelity and robustness of cerebral organoids as a model for cortical 44 development. 45 46Main text 47The diverse cell types of the human cerebral cortex (Fig. 1a) have been mostly classified based on a handful of 48 morphological, anatomical, and physiological features. Recent innovations in single cell genomics, such as single 49 cell mRNA sequencing (scRNA-seq), have enabled massively parallel profiling of thousands of molecular 50 features in every cell, uncovering the remarkable molecular diversity of cell types previously considered 51 homologous, such as excitatory neurons located in different areas of the cerebral cortex 1-6 . However, the 52 developmental mechanisms underlying the emergence of distinct cellular identities are largely unknown, as most 53 cortical neurons are generated at stages that are inaccessible to experimentation 5 . 54 55Over 60 years ago, Conrad Waddington introduced the concept of an epigenomic landscape to account for the 56 emergence of distinct cell fates 7 . In particular, chromatin state defines the functional architecture of the genome 57

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Section: Discussionmentioning

confidence: 99%

Single cell epigenomic atlas of the developing human brain and organoids

Rs¹,

Wilfert

et al. 2019

Preprint

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“…Furthermore, novel viral tools provide cell type-specific genetic targeting in this system 61 , and application of enhancers for ET cells, such as the Fam84b enhancer that labels mouse ET cells with >90% specificity 62 , could be used to label VENs in ex vivo human brain tissue. Such studies can help to further refine our understanding of the defining characteristics of VENs, potentially providing information about their local connectivity and teasing out subtle gene expression differences between ET cells with spindle, fork, and pyramidal shapes.…”

Section: Discussionmentioning

confidence: 99%

Transcriptomic evidence that von Economo neurons are regionally specialized extratelencephalic-projecting excitatory neurons

Hodge

Miller

Novotny

et al. 2019

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von Economo neurons (VENs) are bipolar, spindle-shaped neurons restricted to layer 5 of human frontoinsula and anterior cingulate cortex that appear to be selectively vulnerable to neuropsychiatric and neurodegenerative diseases, although little is known about other VEN cellular phenotypes. Single nucleus RNA-sequencing of frontoinsula layer 5 identified a transcriptomically-defined cell cluster that contained VENs, but also fork cells and a subset of pyramidal neurons. Cross-species alignment of this cell cluster with a well-annotated mouse classification shows strong homology to extratelencephalic (ET) excitatory neurons that project to subcerebral targets. This cluster also shows strong homology to a putative ET cluster in human temporal cortex, but with a strikingly specific regional signature. Together these results predict VENs are a regionally distinctive type of ET neuron, and we additionally describe the first patch clamp recordings of VENs from neurosurgically-resected tissue that show distinctive intrinsic membrane properties relative to neighboring pyramidal neurons.

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“…Previously, we harnessed the power and specificity of Cre transgenic mice to apply increased selective pressure to viral engineering, leading to the variants AAV-PHP.B and AAV-PHP.eB, which cross the blood-brain barrier following intravenous (IV) administration and broadly transduce cells throughout the CNS 17,18 . These variants transformed the way we study the CNS in rodents, opening up completely novel approaches for measuring and affecting brain activity, both in exploratory and translational contexts [19][20][21][22] . However, these variants also transduce cells in the liver and other offtarget organs.…”

Section: Introductionmentioning

confidence: 99%

Broad gene expression throughout the mouse and marmoset brain after intravenous delivery of engineered AAV capsids

Flytzanis

Goeden

Goertsen

et al. 2020

Preprint

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Genetic intervention is increasingly explored as a therapeutic option for debilitating disorders of the central nervous system. The safety and efficacy of gene therapies relies upon expressing a transgene in affected cells while minimizing off-target expression. To achieve organ/cell-type specific targeting after intravenous delivery of viral vectors, we employed a Cre-transgenic-based screening platform for fast and efficient capsid selection, paired with sequential engineering of multiple surface-exposed loops. We identified capsid variants that are enriched in the brain and detargeted from the liver in mice. The improved enrichment in the brain extends to nonhuman primates, enabling robust, non-invasive gene delivery to the marmoset brain following IV administration. Importantly, the capsids identified display non-overlapping cell-type tropisms within the brain, with one exhibiting high specificity to neurons. The ability to cross the blood-brain barrier with cell-type specificity in rodents and nonhuman primates enables new avenues for basic research and potential therapeutic interventions unattainable with naturally occurring serotypes. Affiliations

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Enhancer viruses and a transgenic platform for combinatorial cell subclass-specific labeling

Cited by 36 publications

References 84 publications

Single cell epigenomic atlas of the developing human brain and organoids

Single cell epigenomic atlas of the developing human brain and organoids

Transcriptomic evidence that von Economo neurons are regionally specialized extratelencephalic-projecting excitatory neurons

Broad gene expression throughout the mouse and marmoset brain after intravenous delivery of engineered AAV capsids

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