A comprehensive transcriptional map of primate brain development

Bakken, Trygve E.; Miller, Jeremy A.; Ding, Song‐Lin; Sunkin, Susan M.; Smith, Kimberly A.; Ng, Lydia; Szafer, Aaron; Dalley, Rachel; Royall, Joshua J.; Lemon, Tracy; Shapouri, Sheila; Aiona, Kaylynn; Arnold, James M.; Bennett, Jeffrey; Bertagnolli, Darren; Bickley, Kristopher; Boe, Andrew F.; Brouner, Krissy; Butler, Stephanie; Byrnes, Emi J.; Caldejon, Shiella; Carey, Anita; Cate, Shelby; Chapin, Mike; Chen, Jefferey; Dee, Nick; Desta, Tsega; Dolbeare, Tim; Dotson, Nadia; Ebbert, Amanda; Fulfs, Erich; Gee, Garrett; Gilbert, Terri L.; Goldy, Jeff; Gourley, Lindsey; Gregor, Ben W.; Gu, Guangyu; Hall, Jon G.; Haradon, Zeb; Haynor, David R.; Hejazinia, Nika; Hoerder‐Suabedissen, Anna; Howard, Robert; Jochim, Jay; Kinnunen, Marty; Kriedberg, Ali; Kuan, Chihchau; Lau, Christopher; Lee, Chang Kyu; Lee, Felix; Luong, Lon T.; Mastan, Naveed; May, Ryan; Melchor, J.L; Mosqueda, Nerick; Mott, Erika; Ngo, Kiet; Nyhus, Julie; Oldre, Aaron; Olson, Eric N.; Parente, Jody; Parker, Patrick D.; Parry, Sheana; Pendergraft, Julie; Potekhina, Lydia; Reding, Melissa; Riley, Zackery L.; Roberts, T. Guy; Rogers, Brandon M. A.; Roll, Kate; Rosen, David; Sandman, David; Sarreal, Melaine; Shapovalova, Nadiya V.; Shu, Shi; Sjoquist, Nathan; Sodt, Andy J.; Townsend, Robbie; Velasquez, Lissette S.; Wagley, Udi; Wakeman, Wayne; White, Casey; Bennett, Crissa; Wu, Jennifer E.; Young, Rob; Youngstrom, Brian L.; Wohnoutka, Paul; Gibbs, Richard A.; Rogers, Jeffrey; Hohmann, John G.; Hawrylycz, Michael; Hevner, Robert F.; Molnár, Zoltán; Phillips, John W.; Dang, Chinh; Jones, Allan R.; Amaral, David G.; Bernard, Amy; Lein, Ed

doi:10.1038/nature18637

Cited by 334 publications

(345 citation statements)

References 80 publications

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“…Between D100 and D125 in vitro, the rate of transcriptomic changes appeared to slow. A slow-down in gene expression dynamics has been observed in previous studies of human cortical development (Bakken et al, 2016;Colantuoni et al, 2011). It is possible that our in vitro observations reflect similar changes occurring at equivalent ages in vivo, or that some extrinsic element necessary for continued development of these cells is missing from our protocol, as previous work has suggested that development is comparatively slow in vitro (Sadegh and Macklis, 2014).…”

Section: Discussionsupporting

confidence: 56%

“…more mature) pseudotime neurons ( Figure 3B, right panels). To verify these results, we compared gene expression changes correlated with pseudotime for our in vitro cells to gene expression patterns observed in the developing non-human primate and human brains ( Figure S6) (Bakken et al, 2016). We find that genes positively or negatively correlated with pseudotime in vitro are expressed in similar patterns in vivo.…”

Section: Scrna-seq Analysis Of In Vitro-derived Human Interneuronsmentioning

confidence: 77%

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Single-Cell Profiling of an In Vitro Model of Human Interneuron Development Reveals Temporal Dynamics of Cell Type Production and Maturation

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Yao²,

Miller³

et al. 2017

Neuron

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SummaryGABAergic interneurons are essential for neural circuit function and their loss or dysfunction is implicated in human neuropsychiatric disease. In vitro methods for interneuron generation hold promise for studying human cellular and functional properties and ultimately therapeutic cell replacement. We describe here a protocol for generating cortical interneurons from hESCs and analyze the properties and maturation timecourse of cell types using single-cell RNAseq. We find that the cell types produced mimic in vivo temporal patterns of neuron and glial production, with immature progenitors and neurons observed early and mature cortical neurons and glial cell types produced late. By comparing the transcriptomes of immature interneurons to more mature neurons, we identified genes important for human interneuron differentiation. Many of these genes were previously implicated in neurodevelopmental and neuropsychiatric disorders. Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. HHS Public Access

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Section: Discussionsupporting

confidence: 56%

Section: Scrna-seq Analysis Of In Vitro-derived Human Interneuronsmentioning

confidence: 77%

Single-Cell Profiling of an In Vitro Model of Human Interneuron Development Reveals Temporal Dynamics of Cell Type Production and Maturation

Close¹,

Yao²,

Miller³

et al. 2017

Neuron

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“…To date, many studies have shown the heterogeneity of neural precursor cells (Johnson et al 2015;Llorens-Bobadilla et al 2015) and neurons (Molyneaux et al 2007;Pollen et al 2014;Darmanis et al 2015;Usoskin et al 2015) in mouse and human brain by scRNA-seq. However, due to complexity of data analysis of cellular dynamics, coupled with the biological variability (birth, death, and differentiation) of individual cells, as well as the presence of technical, environmental, and intracellular noise (Kuznetsov 2001(Kuznetsov , 2003Kuznetsov et al 2002;Kim and Marioni 2013;Kharchenko et al 2014;Buettner et al 2015;Daigle et al 2015;Vu et al 2016), it remains a challenge to interpret the heterogeneity and dynamics of NPC to neuron transitions (Camp et al 2015;Bakken et al 2016;Yao et al 2017). Given the lack of synchronous development, the molecular patterns that switch on and switch off pathways governing alternative neuronal fate choices (Ming and Song 2011) are not clear.…”

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confidence: 99%

Single-cell gene expression analysis reveals regulators of distinct cell subpopulations among developing human neurons

et al. 2017

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The stochastic dynamics and regulatory mechanisms that govern differentiation of individual human neural precursor cells (NPC) into mature neurons are currently not fully understood. Here, we used single-cell RNA-sequencing (scRNA-seq) of developing neurons to dissect/identify NPC subtypes and critical developmental stages of alternative lineage specifications. This study comprises an unsupervised, high-resolution strategy for identifying cell developmental bifurcations, tracking the stochastic transcript kinetics of the subpopulations, elucidating regulatory networks, and finding key regulators. Our data revealed the bifurcation and developmental tracks of the two NPC subpopulations, and we captured an early (24 h) transition phase that leads to alternative neuronal specifications. The consequent up-regulation and down-regulation of stageand subpopulation-specific gene groups during the course of maturation revealed biological insights with regard to key regulatory transcription factors and lincRNAs that control cellular programs in the identified neuronal subpopulations.

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“…3 H]dT in macaque monkeys at various gestational ages to label the cohorts of neurons that were born at that period to establish the inside-first, outside-last generation of cortical layers in primates and produce fundamental insights into the timing of the generation of the macaque cortical neuronal cohorts that we still use today (7). Since then we gained a much better understanding of the subplate and its dynamic interactions with incoming afferents and forming cortical circuits in a variety of species (4, [8][9][10][11].…”

mentioning

confidence: 99%

“…Since then we gained a much better understanding of the subplate and its dynamic interactions with incoming afferents and forming cortical circuits in a variety of species (4, [8][9][10][11]. Additionally, the subplate has been the subject of imaging studies and transcriptomic analyses because of increasing evidence for its association with various cognitive developmental disorders (7,(12)(13)(14).…”

mentioning

confidence: 99%