Your search keyword '"Lancaster, Madeline A."' showing total 9 results

1. Androgens increase excitatory neurogenic potential in human brain organoids.

Author

Kelava I, Chiaradia I, Pellegrini L, Kalinka AT, and Lancaster MA

Subjects

Action Potentials drug effects, Androgens metabolism, Brain drug effects, Brain enzymology, Brain metabolism, Cell Count, Female, Gene Expression Profiling, Histone Deacetylases genetics, Humans, Male, Neural Inhibition drug effects, Neuroglia cytology, Neuroglia drug effects, Organ Size drug effects, Organoids enzymology, Organoids metabolism, Stem Cells cytology, Stem Cells drug effects, TOR Serine-Threonine Kinases genetics, Androgens pharmacology, Brain cytology, Cortical Excitability drug effects, Neurogenesis drug effects, Organoids cytology, Organoids drug effects, Sex Characteristics

Abstract

The biological basis of male-female brain differences has been difficult to elucidate in humans. The most notable morphological difference is size, with male individuals having on average a larger brain than female individuals 1,2 , but a mechanistic understanding of how this difference arises remains unknown. Here we use brain organoids 3 to show that although sex chromosomal complement has no observable effect on neurogenesis, sex steroids-namely androgens-lead to increased proliferation of cortical progenitors and an increased neurogenic pool. Transcriptomic analysis and functional studies demonstrate downstream effects on histone deacetylase activity and the mTOR pathway. Finally, we show that androgens specifically increase the neurogenic output of excitatory neuronal progenitors, whereas inhibitory neuronal progenitors are not increased. These findings reveal a role for androgens in regulating the number of excitatory neurons and represent a step towards understanding the origin of sex-related brain differences in humans., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

2. Brain Organoids: Human Neurodevelopment in a Dish.

Author

Benito-Kwiecinski S and Lancaster MA

Subjects

Animals, Cell Culture Techniques, Cell Survival, Developmental Biology, Embryonic Stem Cells cytology, Humans, In Vitro Techniques, Induced Pluripotent Stem Cells physiology, Mice, Models, Animal, Necrosis, Reproducibility of Results, Signal Transduction, Tissue Engineering methods, Brain embryology, Brain growth & development, Embryoid Bodies cytology, Neurogenesis, Organoids growth & development

Abstract

The human brain is often described as the most complex organ in our body. Because of the limited accessibility of living brain tissue, human-specific features of neurodevelopment and disease remain largely unknown. The ability of induced pluripotent stem cells to self-organize into 3D brain organoids has revolutionized approaches to studying brain development in vitro. This review will first look at the history of studying neural development in a dish and how organoids came to be. We evaluate the ability of brain organoids to recapitulate key developmental events, focusing on the generation of various regional identities, cytoarchitecture, cell diversity, features of neuronal maturation, and circuit formation. We also consider the limitations of the model and review recent approaches to improve reproducibility and the healthy maturation of brain organoids., (Copyright © 2020 Cold Spring Harbor Laboratory Press; all rights reserved.)

Published

2020

3. Brain organoids get vascularized.

Author

Lancaster MA

Subjects

Animals, Cell Movement genetics, Humans, Mice, Neurons cytology, Neurons physiology, Blood Vessels growth & development, Brain growth & development, Neurogenesis genetics, Organoids growth & development

Published

2018

4. Guided self-organization and cortical plate formation in human brain organoids.

Author

Lancaster MA, Corsini NS, Wolfinger S, Gustafson EH, Phillips AW, Burkard TR, Otani T, Livesey FJ, and Knoblich JA

Subjects

Cells, Cultured, Guided Tissue Regeneration methods, Humans, Neural Stem Cells cytology, Organ Culture Techniques methods, Organoids cytology, Prosencephalon cytology, Batch Cell Culture Techniques methods, Neural Stem Cells physiology, Neurogenesis physiology, Organoids growth & development, Prosencephalon growth & development, Tissue Engineering methods

Abstract

Three-dimensional cell culture models have either relied on the self-organizing properties of mammalian cells or used bioengineered constructs to arrange cells in an organ-like configuration. While self-organizing organoids excel at recapitulating early developmental events, bioengineered constructs reproducibly generate desired tissue architectures. Here, we combine these two approaches to reproducibly generate human forebrain tissue while maintaining its self-organizing capacity. We use poly(lactide-co-glycolide) copolymer (PLGA) fiber microfilaments as a floating scaffold to generate elongated embryoid bodies. Microfilament-engineered cerebral organoids (enCORs) display enhanced neuroectoderm formation and improved cortical development. Furthermore, reconstitution of the basement membrane leads to characteristic cortical tissue architecture, including formation of a polarized cortical plate and radial units. Thus, enCORs model the distinctive radial organization of the cerebral cortex and allow for the study of neuronal migration. Our data demonstrate that combining 3D cell culture with bioengineering can increase reproducibility and improve tissue architecture.

Published

2017

5. Creating Patient-Specific Neural Cells for the In Vitro Study of Brain Disorders.

Author

Brennand KJ, Marchetto MC, Benvenisty N, Brüstle O, Ebert A, Izpisua Belmonte JC, Kaykas A, Lancaster MA, Livesey FJ, McConnell MJ, McKay RD, Morrow EM, Muotri AR, Panchision DM, Rubin LL, Sawa A, Soldner F, Song H, Studer L, Temple S, Vaccarino FM, Wu J, Vanderhaeghen P, Gage FH, and Jaenisch R

Subjects

Brain drug effects, Brain metabolism, Brain physiopathology, Brain Diseases drug therapy, Brain Diseases genetics, Brain Diseases physiopathology, Drug Discovery methods, Humans, Induced Pluripotent Stem Cells cytology, Induced Pluripotent Stem Cells metabolism, Mosaicism, Precision Medicine methods, Brain pathology, Brain Diseases pathology, Induced Pluripotent Stem Cells pathology, Neurogenesis

Abstract

As a group, we met to discuss the current challenges for creating meaningful patient-specific in vitro models to study brain disorders. Although the convergence of findings between laboratories and patient cohorts provided us confidence and optimism that hiPSC-based platforms will inform future drug discovery efforts, a number of critical technical challenges remain. This opinion piece outlines our collective views on the current state of hiPSC-based disease modeling and discusses what we see to be the critical objectives that must be addressed collectively as a field., (Copyright © 2015 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2015

6. Self‐organized developmental patterning and differentiation in cerebral organoids

Author

Renner, Magdalena, Lancaster, Madeline A, Bian, Shan, Choi, Heejin, Ku, Taeyun, Peer, Angela, Chung, Kwanghun, and Knoblich, Juergen A

Published

2017

7. Population-scale single-cell RNA-seq profiling across dopaminergic neuron differentiation

Author

Jerber, Julie, Seaton, Daniel D, Cuomo, Anna SE, Kumasaka, Natsuhiko, Haldane, James, Steer, Juliette, Patel, Minal, Pearce, Daniel, Andersson, Malin, Bonder, Marc Jan, Mountjoy, Ed, Ghoussaini, Maya, Lancaster, Madeline A, HipSci Consortium, Marioni, John C, Merkle, Florian T, Gaffney, Daniel J, Stegle, Oliver, Seaton, Daniel D [0000-0002-5222-3893], Cuomo, Anna SE [0000-0001-5168-6979], Kumasaka, Natsuhiko [0000-0002-3557-0375], Haldane, James [0000-0001-7778-9036], Steer, Juliette [0000-0001-8086-7955], Andersson, Malin [0000-0003-1935-1989], Marioni, John C [0000-0001-9092-0852], Merkle, Florian T [0000-0002-8513-2998], Gaffney, Daniel J [0000-0002-1529-1862], Stegle, Oliver [0000-0002-8818-7193], and Apollo - University of Cambridge Repository

Subjects

Oxidative Stress, Sequence Analysis, RNA, Dopaminergic Neurons, Neurogenesis, Rotenone, Induced Pluripotent Stem Cells, Quantitative Trait Loci, Humans, Cell Differentiation, Genetic Predisposition to Disease, Receptor, Fibroblast Growth Factor, Type 1, Single-Cell Analysis, Transcriptome

Abstract

Studying the function of common genetic variants in primary human tissues and during development is challenging. To address this, we use an efficient multiplexing strategy to differentiate 215 human induced pluripotent stem cell (iPSC) lines toward a midbrain neural fate, including dopaminergic neurons, and use single-cell RNA sequencing (scRNA-seq) to profile over 1 million cells across three differentiation time points. The proportion of neurons produced by each cell line is highly reproducible and is predictable by robust molecular markers expressed in pluripotent cells. Expression quantitative trait loci (eQTL) were characterized at different stages of neuronal development and in response to rotenone-induced oxidative stress. Of these, 1,284 eQTL colocalize with known neurological trait risk loci, and 46% are not found in the Genotype-Tissue Expression (GTEx) catalog. Our study illustrates how coupling scRNA-seq with long-term iPSC differentiation enables mechanistic studies of human trait-associated genetic variants in otherwise inaccessible cell states.

Published

2021

8. Spindle orientation in mammalian cerebral cortical development

Author

Lancaster, Madeline A and Knoblich, Juergen A

Subjects

Cerebral Cortex, Mammals, Neurons, Neuroscience(all), Neurogenesis, Animals, Cell Polarity, Humans, Spindle Apparatus, Neuroglia, Article, Cell Proliferation

Abstract

Highlights ► Spindle orientation is a key mechanism for generating cell diversity and balancing self-renewal and differentiation of neural stem cells. ► Regulators of spindle orientation, such as mInsc and LGN, are necessary for balancing planar and oblique orientations in the developing mammalian cerebral cortex. ► Spindle orientation influences neuron production and cortical size by regulating production of intermediate progenitors and outer radial glial progenitors., In any mitotic cell, the orientation of the mitotic spindle determines the orientation of the cleavage plane and therefore the position of the two daughter cells. When combined with polarization of cellular components, spindle orientation is also a well-conserved means of generating daughter cells with asymmetric cell fates, such as progenitors and differentiated cell types. In the mammalian neocortex, the precise planar spindle orientation observed early during development is vital for symmetric proliferative divisions. During later stages, spindles can be oblique or even vertical but the role of this reorientation is somewhat less clear as asymmetric cell fates can arise independently of spindle orientation during this stage. Although decades of work have identified many key conserved regulators of spindle positioning, its precise role in cell fate determination in the mammalian neocortex has been enigmatic. Recent work focused on mInsc and LGN has now revealed an important role for spindle orientation in determination of specific asymmetric cell fates, namely intermediate progenitors and a new progenitor population, termed outer radial glia. In this way, spindle orientation helps determine the neurogenic outcome of asymmetric progenitor divisions, thereby influencing neuron output and cerebral cortical expansion.

Published

2012

9. Characterising molecular and cellular mechanisms of human brain evolution using brain organoids

Author

Benito Kwiecinski, Silvia Kima and Lancaster, Madeline

Subjects

brain evolution, brain organoids, neural progenitor cells, neurogenesis, gorilla, chimpanzee, AUTS2, ZEB2

Abstract

The evolutionary lineage of humans is marked by a rapid expansion in brain size. Efforts to study human brain evolution have characteristically relied on anatomical and genomic comparisons between adult ape brains, meaning that the molecular mechanisms underlying human-specific brain expansion remain largely unknown. In this work we show that brain organoids can be used to identify and functionally test mechanisms underlying human-specific features of brain development. Through a meta-analysis of comparative genomics and transcriptomics, we identified candidate regulators of human brain evolution. We show that the function of these candidate genes can be queried in human brain organoids by analysing the effect of gain-of-function in a subset of radial glial cells. We find that the transcriptional regulator, AUTS2, has a dramatic effect on cell fate and tissue architecture. By generating organoids with loss-of-function of C-terminal-containing AUTS2 isoforms, we find neurogenesis is premature, which may reflect the microcephaly observed in humans with disruptions in AUTS2. In order to screen large numbers of human brain evolution candidates in parallel, we scale up organoid production in Aggrewell plates and evaluate the use of inducible CRISPR-Cas9 hESC lines to perform loss-of-function screens. We show that Aggrewell organoids can be used to detect phenotypes affecting early tissue architecture and neural progenitor cell (NPC) behaviour. Building on this, we perform comparative analyses of early neural morphogenesis using brain organoids derived from human, gorilla, chimpanzee and mouse. We find that the differentiation of proliferative neuroepithelial NPCs into neurogenic radial glial NPCs is a protracted process in apes and involves a previously unrecognised transitioning cell state, characterised by a change in cell morphology. We show that human organoids are delayed in this transition and generate more expanded tissue than the other species as a result. RNA-sequencing of human and gorilla organoids reveals differences in temporal gene expression patterns associated with biological functions. We find a delay in human gene expression patterns associated with cell morphogenesis, which in particular highlights ZEB2, a transcription factor known as a core regulator of epithelial-to-mesenchymal transition. Through gain-of-function in human, we show that ZEB2 is sufficient to trigger the transition of neuroepithelial cells which mimics nonhuman ape tissue architecture. Thus, we have demonstrated an instructive role of NPC shape regulation in brain evolution and established brain organoids as a model to identify and functionally test molecular mechanisms governing evolutionary differences in brain architecture.

Published

2020