Your search keyword '"Satyan Chintawar"' showing total 3 results

1. Reproducibility of Molecular Phenotypes after Long-Term Differentiation to Human iPSC-Derived Neurons: A Multi-Site Omics Study

Author

Viola Volpato, James Smith, Cynthia Sandor, Janina S. Ried, Anna Baud, Adam Handel, Sarah E. Newey, Frank Wessely, Moustafa Attar, Emma Whiteley, Satyan Chintawar, An Verheyen, Thomas Barta, Majlinda Lako, Lyle Armstrong, Caroline Muschet, Anna Artati, Carlo Cusulin, Klaus Christensen, Christoph Patsch, Eshita Sharma, Jerome Nicod, Philip Brownjohn, Victoria Stubbs, Wendy E. Heywood, Paul Gissen, Roberta De Filippis, Katharina Janssen, Peter Reinhardt, Jerzy Adamski, Ines Royaux, Pieter J. Peeters, Georg C. Terstappen, Martin Graf, Frederick J. Livesey, Colin J. Akerman, Kevin Mills, Rory Bowden, George Nicholson, Caleb Webber, M. Zameel Cader, and Viktor Lakics

Subjects

Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Summary: Reproducibility in molecular and cellular studies is fundamental to scientific discovery. To establish the reproducibility of a well-defined long-term neuronal differentiation protocol, we repeated the cellular and molecular comparison of the same two iPSC lines across five distinct laboratories. Despite uncovering acceptable variability within individual laboratories, we detect poor cross-site reproducibility of the differential gene expression signature between these two lines. Factor analysis identifies the laboratory as the largest source of variation along with several variation-inflating confounders such as passaging effects and progenitor storage. Single-cell transcriptomics shows substantial cellular heterogeneity underlying inter-laboratory variability and being responsible for biases in differential gene expression inference. Factor analysis-based normalization of the combined dataset can remove the nuisance technical effects, enabling the execution of robust hypothesis-generating studies. Our study shows that multi-center collaborations can expose systematic biases and identify critical factors to be standardized when publishing novel protocols, contributing to increased cross-site reproducibility. : In this article, Lakics and colleagues show that, while individual laboratories are able to identify consistent molecular and seemingly statistically robust differences between iPSC neuronal models, cross-site reproducibility is poor. Their findings support multi-center collaborations to expose systematic biases and identify critical factors to be standardized to improve reproducibility in iPSC-based molecular experiments. Keywords: induced pluripotent stem cell, reproducibility, cross-site experimental variation, cortical neurons, gene expression profile, proteomic profiles, single-cell sequencing, molecular profiling, stembancc, public-private partnership

Published

2018

2. A Highly Efficient Human Pluripotent Stem Cell Microglia Model Displays a Neuronal-Co-culture-Specific Expression Profile and Inflammatory Response

Author

Walther Haenseler, Stephen N. Sansom, Julian Buchrieser, Sarah E. Newey, Craig S. Moore, Francesca J. Nicholls, Satyan Chintawar, Christian Schnell, Jack P. Antel, Nicholas D. Allen, M. Zameel Cader, Richard Wade-Martins, William S. James, and Sally A. Cowley

Subjects

human, induced pluripotent stem cell, iPSC, macrophage, microglia, cortical neurons, neuroinflammation, neurodegeneration, Alzheimer's disease, Parkinson's disease, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Microglia are increasingly implicated in brain pathology, particularly neurodegenerative disease, with many genes implicated in Alzheimer's, Parkinson's, and motor neuron disease expressed in microglia. There is, therefore, a need for authentic, efficient in vitro models to study human microglial pathological mechanisms. Microglia originate from the yolk sac as MYB-independent macrophages, migrating into the developing brain to complete differentiation. Here, we recapitulate microglial ontogeny by highly efficient differentiation of embryonic MYB-independent iPSC-derived macrophages then co-culture them with iPSC-derived cortical neurons. Co-cultures retain neuronal maturity and functionality for many weeks. Co-culture microglia express key microglia-specific markers and neurodegenerative disease-relevant genes, develop highly dynamic ramifications, and are phagocytic. Upon activation they become more ameboid, releasing multiple microglia-relevant cytokines. Importantly, co-culture microglia downregulate pathogen-response pathways, upregulate homeostatic function pathways, and promote a more anti-inflammatory and pro-remodeling cytokine response than corresponding monocultures, demonstrating that co-cultures are preferable for modeling authentic microglial physiology.

Published

2017

3. Reproducibility of Molecular Phenotypes after Long-Term Differentiation to Human iPSC-Derived Neurons: A Multi-Site Omics Study

Author

George Nicholson, Lyle Armstrong, Caroline Muschet, Adam E. Handel, Wendy E. Heywood, Eshita Sharma, Pieter J. Peeters, Philip W. Brownjohn, Frank Wessely, Georg C. Terstappen, Carlo Cusulin, Majlinda Lako, Katharina Janssen, Viktor Lakics, Satyan Chintawar, Kevin Mills, Jerzy Adamski, Thomas Barta, Anna Baud, Caleb Webber, Viola Volpato, Moustafa Attar, Roberta De Filippis, Janina S. Ried, Frederick J. Livesey, Peter Reinhardt, Martin Graf, Cynthia Sandor, Jérôme Nicod, Rory Bowden, M. Zameel Cader, Sarah E. Newey, Ines Royaux, Emma S. Whiteley, Aanna Artati, Victoria Stubbs, Paul Gissen, James Smith, An Verheyen, Christoph Patsch, Klaus Christensen, Colin J. Akerman, Smith, James [0000-0001-9131-5849], Brownjohn, Phil [0000-0002-4707-3077], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Proteomics, induced pluripotent stem cell, Genotype, Cellular differentiation, molecular profiling, Induced Pluripotent Stem Cells, Computational biology, Biology, single-cell sequencing, Biochemistry, Article, Cell Line, Transcriptome, 03 medical and health sciences, 0302 clinical medicine, Genetics, cross-site experimental variation, Humans, Induced pluripotent stem cell, lcsh:QH301-705.5, reproducibility, Regulation of gene expression, Neurons, lcsh:R5-920, Reproducibility, Cortical Neurons, Cross-site Experimental Variation, Gene Expression Profile, Induced Pluripotent Stem Cell, Molecular Profiling, Proteomic Profiles, Public-private Partnership, Single-cell Sequencing, Stembancc, cortical neurons, Reproducibility of Results, Cell Differentiation, Cell Biology, proteomic profiles, Phenotype, 3. Good health, public-private partnership, 030104 developmental biology, lcsh:Biology (General), Single cell sequencing, Gene Expression Regulation, gene expression profile, lcsh:Medicine (General), Factor Analysis, Statistical, 030217 neurology & neurosurgery, Developmental Biology, stembancc

Abstract

Summary Reproducibility in molecular and cellular studies is fundamental to scientific discovery. To establish the reproducibility of a well-defined long-term neuronal differentiation protocol, we repeated the cellular and molecular comparison of the same two iPSC lines across five distinct laboratories. Despite uncovering acceptable variability within individual laboratories, we detect poor cross-site reproducibility of the differential gene expression signature between these two lines. Factor analysis identifies the laboratory as the largest source of variation along with several variation-inflating confounders such as passaging effects and progenitor storage. Single-cell transcriptomics shows substantial cellular heterogeneity underlying inter-laboratory variability and being responsible for biases in differential gene expression inference. Factor analysis-based normalization of the combined dataset can remove the nuisance technical effects, enabling the execution of robust hypothesis-generating studies. Our study shows that multi-center collaborations can expose systematic biases and identify critical factors to be standardized when publishing novel protocols, contributing to increased cross-site reproducibility., Highlights • Cross-site reproducibility in iPSC-based molecular experiments is poor • Factor analysis-based normalization can be used to analyze nuisance variation • External validation of iPSC experimental molecular data is critical for reproducibility • Collaborative studies are needed to reveal systematic biases to improve reproducibility, In this article, Lakics and colleagues show that, while individual laboratories are able to identify consistent molecular and seemingly statistically robust differences between iPSC neuronal models, cross-site reproducibility is poor. Their findings support multi-center collaborations to expose systematic biases and identify critical factors to be standardized to improve reproducibility in iPSC-based molecular experiments.

Published

2018