Village in a dish: a model system for population-scale hiPSC studies

Neavin, Drew; Steinmann, Angela; Chiu, Han Sheng; Daniszewski, Maciej; Moutinho, Cátia; Chan, Chia-Ling; Tyebally, Mubarika; Gnanasambandapillai, Vikkitharan; Lam, Chuan En; Nguyen, Uyen; Hernández, Damián; Lidgerwood, Grace E.; Hewitt, Alex W.; Pébay, Alice; Palpant, Nathan J.; Powell, Joseph E.

doi:10.1101/2021.08.19.457030

Cited by 10 publications

(11 citation statements)

References 34 publications

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“…It also enables integration of information across multiple levels, as shown here for the case of gene expression, cell-cycle occupancy, and mating efficiency. The results of this study have the potential to inform the design, execution, and analysis of other one-pot studies of the effects of genetic variation on gene expression, such as human "cell villages" 60,61 .…”

Section: Discussionmentioning

confidence: 97%

Single-cell eQTL mapping in yeast reveals a tradeoff between growth and reproduction

Boocock,

Alexander,

Tapia

et al. 2023

Preprint

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Expression quantitative trait loci (eQTLs) provide a key bridge between noncoding DNA sequence variants and organismal traits. The effects of eQTLs can differ among tissues, cell types, and cellular states, but these differences are obscured by gene expression measurements in bulk populations. We developed a one-pot approach to map eQTLs inSaccharomyces cerevisiaeby single-cell RNA sequencing (scRNA-seq) and applied it to over 100,000 single cells from three crosses. We used scRNA-seq data to genotype each cell, measure gene expression, and classify the cells by cell-cycle stage. We mapped thousands of local and distant eQTLs and identified interactions between eQTL effects and cell-cycle stages. We took advantage of single-cell expression information to identify hundreds of genes with allele-specific effects on expression noise. We used cell-cycle stage classification to map 20 loci that influence cell-cycle progression. One of these loci influenced the expression of genes involved in the mating response. We showed that the effects of this locus arise from a common variant (W82R) in the geneGPA1, which encodes a signaling protein that negatively regulates the mating pathway. The 82R allele increases mating efficiency at the cost of slower cell-cycle progression and is associated with a higher rate of outcrossing in nature. Our results provide a more granular picture of the effects of genetic variants on gene expression and downstream traits.

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Section: Discussionmentioning

confidence: 97%

Single-cell eQTL mapping in yeast reveals a tradeoff between growth and reproduction

Boocock,

Alexander,

Tapia

et al. 2023

Preprint

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“…Donor background also affected phenotypes both directly and indirectly via cell density in wells, and technical across-well variability contributed to screening complexity. While we were able to considerably ameliorate these challenges by combining experimental and computational methods, we believe that the use of pooled formats containing multiple, genetically-diverse cell lines (“cell villages”; (Mitchell et al, 2020; Neavin et al, 2023)) may appreciably reduce remaining variability and enhance our ability to robustly identify phenotypes; this is a direction of future research. We have only begun to understand the richness of information available in our single-cell images.…”

Section: Discussionmentioning

confidence: 99%

Deep Learning Analysis on Images of iPSC-derived Motor Neurons Carrying fALS-genetics Reveals Disease-Relevant Phenotypes

Atmaramani,

Dreossi,

Ford

et al. 2024

Preprint

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Amyotrophic lateral sclerosis (ALS) is a devastating condition with very limited treatment options. It is a heterogeneous disease with complex genetics and unclear etiology, making the discovery of disease-modifying interventions very challenging. To discover novel mechanisms underlying ALS, we leverage a unique platform that combines isogenic, induced pluripotent stem cell (iPSC)-derived models of disease-causing mutations with rich phenotyping via high-content imaging and deep learning models. We introduced eight mutations that cause familial ALS (fALS) into multiple donor iPSC lines, and differentiated them into motor neurons to create multiple isogenic pairs of healthy (wild-type) and sick (mutant) motor neurons. We collected extensive high-content imaging data and used machine learning (ML) to process the images, segment the cells, and learn phenotypes. Self-supervised ML was used to create a concise embedding that captured significant, ALS-relevant biological information in these images. We demonstrate that ML models trained on core cell morphology alone can accurately predict TDP-43 mislocalization, a known phenotypic feature related to ALS. In addition, we were able to impute RNA expression from these image embeddings, in a way that elucidates molecular differences between mutants and wild-type cells. Finally, predictors leveraging these embeddings are able to distinguish between mutant and wild-type both within and across donors, defining cellular, ML-derived disease models for diverse fALS mutations. These disease models are the foundation for a novel screening approach to discover disease-modifying targets for familial ALS.

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“…For example, if placed under the control of appropriate promoters, barcoding proteins could be used to label specific neuronal cell types in genetically homogenous cultures or organoids. Alternatively, barcoding proteins could be used to label cells of a distinct genotype in pooled cultures, as used in larger-scale iPSC-based studies, where cell/donor identity is inferred using single-cell sequencing technologies [ 242 , 243 , 244 ], thereby increasing the throughput, decreasing the cost, and minimising potential artefacts from handling multiple cultures in parallel.…”

Section: Challenges and Caveats Of Using Gefbsmentioning

confidence: 99%

Seeing Neurodegeneration in a New Light Using Genetically Encoded Fluorescent Biosensors and iPSCs

Stellon

Talbot

Hewitt

et al. 2023

IJMS

Self Cite

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Neurodegenerative diseases present a progressive loss of neuronal structure and function, leading to cell death and irrecoverable brain atrophy. Most have disease-modifying therapies, in part because the mechanisms of neurodegeneration are yet to be defined, preventing the development of targeted therapies. To overcome this, there is a need for tools that enable a quantitative assessment of how cellular mechanisms and diverse environmental conditions contribute to disease. One such tool is genetically encodable fluorescent biosensors (GEFBs), engineered constructs encoding proteins with novel functions capable of sensing spatiotemporal changes in specific pathways, enzyme functions, or metabolite levels. GEFB technology therefore presents a plethora of unique sensing capabilities that, when coupled with induced pluripotent stem cells (iPSCs), present a powerful tool for exploring disease mechanisms and identifying novel therapeutics. In this review, we discuss different GEFBs relevant to neurodegenerative disease and how they can be used with iPSCs to illuminate unresolved questions about causes and risks for neurodegenerative disease.

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Village in a dish: a model system for population-scale hiPSC studies

Cited by 10 publications

References 34 publications

Single-cell eQTL mapping in yeast reveals a tradeoff between growth and reproduction

Single-cell eQTL mapping in yeast reveals a tradeoff between growth and reproduction

Deep Learning Analysis on Images of iPSC-derived Motor Neurons Carrying fALS-genetics Reveals Disease-Relevant Phenotypes

Seeing Neurodegeneration in a New Light Using Genetically Encoded Fluorescent Biosensors and iPSCs

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