Your search keyword '"Lukowski SW"' showing total 2 results

1. Single-cell RNA-seq of human induced pluripotent stem cells reveals cellular heterogeneity and cell state transitions between subpopulations.

Author

Nguyen QH, Lukowski SW, Chiu HS, Senabouth A, Bruxner TJC, Christ AN, Palpant NJ, and Powell JE

Subjects

Cell Differentiation genetics, Cell Line, Cluster Analysis, Clustered Regularly Interspaced Short Palindromic Repeats genetics, Gene Expression genetics, Genetic Heterogeneity, Genetic Markers genetics, Humans, Sequence Analysis, RNA methods, Transcription, Genetic genetics, Induced Pluripotent Stem Cells cytology, RNA genetics

Abstract

Heterogeneity of cell states represented in pluripotent cultures has not been described at the transcriptional level. Since gene expression is highly heterogeneous between cells, single-cell RNA sequencing can be used to identify how individual pluripotent cells function. Here, we present results from the analysis of single-cell RNA sequencing data from 18,787 individual WTC-CRISPRi human induced pluripotent stem cells. We developed an unsupervised clustering method and, through this, identified four subpopulations distinguishable on the basis of their pluripotent state, including a core pluripotent population (48.3%), proliferative (47.8%), early primed for differentiation (2.8%), and late primed for differentiation (1.1%). For each subpopulation, we were able to identify the genes and pathways that define differences in pluripotent cell states. Our method identified four transcriptionally distinct predictor gene sets composed of 165 unique genes that denote the specific pluripotency states; using these sets, we developed a multigenic machine learning prediction method to accurately classify single cells into each of the subpopulations. Compared against a set of established pluripotency markers, our method increases prediction accuracy by 10%, specificity by 20%, and explains a substantially larger proportion of deviance (up to threefold) from the prediction model. Finally, we developed an innovative method to predict cells transitioning between subpopulations and support our conclusions with results from two orthogonal pseudotime trajectory methods., (© 2018 Nguyen et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2018

2. Slightly deleterious genomic variants and transcriptome perturbations in Down syndrome embryonic selection.

Author

Popadin K, Peischl S, Garieri M, Sailani MR, Letourneau A, Santoni F, Lukowski SW, Bazykin GA, Nikolaev S, Meyer D, Excoffier L, Reymond A, and Antonarakis SE

Subjects

Abortion, Spontaneous, Female, Humans, Pregnancy, Aneuploidy, Chromosomes, Human, Pair 21 genetics, Down Syndrome embryology, Down Syndrome genetics, Genotype, Transcriptome

Abstract

The majority of aneuploid fetuses are spontaneously miscarried. Nevertheless, some aneuploid individuals survive despite the strong genetic insult. Here, we investigate if the survival probability of aneuploid fetuses is affected by the genome-wide burden of slightly deleterious variants. We analyzed two cohorts of live-born Down syndrome individuals (388 genotyped samples and 16 fibroblast transcriptomes) and observed a deficit of slightly deleterious variants on Chromosome 21 and decreased transcriptome-wide variation in the expression level of highly constrained genes. We interpret these results as signatures of embryonic selection, and propose a genetic handicap model whereby an individual bearing an extremely severe deleterious variant (such as aneuploidy) could escape embryonic lethality if the genome-wide burden of slightly deleterious variants is sufficiently low. This approach can be used to study the composition and effect of the numerous slightly deleterious variants in humans and model organisms., (© 2018 Popadin et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2018