Your search keyword '"Olena Kuksenko"' showing total 9 results

1. Multiplexed single-cell transcriptional response profiling to define cancer vulnerabilities and therapeutic mechanism of action

Author

James M. McFarland, Brenton R. Paolella, Allison Warren, Kathryn Geiger-Schuller, Tsukasa Shibue, Michael Rothberg, Olena Kuksenko, William N. Colgan, Andrew Jones, Emily Chambers, Danielle Dionne, Samantha Bender, Brian M. Wolpin, Mahmoud Ghandi, Itay Tirosh, Orit Rozenblatt-Rosen, Jennifer A. Roth, Todd R. Golub, Aviv Regev, Andrew J. Aguirre, Francisca Vazquez, and Aviad Tsherniak

Subjects

Science

Abstract

Large-scale screens of chemical and genetic vulnerabilities in cancer are typically limited to simple readouts of cell viability. Here, the authors develop a method for profiling post-perturbation transcriptional responses across large pools of cancer cell lines, enabling deep characterization of shared and context-specific responses.

Published

2020

2. Systematically characterizing the roles of E3-ligase family members in inflammatory responses with massively parallel Perturb-seq

Author

Kathryn Geiger-Schuller, Basak Eraslan, Olena Kuksenko, Kushal K. Dey, Karthik A. Jagadeesh, Pratiksha I. Thakore, Ozge Karayel, Andrea R. Yung, Anugraha Rajagopalan, Ana M Meireles, Karren Dai Yang, Liat Amir-Zilberstein, Toni Delorey, Devan Phillips, Raktima Raychowdhury, Christine Moussion, Alkes L. Price, Nir Hacohen, John G. Doench, Caroline Uhler, Orit Rozenblatt-Rosen, and Aviv Regev

Subjects

Article

Abstract

E3 ligases regulate key processes, but many of their roles remain unknown. Using Perturb-seq, we interrogated the function of 1,130 E3 ligases, partners and substrates in the inflammatory response in primary dendritic cells (DCs). Dozens impacted the balance of DC1, DC2, migratory DC and macrophage states and a gradient of DC maturation. Family members grouped into co-functional modules that were enriched for physical interactions and impacted specific programs through substrate transcription factors. E3s and their adaptors co-regulated the same processes, but partnered with different substrate recognition adaptors to impact distinct aspects of the DC life cycle. Genetic interactions were more prevalent within than between modules, and a deep learning model, comβVAE, predicts the outcome of new combinations by leveraging modularity. The E3 regulatory network was associated with heritable variation and aberrant gene expression in immune cells in human inflammatory diseases. Our study provides a general approach to dissect gene function.

Published

2023

3. Single-nucleus cross-tissue molecular reference maps toward understanding disease gene function

Author

Gökcen Eraslan, Eugene Drokhlyansky, Shankara Anand, Evgenij Fiskin, Ayshwarya Subramanian, Michal Slyper, Jiali Wang, Nicholas Van Wittenberghe, John M. Rouhana, Julia Waldman, Orr Ashenberg, Monkol Lek, Danielle Dionne, Thet Su Win, Michael S. Cuoco, Olena Kuksenko, Alexander M. Tsankov, Philip A. Branton, Jamie L. Marshall, Anna Greka, Gad Getz, Ayellet V. Segrè, François Aguet, Orit Rozenblatt-Rosen, Kristin G. Ardlie, and Aviv Regev

Subjects

Multidisciplinary

Abstract

Understanding gene function and regulation in homeostasis and disease requires knowledge of the cellular and tissue contexts in which genes are expressed. Here, we applied four single-nucleus RNA sequencing methods to eight diverse, archived, frozen tissue types from 16 donors and 25 samples, generating a cross-tissue atlas of 209,126 nuclei profiles, which we integrated across tissues, donors, and laboratory methods with a conditional variational autoencoder. Using the resulting cross-tissue atlas, we highlight shared and tissue-specific features of tissue-resident cell populations; identify cell types that might contribute to neuromuscular, metabolic, and immune components of monogenic diseases and the biological processes involved in their pathology; and determine cell types and gene modules that might underlie disease mechanisms for complex traits analyzed by genome-wide association studies.

Published

2022

4. A transcription factor atlas of directed differentiation

Author

Julia Joung, Sai Ma, Tristan Tay, Kathryn R. Geiger-Schuller, Paul C. Kirchgatterer, Vanessa K. Verdine, Baolin Guo, Mario A. Arias-Garcia, William E. Allen, Ankita Singh, Olena Kuksenko, Omar O. Abudayyeh, Jonathan S. Gootenberg, Zhanyan Fu, Rhiannon K. Macrae, Jason D. Buenrostro, Aviv Regev, and Feng Zhang

Subjects

General Biochemistry, Genetics and Molecular Biology

Abstract

Transcription factors (TFs) regulate gene programs, thereby controlling diverse cellular processes and cell states. To comprehensively understand TFs and the programs they control, we created a barcoded library of all annotated human TF splice isoforms (3,500) and applied it to build a TF Atlas charting expression profiles of human embryonic stem cells (hESCs) overexpressing each TF at single-cell resolution. We mapped TF-induced expression profiles to reference cell types and validated candidate TFs for generation of diverse cell types, spanning all three germ layers and trophoblasts. Targeted screens with subsets of the library allowed us to create a tailored cellular disease model and integrate mRNA expression and chromatin accessibility data to identify downstream regulators. Finally, we characterized the effects of combinatorial TF overexpression by developing and validating a strategy for predicting combinations of TFs that produce target expression profiles matching reference cell types to accelerate cellular engineering efforts.

Published

2022

5. Single-nucleus cross-tissue molecular reference maps to decipher disease gene function

Author

Olena Kuksenko, John M. Rouhana, Anna Greka, Aviv Regev, Orit Rozenblatt-Rosen, François Aguet, Evgenij Fiskin, Nicholas Van Wittenberghe, Philip A. Branton, Julia Waldman, Danielle Dionne, Eugene Drokhlyansky, Ayellet V. Segrè, Michael S. Cuoco, Ayshwarya Subramanian, Jiali Wang, Kristin G. Ardlie, Gökcen Eraslan, Michal Slyper, Thet Su Win, Shankara Anand, Gad Getz, Orr Ashenberg, and Jamie L. Marshall

Subjects

Cell type, Context (language use), Genomics, Genome-wide association study, Human leukocyte antigen, Computational biology, Biology, Gene, Function (biology), Tissue homeostasis

Abstract

Understanding the function of genes and their regulation in tissue homeostasis and disease requires knowing the cellular context in which genes are expressed in tissues across the body. Single cell genomics allows the generation of detailed cellular atlases in human tissues, but most efforts are focused on single tissue types. Here, we establish a framework for profiling multiple tissues across the human body at single-cell resolution using single nucleus RNA-Seq (snRNA-seq), and apply it to 8 diverse, archived, frozen tissue types (three donors per tissue). We apply four snRNA-seq methods to each of 25 samples from 16 donors, generating a cross-tissue atlas of 209,126 nuclei profiles, and benchmark them vs. scRNA-seq of comparable fresh tissues. We use a conditional variational autoencoder (cVAE) to integrate an atlas across tissues, donors, and laboratory methods. We highlight shared and tissue-specific features of tissue-resident immune cells, identifying tissue-restricted and non-restricted resident myeloid populations. These include a cross-tissue conserved dichotomy between LYVE1- and HLA class II-expressing macrophages, and the broad presence of LAM-like macrophages across healthy tissues that is also observed in disease. For rare, monogenic muscle diseases, we identify cell types that likely underlie the neuromuscular, metabolic, and immune components of these diseases, and biological processes involved in their pathology. For common complex diseases and traits analyzed by GWAS, we identify the cell types and gene modules that potentially underlie disease mechanisms. The experimental and analytical frameworks we describe will enable the generation of large-scale studies of how cellular and molecular processes vary across individuals and populations.

Published

2021

6. Multiplexed single-cell transcriptional response profiling to define cancer vulnerabilities and therapeutic mechanism of action

Author

William Colgan, Itay Tirosh, Emily Chambers, Andrew Jones, James M. McFarland, Jennifer Roth, Aviad Tsherniak, Michael V. Rothberg, Samantha Bender, Todd R. Golub, Kathryn Geiger-Schuller, Francisca Vazquez, Mahmoud Ghandi, Andrew J. Aguirre, Allison Warren, Olena Kuksenko, Aviv Regev, Orit Rozenblatt-Rosen, Brenton R. Paolella, Danielle Dionne, Tsukasa Shibue, and Brian M. Wolpin

Subjects

0301 basic medicine, Cell Survival, Pyridones, Science, Cell, General Physics and Astronomy, Antineoplastic Agents, Pyrimidinones, 02 engineering and technology, Computational biology, Biology, Polymorphism, Single Nucleotide, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Gene expression analysis, Cell Line, Tumor, Neoplasms, Cancer genomics, medicine, Humans, SNP, Multiplex, Viability assay, lcsh:Science, Models, Statistical, Multidisciplinary, Base Sequence, Gene Expression Profiling, General Chemistry, 021001 nanoscience & nanotechnology, Phenotype, Gene Expression Regulation, Neoplastic, Gene expression profiling, 030104 developmental biology, medicine.anatomical_structure, Mechanism of action, Cancer cell, lcsh:Q, Single-Cell Analysis, medicine.symptom, 0210 nano-technology

Abstract

Assays to study cancer cell responses to pharmacologic or genetic perturbations are typically restricted to using simple phenotypic readouts such as proliferation rate. Information-rich assays, such as gene-expression profiling, have generally not permitted efficient profiling of a given perturbation across multiple cellular contexts. Here, we develop MIX-Seq, a method for multiplexed transcriptional profiling of post-perturbation responses across a mixture of samples with single-cell resolution, using SNP-based computational demultiplexing of single-cell RNA-sequencing data. We show that MIX-Seq can be used to profile responses to chemical or genetic perturbations across pools of 100 or more cancer cell lines. We combine it with Cell Hashing to further multiplex additional experimental conditions, such as post-treatment time points or drug doses. Analyzing the high-content readout of scRNA-seq reveals both shared and context-specific transcriptional response components that can identify drug mechanism of action and enable prediction of long-term cell viability from short-term transcriptional responses to treatment., Large-scale screens of chemical and genetic vulnerabilities in cancer are typically limited to simple readouts of cell viability. Here, the authors develop a method for profiling post-perturbation transcriptional responses across large pools of cancer cell lines, enabling deep characterization of shared and context-specific responses.

Published

2020

7. Multiplexed single-cell profiling of post-perturbation transcriptional responses to define cancer vulnerabilities and therapeutic mechanism of action

Author

Francisca Vazquez, Kathryn Geiger-Schuller, Danielle Dionne, Tsukasa Shibue, Samantha Bender, Todd R. Golub, Aviad Tsherniak, Andrew Jones, Orit Rozenblatt-Rosen, Andrew J. Aguirre, Mahmoud Ghandi, Brenton R. Paolella, James M. McFarland, Aviv Regev, Brian M. Wolpin, Allison Warren, Jennifer Roth, Emily Chambers, Michael V. Rothberg, Itay Tirosh, and Olena Kuksenko

Subjects

0303 health sciences, Cell, Computational biology, Biology, Marker gene, Phenotype, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Mechanism of action, 030220 oncology & carcinogenesis, Cancer cell, medicine, SNP, Multiplex, Viability assay, medicine.symptom, 030304 developmental biology

Abstract

Assays to study cancer cell responses to pharmacologic or genetic perturbations are typically restricted to using simple phenotypic readouts such as proliferation rate or the expression of a marker gene. Information-rich assays, such as gene-expression profiling, are generally not amenable to efficient profiling of a given perturbation across multiple cellular contexts. Here, we developed MIX-Seq, a method for multiplexed transcriptional profiling of post-perturbation responses across a mixture of samples with single-cell resolution, using SNP-based computational demultiplexing of single-cell RNA-sequencing data. We show that MIX-Seq can be used to profile responses to chemical or genetic perturbations across pools of 100 or more cancer cell lines, and combine it with Cell Hashing to further multiplex additional experimental conditions, such as multiple post-treatment time points or drug doses. Analyzing the high-content readout of scRNA-seq reveals both shared and context-specific transcriptional response components that can identify drug mechanism of action and can be used to predict long-term cell viability from short-term transcriptional responses to treatment.

Published

2019

8. Shuffle-Seq: En masse combinatorial encoding for n-way genetic interaction screens

Author

Aviv Regev, Atray Dixit, Olena Kuksenko, and David Feldman

Subjects

Genetic interaction, Encoding (memory), Pairwise comparison, Synthetic lethality, Computational biology, Mammalian genome, Genotype to phenotype, Biology, Phenotype, Gene

Abstract

Genetic interactions, defined as the non-additive phenotypic impact of combinations of genes, are a hallmark of the mapping from genotype to phenotype. However, genetic interactions remain challenging to systematically test given the massive number of possible combinations. In particular, while large-scale screening efforts in yeast have quantified pairwise interactions that affect cell viability, or synthetic lethality, between all pairs of genes as well as for a limited number of three-way interactions, it has previously been intractable to perform the large screens needed to comprehensively assess interactions in a mammalian genome. Here, we develop Shuffle-Seq, a scalable method to assay genetic interactions. Shuffle-Seq leverages the co-inheritance of genetically encoded barcodes in dividing cells and can scale in proportion to sequencing throughput. We demonstrate the technical validity of Shuffle-Seq and apply it to screening for mechanisms underlying drug resistance in a melanoma model. Shuffle-Seq should allow screens of hundreds of millions of combinatorial perturbations and facilitate the understanding of genetic dependencies and drug sensitivities.

Published

2019

9. The Human and Mouse Enteric Nervous System at Single-Cell Resolution

Author

Olena Kuksenko, Nicholas Van Wittenberghe, Gökcen Eraslan, Aviv Regev, Eugene Drokhlyansky, Michael S. Cuoco, Gabriel K. Griffin, Christopher Smillie, Genevieve M. Boland, Maria Ericsson, Orit Rozenblatt-Rosen, Tatyana Sharova, Max N. Goder-Reiser, Danielle Dionne, Andrew J. Aguirre, Daniel B. Graham, and Ramnik J. Xavier

Subjects

Male, Aging, Colon, Cell, Genome-wide association study, Ileum, Mice, Transgenic, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Enteric Nervous System, 03 medical and health sciences, Mice, 0302 clinical medicine, Microscopy, Electron, Transmission, Circadian Clocks, Intestine, Small, medicine, Animals, Humans, Genetic Predisposition to Disease, RNA, Messenger, RNA-Seq, Gene, 030304 developmental biology, Inflammation, Neurons, 0303 health sciences, Messenger RNA, Gene Expression Regulation, Developmental, Epithelial Cells, Cell biology, Mice, Inbred C57BL, Intestinal Diseases, medicine.anatomical_structure, Nissl Bodies, Enteric nervous system, Female, Neuron, Endoplasmic Reticulum, Rough, Distal colon, Nervous System Diseases, Single-Cell Analysis, Stromal Cells, Neuroglia, Ribosomes, 030217 neurology & neurosurgery

Abstract

The enteric nervous system (ENS) coordinates diverse functions in the intestine but has eluded comprehensive molecular characterization because of the rarity and diversity of cells. Here we develop two methods to profile the ENS of adult mice and humans at single-cell resolution: RAISIN RNA-seq for profiling intact nuclei with ribosome-bound mRNA and MIRACL-seq for label-free enrichment of rare cell types by droplet-based profiling. The 1,187,535 nuclei in our mouse atlas include 5,068 neurons from the ileum and colon, revealing extraordinary neuron diversity. We highlight circadian expression changes in enteric neurons, show that disease-related genes are dysregulated with aging, and identify differences between the ileum and proximal/distal colon. In humans, we profile 436,202 nuclei, recovering 1,445 neurons, and identify conserved and species-specific transcriptional programs and putative neuro-epithelial, neuro-stromal, and neuro-immune interactions. The human ENS expresses risk genes for neuropathic, inflammatory, and extra-intestinal diseases, suggesting neuronal contributions to disease.

Published

2019