Developing new tools to study and program cell fate at the single-cell level

Marjan Biocanin
EPFL, 2021
Thèse EPFL

Résumé

Single-cell transcriptomics (scRNA-seq) started a technological revolution in biology by enabling through the plethora of methods to assess a molecular state of the cell on systems level without the strict necessity of the prior knowledge of the cell state. This wealth of data enabled us to answer fundamental problems of biology â how cells develop into plastic tissue, how they orchestrate developmental and homeostatic processes?

This thesis will cover developing novel methods and assays to study, map and perturb cell fates using droplet microfluidics-based scRNA-seq. First part will cover our re-engineering Drop-seq setup, for broader adoption and more efficient sample handling. The developments presented will cover a novel flexible workflow that significantly simplifies the sample handling while being efficient in single-cell material recovery.

Building on previous advances, the next part will cover a novel dropleting platform for deterministic mRNA capture bead and cell co-encapsulation (DisCo) and its application to study single intestinal organoid development. Here, a key advancement, so far unsolved in the field is ability to deterministically control the cell capture process. Although at lower throughput than other droplet microfluidics-based methods, this method allows processing low cell input samples with high capture efficiencies. As a proof-of-concept study, we have studied early development of single intestinal organoids. DisCo helped us in uncovering extensive organoid heterogeneity and to identify the three distinct and aberrant subtypes of intestinal organoids such as enterocysts, spheroids and gobloids.

Finally, the third part will cover the development of novel gain of function barcoded transcription factor (TF) screening in conjugation with scRNA-seq (TF-seq). To understand the role of TF in maintaining cell types, systematic manipulation of TFs combined by global gene expression profiling will aid in delineating their role in cell state progression and maintenance. We applied TF-seq on murine mesenchymal stem cell-like C3H10T1/2 model and found multiple known factors that program cells to adipose (Cebpa, Pparg), osteogenic (Runx2, Dlx3), and myogenic lineages (Myod, Myog). Additionally, we discovered and confirmed two novel TFs (Rhox12, Mycn) involved in adipogenesis. By analyzing both TF activity and genome-wide changes caused, this approach has the power to uncover both strong and weak drivers of lineage commitment among TFs.

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https://infoscience.epfl.ch/record/286163?ln=fr

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Marjan Biocanin
EPFL, 2021
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/286163?ln=fr

À propos de ce résultat

Concepts associés (30)

Concepts associés

Chargement

Publications associées (65)

Publications associées

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Assessing the role of Hes1 and identification of target genes in human and murine T-ALL

Silvia Wirth

The Notch signalling pathway is an ancient cell signalling mechanism that enables short-range communications between cells and controls a broad spectrum of cell fates and developmental processes. In the haematopoietic system Notch signalling has been linked to physiological, but also to pathological phenotypes of T cell development. Identification of numerous activating mutations within the NOTCH1 receptor in human T cell acute lymphoblastic leukaemia (T-ALL) patient samples demonstrated that aberrant activation of this signalling pathway is a frequent event in T-ALL. Active Notch signalling leads to the expression of a plethora of genes that might be drivers or passengers in tumorigenesis including Hes1, which encodes a transcriptional repressor. We have therefore studied Hes1 in the context of T-ALL in mouse models that mimic human disease and in human T-ALL cell lines with the aim to evaluate whether Hes1 affects disease development and disease maintenance and to characterize its function on a molecular level. The first part of this study is dedicated to the functional characterisation of Hes1 in vivo in T-ALL mouse models and in vitro in human T-ALL cell lines. Using a retroviral bone marrow transplant model of T-ALL in which progenitor cells are transduced with a retrovirus expressing constitutive active Notch1 intracellular domain (NICD) we could show that Hes1 is not required in established, late stage T-ALL cells, but that it promotes tumour progression in the early stages of the disease. We have also investigated the function of HES1 in human T-ALL and can show that the overexpression of dominant negative versions of Hes1 in two patient derived cell lines (T-ALL1, CUTLL-1) does not affect proliferation or apoptosis, emphasising that HES1 does not affect cell viability once cells are fully transformed to the leukemic state. In the second part of the study we set out to systematically delineate the gene regulatory networks down-stream of Hes1 by combining RNA-seq and ChIP-seq analysis. Comparing the gene expression of murine premalignant, early stage NICD induced CD4+CD8+ DP cells in the presence and absence of Hes1 by RNA-seq, we unexpectedly found a predominant upregulation of genes in cells expressing Hes1 indicating that Hes1 might rather act as a positive regulator of transcription than as a transcriptional repressor of distinct target genes. Hes1 might influence transcription through secondary or indirect effects as combinatorial analysis of RNA-seq and ChIP-seq led to the identification of only a small number of potential direct target genes that are transcriptionally regulated by Hes1. In summary, the role of Hes1 in promoting the early stages of the disease appears to be highly complex and is likely to involve both direct and indirect control of gene regulatory networks.

EPFL2014

Chargement

Over the past decade, methods to culture stem cells in three dimensions have opened up a plethora of new opportunities for basic and translational research in the life sciences. In particular, the use of natural extracellular matrix (ECM) surrogates, such as mouse tumour-derived Matrigel, unleashed the possibility to recapitulate complex multicellular behaviours in vitro, culminating in the successful derivation of miniaturized organs, termed organoids. While organoids hold tremendous potential as model systems in basic biology, the translational potential of these systems is hampered by their strict dependency on animal-derived matrices that suffer from batch-to-batch variability, potential immunogenicity, and ethical concerns. Recent efforts in engineering covalently crosslinked synthetic hydrogels have attempted to substitute these ill-defined organoid culture systems. However, although these bio-artificial matrices have shown significant potential for 3D organoid culture, their stability and their inherent elastic nature hamper organoid development. Indeed, the native ECM, just like Matrigel, is a highly viscoelastic and dynamic 3D milieu that can relax in response to tissue-induced stress by breaking and subsequently rearranging its network, thus permitting cellular remodelling without compromising the macroscopic stability of the material over time. Therefore, there is a need to develop the next generation of synthetic organoid culture matrices, exhibiting in vivo-like stress-relaxation properties. This thesis provides a perspective on how chemically defined, bio-inspired hydrogels can be designed as potential replacements for native ECM-based matrices for 3D organoid culture. In contrast to traditional synthetic hydrogels that cannot accommodate the dynamic mechanical changes occurring during organoid development, four types of synthetic matrices were developed that are crosslinked, either fully or partially, through dynamic physical bonds. The introduction of such network dynamics is shown to facilitate key morphogenetic processes, such as tissue budding, that are normally absent in purely elastic networks. A unifying hypothesis emerging from these results is that stress relaxation is a crucial requirement for 3D organoid culture. The mechanisms by which stress relaxation influence ISC fate and organoid development remain to be further studied. Preliminary experiments indicated that the stem cells may sense and respond to these characteristics through differential activation of mechanosensing pathways including the transcriptional co-activator YAP. The dynamic hydrogels developed in this thesis hold great promise as tunable environments for stem cell-based self-organization, enabling morphogenetic processes that may be suppressed in conventional synthetic hydrogels systems predominantly used in 3D cell culture applications.

EPFL2019

Chargement

Modeling hematopoietic stem cell dynamics in bioengineered niches

Sonja Giger

Bone marrow transplantation is a well-established medical procedure for the treatment of various hematologic diseases. However, the relatively low number of hematopoietic stem cells (HSCs) that can be harvested, especially from umbilical cord blood, limits even broader applicability of the procedure. A better understanding of the biology of HSCs, and in particular how these rare cells are regulated by microenvironmental niches in the bone marrow, could ultimately enable robust in vitro expansion of HSCs. In this thesis, several novel strategies were developed to study and manipulate HSC biology in vitro, through the regulation of key niche factors, cellular metabolism, and the complex multicellular crosstalk in a niche-mimicking context. First, we made use of gastruloids, an embryonic stem cell-based model of early mouse development, to mimic key aspects of embryonic hematopoiesis in vitro. Simultaneously with the establishment of a vascular network, we detected by immunophenotyping the emergence of primitive blood progenitor cells during the late developmental stages of gastruloids. These embryonic blood progenitors were spatially localized close to a vascular-like plexus in the anterior portion of the gastruloid. Colony-forming assays demonstrated an interesting differentiation potential of these cells. These data demonstrate the potential of gastruloids as an easily accessible in vitro model to study blood development in an embryo-like context. Second, a bioengineering approach was used to study HSC fate choices upon exposure to niche-specific ligands in a well-defined artificial environment. A combination of time-lapse microscopy and single-cell multigene expression analysis was used to define differentiation and cell-cycle states of mouse and human HSCs. Strikingly, selected artificial niches reduced proliferation and maintained the long-term multilineage potential of HSCs in vitro. These artificial niches hold significant potential for the study of mechanisms involved in HSC fate regulation. Third, the influence of the metabolism on fate choices of adult HSCs was studied, specifically focusing on fatty acid Î²-oxidation. Malonyl-CoA was used to reversibly block fatty acid Î²-oxidation in mouse HSCs. In vitro treatment of HSCs with malonyl-CoA promoted their expansion and increased lymphoid reconstitution upon in vivo transplantation. This study sheds new light on the role of the metabolic environment in HSC regulation. Surprisingly, exposure to only a single, readily available metabolite was found to be sufficient to strongly influence HSC behavior. Fourth, a miniaturized multicellular culture system was developed to mimic the hallmarks of the dynamics of HSCs in their native bone marrow. Primary human mesenchymal stem/progenitor cells and endothelial cells were aggregated in a high-throughput manner in biomimetic hydrogel microwells to form self-organizing bone marrow organoids. Immunostaining demonstrated the formation of branched vascular networks, rendering the organoids permissive for the homing of human hematopoietic stem and progenitor cells. These results suggest that bone marrow organoids may be a suitable platform for the modeling of physiological and clinically-relevant stem cell dynamics in vitro. Altogether, this thesis presents several innovative approaches for modeling key features of native stem cell microenvironments that will contribute to a better understanding of the biology of HSCs and their regulatory niche.

EPFL2019

Chargement

Assessing the role of Hes1 and identification of target genes in human and murine T-ALL

Silvia Wirth

EPFL2014

Modeling hematopoietic stem cell dynamics in bioengineered niches

Sonja Giger

EPFL2019