2,239 research outputs found
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The role of HG in the analysis of temporal iteration and interaural correlation
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Mapping the transcriptional landscape of haematopoietic stem and progenitor cells
Maintenance of the blood system requires balanced cell-fate decisions of haematopoietic stem and progenitor cells (HSPCs). Individual haematopoietic stem cells (HSCs) decide between self-renewal and differentiation and can generate all mature cell types. Cell-fate decisions are made at the single-cell level and are governed by regulatory networks. Dysregulation in this balanced process could lead to serious blood disorders such as leukaemia; therefore, it is important to understand how individual cells make these cell-fate decisions.
To investigate HSPC populations, 1,654 cells were profiled by single-cell RNA-sequencing. Index sorting made it possible to sort HSPCs using broad sorting gates and retrospectively assign them to common HSPC populations, retaining all information about specific functionally pure populations while also capturing any intermediate cells normally excluded by conventional gating. Reconstruction of differentiation trajectories revealed dynamic expression changes associated with early lineage differentiation from HSCs. This transcriptional atlas of HSPC differentiation was further used to identify candidate genes for a CRISPR screen investigating genes implicated in HSC biology. These candidate gene perturbations were interrogated for changes in the expression of the HSC marker EPCR, as well as changes in apoptosis and lineage output.
Transcription factors play a key role in regulating cell-fate decisions and operate within organized regulatory programs. To study relationships between transcription factors in HSPC populations, qRT-PCR was used to profile the expression of 41 genes, including 31 transcription factors, in HSPCs at the single-cell level. This approach confirmed known aspects of haematopoiesis and made deeper investigation of HSPC heterogeneity possible. Regulatory networks were reconstructed using Boolean network inference models and recapitulated differentiation of HSCs towards megakaryocyte–erythrocyte progenitors and lymphoid-primed multipotent progenitors. By comparing these two models, a rule specific to the megakaryocyte-erythrocyte progenitor network was identified, in which GATA2 positively regulated Nfe2 and Cbfa2t3h. This was subsequently validated using transcription factor binding profiles and in vitro luciferase assays using a model cell line.
Overall, the work presented in this thesis confirmed known aspects of HSPC biology using single-cell gene expression analysis and demonstrated how in silico approaches can be used to guide in vitro and in vivo investigations. In addition, the single-cell RNA-sequencing data was developed into an intuitive web interface that can be used to visualise the gene expression for any gene of choice at single-cell resolution across the HSPC atlas, providing a powerful resource for the haematopoietic community.My funding for the CIMR 4 year programme was provided by the Medical Research Council (MRC)
Resolving Biological Trajectories in Single-cell Data using Feature Selection and Multi-modal Integration
Single-cell technologies can readily measure the expression of thousands of molecular features from individual cells undergoing dynamic biological processes, such as cellular differentiation, immune response, and disease progression. While computational trajectory inference methods and RNA velocity approaches have been developed to study how subtle changes in gene or protein expression impact cell fate decision-making, identifying characteristic features that drive continuous biological processes remains difficult to detect due to the inherent biological or technical challenges associated with single-cell data. Here, we developed two data representation-based approaches for improving inference of cellular dynamics. First, we present DELVE, an unsupervised feature selection method for identifying a representative subset of dynamically-expressed molecular features that resolve cellular trajectories in noisy data. In contrast to previous work, DELVE uses a bottom-up approach to mitigate the effect of unwanted sources of variation confounding inference and models cell states from dynamic feature modules that constitute core regulatory complexes. Using simulations, single-cell RNA sequencing data, and iterative immunofluorescence imaging data in the context of cell cycle and cellular differentiation, we demonstrate that DELVE selects genes or proteins that more accurately characterize cell populations and improve the recovery of cell type transitions. Next, we present the first task-oriented benchmarking study that investigates integration of temporal gene expression modalities for dynamic cell state prediction. We benchmark ten multi-modal integration approaches on ten datasets spanning different biological contexts, sequencing technologies, and species. This study illustrates how temporal gene expression modalities can be optimally combined to improve inference of cellular trajectories and more accurately predict sample-associated perturbation and disease phenotypes. Lastly, we illustrate an application of these approaches and perform an integrative analysis of gene expression and RNA velocity data to study the crosstalk between signaling pathways that govern the mesendoderm fate decision during directed definitive endoderm differentiation. Results of this study suggest that lineage-specific, temporally expressed genes within the primitive streak may serve as a potential target for increasing definitive endoderm efficiency. Collectively, this work uses scalable data-driven approaches to effectively manage the inherent biological or technical challenges associated with single-cell data in order to improve inference of cellular dynamics.Doctor of Philosoph
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Understanding transcriptional regulation through computational analysis of single-cell transcriptomics
Gene expression is tightly regulated by complex transcriptional regulatory mechanisms to achieve specific expression patterns, which are essential to facilitate important biological processes such as embryonic development. Dysregulation of gene expression can lead to diseases such as cancers. A better understanding of the transcriptional regulation will therefore not only advance the understanding of fundamental biological processes, but also provide mechanistic insights into diseases.
The earlier versions of high-throughput expression profiling techniques were limited to measuring average gene expression across large pools of cells. In contrast, recent technological improvements have made it possible to perform expression profiling in single cells. Single-cell expression profiling is able to capture heterogeneity among single cells, which is not possible in conventional bulk expression profiling.
In my PhD, I focus on developing new algorithms, as well as benchmarking and utilising existing algorithms to study the transcriptomes of various biological systems using single-cell expression data. I have developed two different single-cell specific network inference algorithms, BTR and SPVAR, which are based on two different formalisms, Boolean and autoregression frameworks respectively. BTR was shown to be useful for improving existing Boolean models with single-cell expression data, while SPVAR was shown to be a conservative predictor of gene interactions using pseudotime-ordered single-cell expression data.
In addition, I have obtained novel biological insights by analysing single-cell RNAseq data from the epiblast stem cells reprogramming and the leukaemia systems. Three different driver genes, namely Esrrb, Klf2 and GY118F, were shown to drive reprogramming of epiblast stem cells via different reprogramming routes. As for the leukaemia system, FLT3-ITD and IDH1-R132H mutations were shown to interact with each other and potentially predispose some cells for developing acute myeloid leukaemia.Wellcome Trust and Cambridge Trus
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Deciphering Leukaemogenic Mechanisms through System-Scale Analysis of Single-Cell RNA Sequencing Data
Haematopoietic stem cells are responsible for producing and sustaining the diverse array of cell types present in the adult blood system. This complex process requires the strict regulation of haematopoietic fate decisions and differentiation trajectories in order to maintain a healthy state. Haematological malignancies such as leukaemia are associated with various perturbations that disrupt this regulation and drive aberrant cell fate decisions, leading to disease. Much of this dysregulation is proposed to occur at the transcriptional level, and recent technological advancements in single-cell sequencing have made it possible to study
the transcriptional effects of leukaemic perturbations at the scale of individual haematopoietic stem and progenitor cells. However, the mechanisms through which specific perturbations lead to dysregulation of the blood system remain poorly understood.
The primary aim of this work was to build an integrative computational framework for the analysis and comparison of leukaemic perturbations of the murine blood system as measured by single-cell RNA sequencing. Presented in Chapter 3, this framework aims to dissect the perturbation response across different scales – from individual genes to specific
progenitor cell types to the entire blood system – and allow informative comparisons to be made about the similarities and differences between several perturbations. In total, eight genetic perturbations known to associate with leukaemia were analysed, resulting in novel biological insights concerning the behaviour of coordinated gene modules and the cellular abundance shifts driven by them.
As many leukaemic drivers act directly upon the most immature long-term haematopoietic stem cells, a highly targeted analysis of these cells was performed across the leukaemic perturbations. In Chapter 4 a novel computational pipeline was built to link FACS-sorted cell populations and single-cell transcriptional landscapes. Using this, the cellular and molecular responses of the perturbations were investigated, resulting in several novel hypotheses. For example, the data suggests that many leukaemic perturbations gain a competitive advantage against wild-type cells by pushing their MPP1 cells into more active states. Additionally the
data suggests that increases in the transcriptional variability of blood stem cells is associated with pro-erythroid fate decision shifts and vice-versa.
Many different types of haematopoietic perturbations exist and can drive disease progression in the blood system. Chapter 5 focuses on single-cell RNA sequencing data from three further perturbations in various settings, including an infection model of Malaria and a model susceptible to endogenous DNA damage by aldehydes. These analyses have driven
and validated bodies of experimental work, and comparing them to the previously described perturbation models highlighted both conserved changes and differences in the response of the haematopoietic system across different perturbation settings.
The final project aimed to improve upon current computational methods for cellular trajectory inference from single-cell data. Whilst high-throughput experiments allow for the sequencing of large cell numbers, this is balanced by the sparse and noisy nature of the returned data. Current methods perform poorly on such datasets and either cannot deal with large cell numbers or cannot extract enough relevant signal from sparse count matrices. A new computational tool was designed to work best on these large, sparse datasets, and infer the most likely cellular trajectories through snapshot sequencing data using an iterative process.
In Chapter 6 this algorithm was applied to different systems including adult haematopoiesis, and was compared to state-of-the-art methods.
Overall, this thesis has investigated the transcriptional consequences of numerous preleukaemic perturbations on the haematopoietic stem and progenitor cell compartment at the single-cell level. New methods have been built for integration of single-cell perturbation experiments and their analysis across different biological scales. This has revealed novel
biological insights regarding the mechanisms underpinning leukaemic transformation of the blood system
Asteroseismology and Interferometry
Asteroseismology provides us with a unique opportunity to improve our
understanding of stellar structure and evolution. Recent developments,
including the first systematic studies of solar-like pulsators, have boosted
the impact of this field of research within Astrophysics and have led to a
significant increase in the size of the research community. In the present
paper we start by reviewing the basic observational and theoretical properties
of classical and solar-like pulsators and present results from some of the most
recent and outstanding studies of these stars. We centre our review on those
classes of pulsators for which interferometric studies are expected to provide
a significant input. We discuss current limitations to asteroseismic studies,
including difficulties in mode identification and in the accurate determination
of global parameters of pulsating stars, and, after a brief review of those
aspects of interferometry that are most relevant in this context, anticipate
how interferometric observations may contribute to overcome these limitations.
Moreover, we present results of recent pilot studies of pulsating stars
involving both asteroseismic and interferometric constraints and look into the
future, summarizing ongoing efforts concerning the development of future
instruments and satellite missions which are expected to have an impact in this
field of research.Comment: Version as published in The Astronomy and Astrophysics Review, Volume
14, Issue 3-4, pp. 217-36
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Advancing haematopoietic stem and progenitor cell biology through single-cell profiling.
Haematopoietic stem and progenitor cells (HSPCs) sit at the top of the haematopoietic hierarchy, and their fate choices need to be carefully controlled to ensure balanced production of all mature blood cell types. As cell fate decisions are made at the level of the individual cells, recent technological advances in measuring gene and protein expression in increasingly large numbers of single cells have been rapidly adopted to study both normal and pathological HSPC function. In this review we emphasise the importance of combining the correct computational models with single-cell experimental techniques, and illustrate how such integrated approaches have been used to resolve heterogeneities in populations, reconstruct lineage differentiation, identify regulatory relationships and link molecular profiling to cellular function.Research in the authors' laboratory is supported by Cancer Research UK, the Biotechnology and Biological Sciences Research Council, Bloodwise, the Leukemia and Lymphoma Society, a Wellcome Trust Strategic Award (Tracing Early Mammalian Lineage Decisions by Single Cell Genomics) and core support grants by the Wellcome Trust to the Cambridge Institute for Medical Research and Wellcome Trust – MRC Cambridge Stem Cell Institute. FKH and SN gratefully acknowledge the MRC for funding of their studentships.This is the author accepted manuscript. The final version is available from Wiley via http://dx.doi.org/10.1002/1873-3468.1223
Control Theoretic Analysis of Human Brain Networks
The brain is a complex system with complicated structures and entangled dynamics. Among the various approaches to investigating the brain\u27s mechanics, the graphical method provides a successful framework for understanding the topology of both the
structural and functional networks, and discovering efficient diagnostic biomarkers for cognitive behaviors, brain disorders and diseases. Yet it cannot explain how the structure affects the functionality and how the brain tunes its transition among multiple states to manipulate the cognitive control. In my dissertation, I propose a novel framework of modeling the mechanics of the cognitive control, which involves in applying control theory to analyzing the brain networks and conceptually connecting the cognitive control with the engineering control. First, I examine the energy distribution among different states via combining the energetic and structural constraints of the brain\u27s state transition in a free energy model, where the interaction between regions is explicitly informed by structural connectivity. This work enables the possibility of achieving a whole view of the brain\u27s energy landscape and preliminarily indicates the feasibility of control theory to model the dynamics of cognitive control. In the following work, I exploit the network control theory to address two questions about how the large-scale circuitry of the human brain constrains its dynamics. First, is the human brain theoretically controllable? Second, which areas of the brain are most influential in constraining or facilitating changes in brain state trajectories? Further, I seek to examine the structural effect on the control actions through solving the optimal control problem under different boundary conditions. I quantify the efficiency of regions in terms of the energy cost for the brain state transition from the default mode to task modes. This analysis is extended to the perturbation analysis of trajectories and is applied to the comparison between the group with mild traumatic brain injury(mTBI) and the healthy group. My research is the first to demonstrate how control theory can be used to analyze human brain networks
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