2,428 research outputs found
Quantifying cancer epithelial-mesenchymal plasticity and its association with stemness and immune response
Cancer cells can acquire a spectrum of stable hybrid epithelial/mesenchymal
(E/M) states during epithelial-mesenchymal transition (EMT). Cells in these
hybrid E/M phenotypes often combine epithelial and mesenchymal features and
tend to migrate collectively commonly as small clusters. Such collectively
migrating cancer cells play a pivotal role in seeding metastases and their
presence in cancer patients indicates an adverse prognostic factor. Moreover,
cancer cells in hybrid E/M phenotypes tend to be more associated with stemness
which endows them with tumor-initiation ability and therapy resistance. Most
recently, cells undergoing EMT have been shown to promote immune suppression
for better survival. A systematic understanding of the emergence of hybrid E/M
phenotypes and the connection of EMT with stemness and immune suppression would
contribute to more effective therapeutic strategies. In this review, we first
discuss recent efforts combining theoretical and experimental approaches to
elucidate mechanisms underlying EMT multi-stability (i.e. the existence of
multiple stable phenotypes during EMT) and the properties of hybrid E/M
phenotypes. Following we discuss non-cell-autonomous regulation of EMT by cell
cooperation and extracellular matrix. Afterwards, we discuss various metrics
that can be used to quantify EMT spectrum. We further describe possible
mechanisms underlying the formation of clusters of circulating tumor cells.
Last but not least, we summarize recent systems biology analysis of the role of
EMT in the acquisition of stemness and immune suppression.Comment: 50 pages, 6 figure
The in silico macrophage: toward a better understanding of inflammatory disease
Macrophages function as sentinel, cell-regulatory hubs capable of initiating,
perpetuating and contributing to the resolution of an inflammatory response,
following their activation from a resting state. Highly complex and varied gene
expression programs within the macrophage enable such functional diversity. To
investigate how programs of gene expression relate to the phenotypic attributes
of the macrophage, the development of in silico modeling methods is needed.
Such models need to cover multiple scales, from molecular pathways in
cell-autonomous immunity and intercellular communication pathways in tissue
inflammation to whole organism response pathways in systemic disease. Here, we
highlight the potential of in silico macrophage modeling as an amenable and
important yet under-exploited tool in aiding in our understanding of the immune
inflammatory response. We also discuss how in silico macrophage modeling can
help in future therapeutic strategies for modulating both the acute protective
effects of inflammation (such as host defense and tissue repair) and the
harmful chronic effects (such as autoimmune diseases).Comment: 7 pages plus 1 figur
Kinetic modelling of competition and depletion of shared miRNAs by competing endogenous RNAs
Non-conding RNAs play a key role in the post-transcriptional regulation of
mRNA translation and turnover in eukaryotes. miRNAs, in particular, interact
with their target RNAs through protein-mediated, sequence-specific binding,
giving rise to extended and highly heterogeneous miRNA-RNA interaction
networks. Within such networks, competition to bind miRNAs can generate an
effective positive coupling between their targets. Competing endogenous RNAs
(ceRNAs) can in turn regulate each other through miRNA-mediated crosstalk.
Albeit potentially weak, ceRNA interactions can occur both dynamically,
affecting e.g. the regulatory clock, and at stationarity, in which case ceRNA
networks as a whole can be implicated in the composition of the cell's
proteome. Many features of ceRNA interactions, including the conditions under
which they become significant, can be unraveled by mathematical and in silico
models. We review the understanding of the ceRNA effect obtained within such
frameworks, focusing on the methods employed to quantify it, its role in the
processing of gene expression noise, and how network topology can determine its
reach.Comment: review article, 29 pages, 7 figure
Advocating the need of a systems biology approach for personalised prognosis and treatment of B-CLL patients
The clinical course of B-CLL is heterogeneous. This heterogeneity leads to a clinical dilemma: can we identify those patients who will benefit from early treatment and predict the survival? In recent years, mathematical modelling has contributed significantly in understanding the complexity of diseases. In order to build a mathematical model for determining prognosis of B-CLL one has to identify, characterise and quantify key molecules involved in the disease. Here we discuss the need and role of mathematical modelling in predicting B-CLL disease pathogenesis and suggest a new systems biology approach for a personalised therapy of B-CLL patients
Modeling cancer metabolism on a genome scale
Cancer cells have fundamentally altered cellular metabolism that is associated with their tumorigenicity and malignancy. In addition to the widely studied Warburg effect, several new key metabolic alterations in cancer have been established over the last decade, leading to the recognition that altered tumor metabolism is one of the hallmarks of cancer. Deciphering the full scope and functional implications of the dysregulated metabolism in cancer requires both the advancement of a variety of omics measurements and the advancement of computational approaches for the analysis and contextualization of the accumulated data. Encouragingly, while the metabolic network is highly interconnected and complex, it is at the same time probably the best characterized cellular network. Following, this review discusses the challenges that genome‐scale modeling of cancer metabolism has been facing. We survey several recent studies demonstrating the first strides that have been done, testifying to the value of this approach in portraying a network‐level view of the cancer metabolism and in identifying novel drug targets and biomarkers. Finally, we outline a few new steps that may further advance this field
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A MicroRNA Based Genetic Clock
This thesis focuses on the design, construction and stable integration in mammalian cells of a natural microRNA-based genetic oscillator. This will help both in better understanding the rules underlying the periodic expression of genes observed in major biological processes, such as the circadian clock and cell-cycle, as well as, in generating new tools to probe and investigate the function of a gene in a cell, by allowing not only its over-expression or knock-down, but also its cyclic expression. The circuit involves a positive feedback loop, consisting of a transcription factor (TF) activating itself, and a negative feedback loop, using a natural micro RNA controlled by the TF, which induces degradation of the TF itself. The circuit was built in a modular way, and implemented it in two lentiviral vectors able to infect both dividing and non-dividing cells, hence suitable for many different applications. Since obtaining stable oscillations is non-trivial, a modified version of the oscillator was engineered, including an intermediate step between the TF and the microRNA, to increase the delay in the negative feedback loop. The oscillatory behavior was tested via in vivo time-lapse fluorescence microscopy in both versions of the oscillator, since both the TF(s) and the microRNA are expressed together with fluorescent reporters.EThOS - Electronic Theses Online ServiceGBUnited Kingdo
Current advances in systems and integrative biology
Systems biology has gained a tremendous amount of interest in the last few years. This is partly due to the realization that traditional approaches focusing only on a few molecules at a time cannot describe the impact of aberrant or modulated molecular environments across a whole system. Furthermore, a hypothesis-driven study aims to prove or disprove its postulations, whereas a hypothesis-free systems approach can yield an unbiased and novel testable hypothesis as an end-result. This latter approach foregoes assumptions which predict how a biological system should react to an altered microenvironment within a cellular context, across a tissue or impacting on distant organs. Additionally, re-use of existing data by systematic data mining and re-stratification, one of the cornerstones of integrative systems biology, is also gaining attention. While tremendous efforts using a systems methodology have already yielded excellent results, it is apparent that a lack of suitable analytic tools and purpose-built databases poses a major bottleneck in applying a systematic workflow. This review addresses the current approaches used in systems analysis and obstacles often encountered in large-scale data analysis and integration which tend to go unnoticed, but have a direct impact on the final outcome of a systems approach. Its wide applicability, ranging from basic research, disease descriptors, pharmacological studies, to personalized medicine, makes this emerging approach well suited to address biological and medical questions where conventional methods are not ideal
Modeling and Analysis of Signal Transduction Networks
Biological pathways, such as signaling networks, are a key component of biological systems of each living cell. In fact, malfunctions of signaling pathways are linked to a number of diseases, and components of signaling pathways are used as potential drug targets. Elucidating the dynamic behavior of the components of pathways, and their interactions, is one of the key research areas of systems biology. Biological signaling networks are characterized by a large number of components and an even larger number of parameters describing the network. Furthermore, investigations of signaling networks are characterized by large uncertainties of the network as well as limited availability of data due to expensive and time-consuming experiments. As such, techniques derived from systems analysis, e.g., sensitivity analysis, experimental design, and parameter estimation, are important tools for elucidating the mechanisms involved in signaling networks. This Special Issue contains papers that investigate a variety of different signaling networks via established, as well as newly developed modeling and analysis techniques
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