186 research outputs found
Blueprint: descrição da complexidade da regulação metabólica através da reconstrução de modelos metabólicos e regulatórios integrados
Tese de doutoramento em Biomedical EngineeringUm modelo metabólico consegue prever o fenótipo de um organismo. No entanto, estes modelos
podem obter previsões incorretas, pois alguns processos metabólicos são controlados por mecanismos
reguladores. Assim, várias metodologias foram desenvolvidas para melhorar os modelos metabólicos
através da integração de redes regulatórias. Todavia, a reconstrução de modelos regulatórios e metabólicos à escala genómica para diversos organismos apresenta diversos desafios.
Neste trabalho, propõe-se o desenvolvimento de diversas ferramentas para a reconstrução e análise
de modelos metabólicos e regulatórios à escala genómica. Em primeiro lugar, descreve-se o Biological
networks constraint-based In Silico Optimization (BioISO), uma nova ferramenta para auxiliar a curação
manual de modelos metabólicos. O BioISO usa um algoritmo de relação recursiva para orientar as previsões de fenótipo. Assim, esta ferramenta pode reduzir o número de artefatos em modelos metabólicos,
diminuindo a possibilidade de obter erros durante a fase de curação.
Na segunda parte deste trabalho, desenvolveu-se um repositório de redes regulatórias para procariontes que permite suportar a sua integração em modelos metabólicos. O Prokaryotic Transcriptional
Regulatory Network Database (ProTReND) inclui diversas ferramentas para extrair e processar informação regulatória de recursos externos. Esta ferramenta contém um sistema de integração de dados que
converte dados dispersos de regulação em redes regulatórias integradas. Além disso, o ProTReND dispõe
de uma aplicação que permite o acesso total aos dados regulatórios.
Finalmente, desenvolveu-se uma ferramenta computacional no MEWpy para simular e analisar modelos regulatórios e metabólicos. Esta ferramenta permite ler um modelo metabólico e/ou rede regulatória,
em diversos formatos. Esta estrutura consegue construir um modelo regulatório e metabólico integrado
usando as interações regulatórias e as ligações entre genes e proteínas codificadas no modelo metabólico e na rede regulatória. Além disso, esta estrutura suporta vários métodos de previsão de fenótipo
implementados especificamente para a análise de modelos regulatórios-metabólicos.Genome-Scale Metabolic (GEM) models can predict the phenotypic behavior of organisms. However,
these models can lead to incorrect predictions, as certain metabolic processes are controlled by regulatory
mechanisms. Accordingly, many methodologies have been developed to extend the reconstruction and
analysis of GEM models via the integration of Transcriptional Regulatory Network (TRN)s. Nevertheless,
the perspective of reconstructing integrated genome-scale regulatory and metabolic models for diverse
prokaryotes is still an open challenge.
In this work, we propose several tools to assist the reconstruction and analysis of regulatory and
metabolic models. We start by describing BioISO, a novel tool to assist the manual curation of GEM
models. BioISO uses a recursive relation-like algorithm and Flux Balance Analysis (FBA) to evaluate and
guide debugging of in silico phenotype predictions. Hence, this tool can reduce the number of artifacts in
GEM models, decreasing the burdens of model refinement and curation.
A state-of-the-art repository of TRNs for prokaryotes was implemented to support the reconstruction
and integration of TRNs into GEM models. The ProTReND repository comprehends several tools to extract
and process regulatory information available in several resources. More importantly, this repository contains a data integration system to unify the regulatory data into standardized TRNs at the genome scale.
In addition, ProTReND contains a web application with full access to the regulatory data.
Finally, we have developed a new modeling framework to define, simulate and analyze GEnome-scale
Regulatory and Metabolic (GERM) models in MEWpy. The GERM model framework can read a GEM
model, as well as a TRN from different file formats. This framework assembles a GERM model using
the regulatory interactions and Genes-Proteins-Reactions (GPR) rules encoded into the GEM model and
TRN. In addition, this modeling framework supports several methods of phenotype prediction designed
for regulatory-metabolic models.I would like to thank Fundação para a Ciência e Tecnologia for the Ph.D. studentship I was awarded
with (SFRH/BD/139198/2018)
PSAMM: A Portable System for the Analysis of Metabolic Models
The genome-scale models of metabolic networks have been broadly applied in phenotype prediction, evolutionary reconstruction, community functional analysis, and metabolic engineering. Despite the development of tools that support individual steps along the modeling procedure, it is still difficult to associate mathematical simulation results with the annotation and biological interpretation of metabolic models. In order to solve this problem, here we developed a Portable System for the Analysis of Metabolic Models (PSAMM), a new open-source software package that supports the integration of heterogeneous metadata in model annotations and provides a user-friendly interface for the analysis of metabolic models. PSAMM is independent of paid software environments like MATLAB, and all its dependencies are freely available for academic users. Compared to existing tools, PSAMM significantly reduced the running time of constraint-based analysis and enabled flexible settings of simulation parameters using simple one-line commands. The integration of heterogeneous, model-specific annotation information in PSAMM is achieved with a novel format of YAML-based model representation, which has several advantages, such as providing a modular organization of model components and simulation settings, enabling model version tracking, and permitting the integration of multiple simulation problems. PSAMM also includes a number of quality checking procedures to examine stoichiometric balance and to identify blocked reactions. Applying PSAMM to 57 models collected from current literature, we demonstrated how the software can be used for managing and simulating metabolic models. We identified a number of common inconsistencies in existing models and constructed an updated model repository to document the resolution of these inconsistencies
Modeling human gut microbiota: from steady states to dynamic systems
Human gut microbes are an essential part of human sub-microscopic systems and involved in many critical biological processes such as Type 2 diabetes (T2D) and osteoporosis. However, the underlying mechanisms are unclear. Several mathematical modeling approaches, such as genome-scale metabolic models (GEMs) and ordinary differential equation (ODE) based models, have been used to simulate the dynamics of human gut microbiota. This thesis aims to explore, simulate, and predict the behavior of gut microbial ecosystems and the relationships between gut microbes and humans by modeling.The importance of the gut microbiome for bone metabolism and T2D has been demonstrated in mice and human cohorts. We first reconstructed a GEM for Limosilactobacillus reuteri ATCC PTA 6475, which is a probiotic that significantly reduces bone loss in older women with lower bone mineral density. To investigate the associations between T2D and the gut microbiota, GEMs for 827 gut microbial species and 1,779 community-level GEMs for T2D cohorts have also been constructed. With these GEMs, we investigated metabolic potentials such as short-chain fatty acids, amino acids, and vitamins that play vital roles in the host metabolism regulation. Furthermore, the integration of the models with machine learning method provides potential insights into the possible roles of gut microbiota in T2D.Cybernetic models, which simulate metabolic rates by integrating the control of enzyme synthesis and enzyme activities, have been applied to explore the dynamic behaviors of small-size metabolic networks. However, only a few studies have applied cybernetic theory to the microbial community so far. The remaining part of this thesis focuses on the use of cybernetic models to explore human gut microbiota\u27s interactions and population dynamics. Considering the high computing burden of the current cybernetic modeling approach for processing the full-size GEMs, we have developed a computing-efficient strategy for model reconstruction and simulation to reveal the metabolic dynamics of human gut microbiota.In this thesis, we explore the human gut microbiota from single L. reuteri species to microbial gut communities, from simple steady state systems by GEMs to complex dynamic systems by cybernetic model
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