18 research outputs found
Mapping the Follicle-Stimulating Hormone-Induced Signaling Networks
Follicle-stimulating hormone (FSH) is a central regulator of male and female reproductive function. Over the last decade, there has been a growing perception of the complexity associated with FSH-induced cellular signaling. It is now clear that the canonical Gs/cAMP/PKA pathway is not the sole mechanism that must be considered in FSH biological actions. In parallel, consistent with the emerging concept of biased agonism, several examples of ligand-mediated selective signaling pathway activation by gonadotropin receptors have been reported. In this context, it is important to gain an integrative view of the signaling pathways induced by FSH and how they interconnect to form a network. In this review, we propose a first attempt at building topological maps of various pathways known to be involved in the FSH-induced signaling network. We discuss the multiple facets of FSH-induced signaling and how they converge to the hormone integrated biological response. Despite of their incompleteness, these maps of the FSH-induced signaling network represent a first step toward gaining a system-level comprehension of this hormoneâs actions, which may ultimately facilitate the discovery of novel regulatory processes and therapeutic strategies for infertility and non-steroidal contraception
Towards a logic-based method to infer provenance-aware molecular networks
International audienceProviding techniques to automatically infer molecular networks is particularly important to understand complex relationships between biological objects. We present a logic-based method to infer such networks and show how it allows inferring signalling networks from the design of a knowledge base. Provenance of inferred data has been carefully collected, allowing quality evaluation. More precisely, our method (i) takes into account various kinds of biological experiments and their origin; (ii) mimics the scientist's reasoning within a first-order logic setting; (iii) specifies precisely the kind of interaction between the molecules; (iv) provides the user with the provenance of each interaction; (v) automatically builds and draws the inferred network
Towards a logic-based method to infer provenance-aware molecular networks
International audienceProviding techniques to automatically infer molecular networks is particularly important to understand complex relationships between biological objects. We present a logic-based method to infer such networks and show how it allows inferring signalling networks from the design of a knowledge base. Provenance of inferred data has been carefully collected, allowing quality evaluation. More precisely, our method (i) takes into account various kinds of biological experiments and their origin; (ii) mimics the scientist's reasoning within a first-order logic setting; (iii) specifies precisely the kind of interaction between the molecules; (iv) provides the user with the provenance of each interaction; (v) automatically builds and draws the inferred network
Automatical inference of signalling pathway's models from experimental
Les rĂ©seaux biologiques, notamment les rĂ©seaux de signalisation dĂ©clenchĂ©s par les hormones, sont extrĂȘmement complexes. Les mĂ©thodes expĂ©rimentales Ă haut dĂ©bit permettent dâaborder cette complexitĂ©, mais la prise en compte de lâensemble des donnĂ©es gĂ©nĂ©rĂ©es requiert la mise au point de mĂ©thodes automatiques pour la construction des rĂ©seaux. Nous avons dĂ©veloppĂ© une nouvelle mĂ©thode dâinfĂ©rence reposant sur la formalisation, sous forme de rĂšgles logiques, du raisonnement de lâexpert sur les donnĂ©es expĂ©rimentales. Cela nĂ©cessite la constitution dâune base de connaissances, ensuite exploitĂ©e par un moteur dâinfĂ©rence afin de dĂ©duire les conclusions permettant de construire les rĂ©seaux. Notre mĂ©thode a Ă©tĂ© Ă©laborĂ©e grĂące au rĂ©seau de signalisation induit par lâhormone folliculo-stimulante dont le rĂ©cepteur fait partie de la grande famille des rĂ©cepteurs couplĂ©s aux protĂ©ines G. Ce rĂ©seau a Ă©galement Ă©tĂ© construit manuellement pour Ă©valuer notre mĂ©thode. Un contrĂŽle a ensuite Ă©tĂ© rĂ©alisĂ© sur rĂ©seau induit par le facteur de croissance Ă©pidermique, se liant Ă un rĂ©cepteur tyrosine kinase, de façon Ă montrer que notre mĂ©thode est capable de dĂ©duire diffĂ©rents types de rĂ©seaux de signalisation.Biological networks, including signalling networks induced by hormones, are very complex. High-throughput experimental methods permit to approach this complexity, but to be able to use all generated data, it is necessary to create automatical inference methods to build networks. We have developped a new inference method based on the formalization of the expertâs reasoning on experimental data. This reasoning is converted into logical rules. This work requires the creation of a knowledge base which is used by an inference engine to deduce conclusions to build networks. Our method has been elaborated by the construction of the signalling network induced by the follicle stimulating hormone whose receptor belongs to the G protein-coupled receptors family. This network has also been built manually to assess our method. Then, a test has been done on the network induced by the epidermal growth factor, which binds to a tyrosine kinase receptor, to demonstrate the ability of our method to deduce differents types of signaling networks
Automatical inference of signalling pathway's models from experimental
Les rĂ©seaux biologiques, notamment les rĂ©seaux de signalisation dĂ©clenchĂ©s par les hormones, sont extrĂȘmement complexes. Les mĂ©thodes expĂ©rimentales Ă haut dĂ©bit permettent dâaborder cette complexitĂ©, mais la prise en compte de lâensemble des donnĂ©es gĂ©nĂ©rĂ©es requiert la mise au point de mĂ©thodes automatiques pour la construction des rĂ©seaux. Nous avons dĂ©veloppĂ© une nouvelle mĂ©thode dâinfĂ©rence reposant sur la formalisation, sous forme de rĂšgles logiques, du raisonnement de lâexpert sur les donnĂ©es expĂ©rimentales. Cela nĂ©cessite la constitution dâune base de connaissances, ensuite exploitĂ©e par un moteur dâinfĂ©rence afin de dĂ©duire les conclusions permettant de construire les rĂ©seaux. Notre mĂ©thode a Ă©tĂ© Ă©laborĂ©e grĂące au rĂ©seau de signalisation induit par lâhormone folliculo-stimulante dont le rĂ©cepteur fait partie de la grande famille des rĂ©cepteurs couplĂ©s aux protĂ©ines G. Ce rĂ©seau a Ă©galement Ă©tĂ© construit manuellement pour Ă©valuer notre mĂ©thode. Un contrĂŽle a ensuite Ă©tĂ© rĂ©alisĂ© sur rĂ©seau induit par le facteur de croissance Ă©pidermique, se liant Ă un rĂ©cepteur tyrosine kinase, de façon Ă montrer que notre mĂ©thode est capable de dĂ©duire diffĂ©rents types de rĂ©seaux de signalisation.Biological networks, including signalling networks induced by hormones, are very complex. High-throughput experimental methods permit to approach this complexity, but to be able to use all generated data, it is necessary to create automatical inference methods to build networks. We have developped a new inference method based on the formalization of the expertâs reasoning on experimental data. This reasoning is converted into logical rules. This work requires the creation of a knowledge base which is used by an inference engine to deduce conclusions to build networks. Our method has been elaborated by the construction of the signalling network induced by the follicle stimulating hormone whose receptor belongs to the G protein-coupled receptors family. This network has also been built manually to assess our method. Then, a test has been done on the network induced by the epidermal growth factor, which binds to a tyrosine kinase receptor, to demonstrate the ability of our method to deduce differents types of signaling networks
ChloroKB, a cell metabolism reconstruction of the model plant Arabidopsis thaliana
International audienceCan we understand how plant cell metabolism really works? An integrated large-scale modelling of plant metabolism predictive model would make possible to analyse the impact of disturbances in environmental conditions on cellular functioning and diversity of plant-made molecules of interest. ChloroKB, a Web application initially developed for exploration of Arabidopsis chloroplast metabolic network now covers Arabidopsis mesophyll cell metabolism. Interconnected metabolic maps show subcellular compartments, metabolites, proteins, complexes, reactions, and transport. Data in ChloroKB have been structured to allow for mathematical modelling and will be used as a reference for modelling work dedicated to a particular issue.Peut-on comprendre comment fonctionne rĂ©ellement le mĂ©tabolisme des cellules vĂ©gĂ©tales ? Un modĂšle prĂ©dictif intĂ©grĂ© Ă grande Ă©chelle du mĂ©tabolisme des plantes permettrait dâanalyser lâimpact des perturbations des conditions environnementales sur le fonctionnement cellulaire et la diversitĂ© des molĂ©cules dâintĂ©rĂȘt fabriquĂ©es par les plantes. ChloroKB, une application Web initialement dĂ©veloppĂ©e pour lâexploration du rĂ©seau mĂ©tabolique du chloroplaste dâArabidopsis, couvre dĂ©sormais le mĂ©tabolisme des cellules du mĂ©sophylle dâArabidopsis. Des cartes mĂ©taboliques interconnectĂ©es dĂ©crivent les compartiments subcellulaires, les mĂ©tabolites, les protĂ©ines, les complexes, les rĂ©actions et le transport. Les donnĂ©es de ChloroKB ont Ă©tĂ© structurĂ©es pour permettre la modĂ©lisation mathĂ©matique et seront utilisĂ©es comme rĂ©fĂ©rence pour les travaux de modĂ©lisation consacrĂ©s Ă une question particuliĂšre
A logic-based method to build signaling networks and propose experimental plans
With the dramatic increase of the diversity and the sheer quantity of biological data generated, the construction of comprehensive signaling networks that include precise mechanisms cannot be carried out manually anymore. In this context, we propose a logic-based method that allows building large signaling networks automatically. Our method is based on a set of expert rules that make explicit the reasoning made by biologists when interpreting experimental results coming from a wide variety of experiment types. These rules allow formulating all the conclusions that can be inferred from a set of experimental results, and thus building all the possible networks that explain these results. Moreover, given an hypothesis, our system proposes experimental plans to carry out in order to validate or invalidate it. To evaluate the performance of our method, we applied our framework to the reconstruction of the FSHR-induced and the EGFR-induced signaling networks. The FSHR is known to induce the transactivation of the EGFR, but very little is known on the resulting FSH- and EGF-dependent network. We built a single network using data underlying both networks. This leads to a new hypothesis on the activation of MEK by p38MAPK, which we validate experimentally. These preliminary results represent a first step in the demonstration of a cross-talk between these two major MAP kinases pathways