Book contents
- Frontmatter
- Contents
- List of contributors
- 1 An introduction to systems genetics
- 2 Computational paradigms for analyzing genetic interaction networks
- 3 Mapping genetic interactions across many phenotypes in metazoan cells
- 4 Genetic interactions and network reliability
- 5 Synthetic lethality and chemoresistance in cancer
- 6 Joining the dots: network analysis of gene perturbation data
- 7 High-content screening in infectious diseases: new drugs against bugs
- 8 Inferring genetic architecture from systems genetics studies
- 9 Bayesian inference for model selection: an application to aberrant signalling pathways in chronic myeloid leukaemia
- 10 Dynamic network models of protein complexes
- 11 Phenotype state spaces and strategies for exploring them
- 12 Automated behavioural fingerprinting of Caenorhabditis elegans mutants
- Index
- Plate Section
- References
9 - Bayesian inference for model selection: an application to aberrant signalling pathways in chronic myeloid leukaemia
Published online by Cambridge University Press: 05 July 2015
- Frontmatter
- Contents
- List of contributors
- 1 An introduction to systems genetics
- 2 Computational paradigms for analyzing genetic interaction networks
- 3 Mapping genetic interactions across many phenotypes in metazoan cells
- 4 Genetic interactions and network reliability
- 5 Synthetic lethality and chemoresistance in cancer
- 6 Joining the dots: network analysis of gene perturbation data
- 7 High-content screening in infectious diseases: new drugs against bugs
- 8 Inferring genetic architecture from systems genetics studies
- 9 Bayesian inference for model selection: an application to aberrant signalling pathways in chronic myeloid leukaemia
- 10 Dynamic network models of protein complexes
- 11 Phenotype state spaces and strategies for exploring them
- 12 Automated behavioural fingerprinting of Caenorhabditis elegans mutants
- Index
- Plate Section
- References
Summary
In the analysis of any data using statistical modelling, it is imperative that the choice of model is informed by expert knowledge and that its adequacy is determined based on the extent to which it captures and describes the patterns observed in the data. This is especially true in systems where a subset of the constituent components may not be known or cannot be observed. In this chapter, we demonstrate how statistical inference can be used to inform model selection and, by identifying where existing models are unable to sufficiently capture observed behaviour, that statistical inference can help indicate which model refinements may be required.
In this chapter, we use Bayesian statistical methodology – specifically, Riemannian manifold population MCMC – to model interactions between molecular species in the JAK/STAT pathway in chronic myeloid leukaemia (CML) and compare two candidate models. We set out the biological context for this inference in Sections 9.1–9.1.4 and describe the two candidate models in Section 9.3. With the biology established, we describe our statistical methodology (Section 9.4) which we successfully apply in a simulation study to provide a proof of concept (Section 9.5), before we consider a subsequent, more biologically realistic dataset (Section 9.6) to assess which model best describes the behaviour observed in vitro. We relate the findings from this second synthetic study back to our model and dataset construction, thereby highlighting what further in vitro and in silico work is required (Section 9.7).
The oncology of chronic myeloid leukaemia
The condition that we now recognise as chronic myeloid leukaemia (CML) was first described in 1845, in quick succession, by two pathologists, Dr John Hughes Bennett (Bennett 1845) and Dr Rudolf Virchow (Virchow 1845).
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- Chapter
- Information
- Systems GeneticsLinking Genotypes and Phenotypes, pp. 161 - 190Publisher: Cambridge University PressPrint publication year: 2015