Disease map definition

A disease map can be defined as a comprehensive, knowledge-based representation of disease mechanisms. Essentially, it is a conceptual model of a disease. It contains disease-related signalling, metabolic and gene regulatory processes with evidence of their relationships to pathophysiological causes and outcomes^8–10 (Fig. ​(Fig.2).2). To describe the complexity of a disease it is important to capture not only biochemical interactions but also physiological mechanisms.

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Fig. 2

A fragment of the Parkinson’s disease map. a A disease map repository allows visual multiscale exploration of the contextualised, disease-relevant mechanisms. Here, the contents of the Parkinson’s Disease map can be explored across scales from the neuronal environment to the detailed molecular pathobiology of the disease. Higher scales emerge from the underlying mechanistic descriptions. b Mechanistic details of dopamine metabolism in the dopaminergic neurones are shown. The involvement of Parkinson’s disease familial genes, PARK2 (Parkin), PARK7 (DJ-1) and SNCA (alpha-synuclein) is highlighted. Excessive oxidation of dopamine into dopamine quinone may lead to conformational changes in proteins and subsequently result in molecular neuropathology associated with Parkinson’s, marked as “disease endpoints” in the figure

A disease map is represented graphically and is encoded in a standard computer-readable and human-readable format, allowing its transformation, partially or wholly, into mathematical models for predictive analysis. We specifically distinguish the literature-derived conceptual model of a disease and the different types of mathematical models that can be produced from it. This way we make the core resource updatable and sustainable while enabling the production of various models by adding assumptions, hypothetical mechanisms and model parameters. The proposed new mechanisms are then confirmed or rejected, and the conceptual core model updated accordingly.

Development of disease maps relies on an active involvement of domain experts. In contrast to most knowledge management solutions that directly reuse available information stored in various databases, building disease maps requires to actively look for mechanistic details and add missing pieces.

The resulting representations provide curated systems-level views of the mechanisms associated with a given disease for interpretation by biomedical experts as well as a broader audience, e.g., physicians, teachers and students.

Multiscale knowledge management is at the heart of the disease map concept. This means developing and exploiting protocols for the high-quality representation of information at different levels of granularity including subcellular, cellular, tissue, organ and organism levels. Although we have become better at describing biological events, there are still challenges to be faced, such as the representation of the physiological layers and the inclusion of regulatory mechanisms. Describing diseases in standardised formats will simplify cross-disease comparisons and will facilitate the identification of similarities and differences in molecular and cellular modules between diseases.

Expected development of the project

The Disease Maps Project builds on the research interests of many groups in understanding the mechanisms of particular diseases. This ensures its natural expansion and efficiency: saving time and resources by sharing tasks and investing together in the development of the required tools and pipelines. We anticipate that many disease maps will be initiated and supported within the next several years, which will transform into new technologies tested and made available for rapid advances in translational research.

One of the important driving forces that bring separate groups together is the interest in studying disease comorbidities and shared mechanisms. In addition, we put emphasis on initiating clusters of disease maps for diseases that are shown to have similar mechanisms: allergic diseases, autoimmune diseases, neurodegenerative disorders and cancers of different origins and types. For example, we aim to investigate common mechanisms of asthma (ongoing effort, advanced stage), allergic rhinitis (planning stage) and atopic dermatitis (planning stage).

Agreements on collaboration and developing technologies (http://disease-maps.org/relatedefforts) are reached with complementary efforts such as WikiPathways¹⁵ (https://wikipathways.org), Pathway Commons¹⁶ (http://www.pathwaycommons.org), the Physiome Project¹⁷ (http://physiomeproject.org), Virtual Metabolic Human¹⁸ (https://vmh.uni.lu) and the Garuda Alliance (http://www.garuda-alliance.org). In each case, we identified overlapping activities and directions of research. Specific common interests are standard formats, interoperability among pathway resources, reuse of pathway modules (WikiPathways, Pathway Commons), description and modelling of physiological and pathophysiological mechanisms (Physiome), linking metabolic and signalling networks (Virtual Metabolic Human) and pipelines and communication between tools (Garuda). Starting from small focussed collaborative projects, we plan to establish common frameworks and aim to progress together as partners while optimising the use of resources and the expertise.

Relationships between normal and disease pathways should be further explored. Developing a disease map often means that (1) pathway information is reused and contextualised for a specific condition and cell type, or/and (2) the pathway structure is modified by a disease. The structure of a pathway often remains the same but the concentrations of the involved proteins and metabolites change significantly as the disease progresses; for example, the FcεRI activation by IgE and allergen in asthma leads to the production of eicosanoids.¹⁹ In other cases, for instance in cystic fibrosis, it is mainly about modified or interrupted pathways when a mutation causes an altered life cycle of the CFTR protein.²⁰ Leveraging non-disease pathway resources, flexible navigation within normal and altered-by-disease pathways, the ability to compare the healthy and disease state would be important for the future advances of the Disease Maps Project. There is a need for a technology for comparing pathway modules, determining what contributes to a well-developed reconstruction, on-the-fly decision-making for choosing an appropriate module for a particular disease map.

The Disease Maps Project also aims to align its work with the European-wide research infrastructures roadmap (http://www.esfri.eu/roadmap-2016), e.g., as part of CORBEL (Coordinated Research Infrastructures Building Enduring Life-science Services; http://www.corbel-project.eu).

Integrating resources

Prior to the Disease Maps initiative, the published reconstructions^8–10,12 used different ways to deliver their maps to users. To review several projects, users would have to go to individual project pages and, in most cases, use different systems employed for map browsing. During our second community meeting we started discussing the exploration of disease maps via web-platforms and integration of maps in a shared repository.¹⁴

The first step for integrating various disease maps is agreeing on shared formats as the common ground for all the involved projects. The maps should be available in the established standards such as SBGN, systems biology markup language (SBML)²¹ and BioPAX.²² Neo4j graph database is another framework to apply as it is well suited for queries via its declarative Cypher language. The graph database approach has been shown to facilitate management and exploration of biomedical knowledge.²³ Neo4j format is used, for example, for Recon2²⁴ and Reactome.²⁵ With this prospect in mind, we have developed a tool for converting SBGN-ML to Neo4j format.²⁶

Reusable disease map modules can be stored in pathway-oriented databases. A solution can be found in collaboration with Pathway Commons,¹⁶ WikiPathways¹⁵ and Reactome²⁵ while minimising duplicated activities and addressing compatibility issues. The disease maps themselves should be available for browsing and exploration in a unified way via a centralised easily accessible web repository using platforms such as MINERVA,²⁷ NaviCell^28,29 and iPathways+¹² (http://www.ipathways.org/plus).

The pillars of the community effort

The key aspect of the Disease Maps Project is the interoperability between various disease maps. An agreement on common guidelines and standards will enable projects to help each other, share common tasks and promote trust in the quality of content provided by another group.

We propose to build this community effort upon the following guiding principles.

Standard formats

Efficient knowledge exchange derives from the use and development of standardised formats. Specific visual formats for disease maps are the SBGN Process Description and Activity Flow languages (Fig. ​(Fig.44).^7,30 The maps should be made accessible in a variety of formats including SBML,²¹ BioPAX²² and Neo4j.²⁶ The recently published System Biology Format Converter³¹ makes the task of communication between different formats much simpler.

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Fig. 4

Representation of biological networks. Note that in all the four cases (a−d) the same set of proteins is shown but the relationships are represented differently. The disease maps employ the two sequential representations: process descriptions and activity flows. These representations correspond to the Process Description and Activity Flow languages of the SBGN standard (adapted from ref. ⁵³)

Required resources, infrastructure and tools

One of the primary requisites for the Disease Maps Project is a collection of biological process and pathway modules that can be reused across maps. The focus could be on, e.g., common components of inflammation, immune responses and metabolism due to their pervasive nature in health and disease.

The process of map creation becomes more distributed and offers new challenges for tool developers.¹⁴ With the advances in cloud environments and web technologies, it is expected to have an easy access to drawing maps online, and the development of the web-based Newt Editor (http://newteditor.org) is a promising step in that direction. Also, it becomes critical to have collaborative editing capabilities similar to Google Docs (https://www.google.com/docs/about), version control similar to Git (https://git-scm.com/about) and support for crowdsourcing as successfully implemented by WikiPathways.¹⁵ Advanced layout algorithms are essential for further progress in semi-automatic map construction and on-demand visualisation of complex systems.^32,33 We encourage the development of new tools as open-source software to allow many groups to simultaneously contribute and extend existing functionalities.

To accommodate the requirements of the activities and tasks within the community project, it is important to balance the use of the well-established intensively used software and a step-by-step exploration to the desired new functionalities. As all the published disease maps^8–10,12 are created in CellDesigner, any new tools need to ensure compatibility with such existing format and provide the necessary interoperability.

Of particular importance are the issues of browsing and semantic zooming²⁹ through each disease map. The word “map” implies the possibility of navigation and a “geographic-like” view of molecular interactions. Generation of new hypotheses requires capabilities for high-dimensional data overlay and tools that help transform and analyse interaction networks on-the-fly. Extensive representations that include thousands of entities require improved approaches for complexity management, e.g., organised maps and semantic zooming to efficiently manage the content online via such tools as MINERVA²⁷ and NaviCell.^28,29

Disease maps should be integrated with gene- and protein-interaction-based approaches^34–41 allowing further exploration beyond known disease mechanisms to suggest new disease-associated genes, processes and functional modules, and propose unknown mechanisms.

Examples of disease maps applications for aiding functional interpretation

While the Disease Maps effort is comparatively new and we are only beginning to learn the power of the approach on a larger scale, there are several examples of the use of disease maps validated by experiments and/or using patients’ data.

Synergistic effect of combined treatment in cancer

An integrative analysis of omics data from triple-negative breast cancer (TNBC) cell lines showed that at least 70 non-overlapping genes were robustly correlated with sensitivity to DNA repair inhibitors Dbait (DT01) and Olaparib. Further analysis in the context of the ACSN maps demonstrated that different specific defects in DNA repair machinery were associated to Dbait or Olaparib sensitivity. Network-based molecular signatures highlighted different mechanisms for cells sensitive/resistant to Dbait and Olaparib, suggesting a rationale for the combination of these two drugs. The synergistic therapeutic effect was confirmed for the combined treatment with Dbait and poly(ADP-ribose) polymerase (PARP) inhibitors in TNBC while sparing healthy tissue⁴² (Fig. ​(Fig.55).

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Fig. 5

Sensitivity of TNBC cell lines to combination of DNA repair inhibitors. a Correlation analysis of survival to DT01 and Olaparib in TNBC and control cell lines. b Molecular portraits of DT01 and Olaparib-sensitive/resistant TNBC cell lines visualised on DNA repair map. c Cell survival to combination of DT01 and Olaparib. With DT01 (black line), without DT01 (grey line), dashed lines indicate calculated cell survival for additive effect of two drugs (adapted from Jdey et al.⁴²)

Finding metastasis inducers in colon cancer through network analysis

To study the interplay between signalling pathways regulating the epithelial-to-mesenchymal transition (EMT), the corresponding module was manually created and integrated into the ACSN. Next, the network complexity reduction was performed in BiNoM⁴³ while preserving the core regulators of EMT. The reduced network was used for modelling EMT phenotypes resulting in the prediction that the simultaneous activation of Notch and the loss of p53 can promote EMT.⁴⁴ To validate this hypothesis, a transgenic mouse model was created with a constitutively active Notch1 receptor in a p53-deleted background. EMT markers were shown to be associated with modulation of Notch and p53 gene expression in a manner similar to the mice model supporting the predicted synergy between these genes⁴⁵ (Fig. ​(Fig.66).

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Fig. 6

Prediction of synthetic interaction combination to achieve invasive phenotype in colon cancer mice model. a Comprehensive signalling network of EMT regulation, a part of the ACSN. b Scheme representing major players regulating EMT after structural analysis and reduction of signalling network complexity. c Simplistic model of EMT regulation. d Simplistic model explaining regulation involving Notch, p53 and Wnt pathways. e Lineage tracing of cell in tumour and in distant organs and immunostaining for major EMT markers. f Regulation of p53, Notch and Wnt pathways in invasive colon cancer in human (TCGA data) (adapted from Chanrion et al.⁴⁵)

It is important to note that the hypothesis driven from the disease map was not intuitive and actually contradicted the commonly accepted dogma in the colon cancer field. This clearly demonstrates that gathering cell signalling mechanisms together may lead to discovering unexpected relationships and new mechanisms.

Another example is available in Supplementary material S2: complex intervention gene sets are derived from data-driven network analysis for cancer patients in order to block “proliferation”’ phenotype, all the proliferation-inducing pathways have to be identified and assembled together, including alternative ones.⁴⁶

This work was supported by the CNRS, University of Luxembourg, Institut Curie and in part through the U-BIOPRED (IMI no. 115010 grant to C.A.) and eTRIKS (IMI no. 115446 grant to C.A., R.B. and R.S.) Consortia funded by the European Union and the European Federation of Pharmaceutical Industry Associations, the Coordinating action for the implementation of systems medicine in Europe (CASyM FP7 grant no. 305333 to C.A. and R.B.), the COLOSYS grant ANR-15-CMED-0001-04, provided by the Agence Nationale de la Recherche under the frame of ERACoSysMed-1, the ERA-Net for Systems Medicine in clinical research and medical practice (to I.K., E.B. and A.Z.). A.P. and S.W. acknowledge a research exchange grant from CASyM.