Abstract
A major barrier for broadening the efficacy of immunotherapies for cancer is identifying key mechanisms that limit the efficacy of tumor infiltrating lymphocytes. Yet, identifying these mechanisms using human samples and mouse models for cancer remains a challenge. While interactions between cancer and the immune system are dynamic and non-linear, identifying the relative roles that biological components play in regulating anti-tumor immunity commonly relies on human intuition alone, which can be limited by cognitive biases. To assist natural intuition, modeling and simulation play an emerging role in identifying therapeutic mechanisms. To illustrate the approach, we developed a multi-scale mechanistic model to describe the control of tumor growth by a primary response of CD8+ T cells against defined tumor antigens using the B16 C57Bl/6 mouse model for malignant melanoma. The mechanistic model was calibrated to data obtained following adenovirus-based immunization and validated to data obtained following adoptive transfer of transgenic CD8+ T cells. More importantly, we use simulation to test whether the postulated network topology, that is the modeled biological components and their associated interactions, is sufficient to capture the observed anti-tumor immune response. Given the available data, the simulation results also provided a statistical basis for quantifying the relative importance of different mechanisms that underpin CD8+ T cell control of B16F10 growth. By identifying conditions where the postulated network topology is incomplete, we illustrate how this approach can be used as part of an iterative design-build-test cycle to expand the predictive power of the model.
Highlights
Recent clinical successes illustrate the potential of immunotherapy to treat cancer (Topalian et al, 2015)
To illustrate in silico model-based inference in the context of cancer immunotherapy, we developed a multi-scale mechanistic model to describe the control of tumor growth by a primary response of CD8+ T cells against defined tumor antigens using the B16 mouse model for malignant melanoma (Ya et al, 2015)
Given the challenges associated with testing hypotheses in humans, pre-clinical mouse models, like the B16 model for malignant melanoma, play a central role in identifying how tumors escape from immune-mediated control
Summary
Recent clinical successes illustrate the potential of immunotherapy to treat cancer (Topalian et al, 2015). Malignant cells create a tissue niche by changing how cells communicate and by disrupting host immunity in non-intuitive ways that can be different among patients and between humans and pre-clinical models (Laland et al, 2014; Klinke, 2014b, 2016). Identifying the Simulating Immune Control of Tumor Growth relative importance of specific mechanisms that can disrupt host immunity in a particular system from experimental data is challenging using human intuition alone. We illustrate a new approach enabled by improved computational power that can be used to test whether our existing knowledge of the key components of a biological system and their interactions, that is the network topology, are sufficient to explain the observed data irrespective of a lack of knowledge regarding the associated parameter values
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call