Abstract
Recent works have highlighted a double role for the Transforming Growth Factor (-): it inhibits cancer in healthy cells and potentiates tumor progression during late stage of tumorigenicity, respectively; therefore it has been termed the “Jekyll and Hyde” of cancer or, alternatively, an “excellent servant but a bad master”. It remains unclear how this molecule could have the two opposite behaviours. In this work, we propose a - multi scale mathematical model at molecular, cellular and tissue scales. The multi scalar behaviours of the - are described by three coupled models built up together which can approximatively be related to distinct microscopic, mesoscopic, and macroscopic scales, respectively. We first model the dynamics of - at the single-cell level by taking into account the intracellular and extracellular balance and the autocrine and paracrine behaviour of -. Then we use the average estimates of the - from the first model to understand its dynamics in a model of duct breast tissue. Although the cellular model and the tissue model describe phenomena at different time scales, their cumulative dynamics explain the changes in the role of - in the progression from healthy to pre-tumoral to cancer. We estimate various parameters by using available gene expression datasets. Despite the fact that our model does not describe an explicit tissue geometry, it provides quantitative inference on the stage and progression of breast cancer tissue invasion that could be compared with epidemiological data in literature. Finally in the last model, we investigated the invasion of breast cancer cells in the bone niches and the subsequent disregulation of bone remodeling processes. The bone model provides an effective description of the bone dynamics in healthy and early stages cancer conditions and offers an evolutionary ecological perspective of the dynamics of the competition between cancer and healthy cells.
Highlights
A full systemic understanding of cancer process will benefit from investigating cell-tissue interaction
Each of these models describes different aspects of the Transforming Growth Factor b (TGF -b) at a particular scale and they are loosely coupled by using averaged quantities of TGF b in such a way to mimic the interactions between different scales; This allows us to consider each model as a ‘‘sub-model’’ which is part of a more comprehensive multi scale model
We propose a model to explain the early stages of tumor and its evolution in bone tissue based on production and sensing of TGF -b in both the paracrine and autocrine processes
Summary
A full systemic understanding of cancer process will benefit from investigating cell-tissue interaction. TGF -b is always produced as an inactive cytokine that cannot bind to its receptor and function unless the latent complex is somehow activated. TGF -b both inhibits and facilitates tumor progression during early and late stage of tumorigenicity, respectively. It still remains veiled how TGF -b plays both contrasting roles [6,7,8]. Tumorigenesis is in many respects a process of disregulated cellular evolution that drives malignant cells to acquire several phenotypic hallmarks of cancer, including the ability of growing autonomously, disregarding cytostatic signals, ignoring apoptotic signals, stimulating angiogenesis, invading, metastasising and becoming immortal. We introduce the role of TGF -b in breast cancer
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