Spatial structure governs the mode of tumour evolution

Noble, Robert; Burri, Dominik; Kather, Jakob Nikolas; Beerenwinkel, Niko

doi:10.1101/586735

Cited by 26 publications

(34 citation statements)

References 43 publications

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“…Our current version of the model completely ignores spatial information, which potentially influences evolutionary dynamics. Recently reported studies have shown that spatial structures regulate evolutionary dynamics in tumors (Noble et al, 2019;West et al, 2019). We also determined that resource bias prompts the driver-branching process, by simulating tumor growth on a one-dimensional lattice (Niida, Hasegawa & Miyano, 2019).…”

Section: Discussionmentioning

confidence: 96%

A unified simulation model for understanding the diversity of cancer evolution

Niida

Hasegawa

Innan

et al. 2020

PeerJ

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Because cancer evolution underlies the therapeutic difficulties of cancer, it is clinically important to understand the evolutionary dynamics of cancer. Thus far, a number of evolutionary processes have been proposed to be working in cancer evolution. However, there exists no simulation model that can describe the different evolutionary processes in a unified manner. In this study, we constructed a unified simulation model for describing the different evolutionary processes and performed sensitivity analysis on the model to determine the conditions in which cancer growth is driven by each of the different evolutionary processes. Our sensitivity analysis has successfully provided a series of novel insights into the evolutionary dynamics of cancer. For example, we found that, while a high neutral mutation rate shapes neutral intratumor heterogeneity (ITH) characterized by a fractal-like pattern, a stem cell hierarchy can also contribute to shaping neutral ITH by apparently increasing the mutation rate. Although It has been reported that the evolutionary principle shaping ITH shifts from selection to accumulation of neutral mutations during colorectal tumorigenesis, our simulation revealed the possibility that this evolutionary shift is triggered by drastic evolutionary events that occur in a short time and confer a marked fitness increase on one or a few cells. This result helps us understand that each process works not separately but simultaneously and continuously as a series of phases of cancer evolution. Collectively, this study serves as a basis to understand in greater depth the diversity of cancer evolution.

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Section: Discussionmentioning

confidence: 96%

A unified simulation model for understanding the diversity of cancer evolution

Niida

Hasegawa

Innan

et al. 2020

PeerJ

View full text Add to dashboard Cite

show abstract

Section: Discussionmentioning

confidence: 96%

Peer Review #1 of "A unified simulation model for understanding the diversity of cancer evolution (v0.1)"

2020

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Because cancer evolution underlies the therapeutic difficulties of cancer, it is clinically important to understand the evolutionary dynamics of cancer. Thus far, a number of evolutionary processes have been proposed to be working in cancer evolution. However, there exists no simulation model that can describe the different evolutionary processes in a unified manner. In this study, we constructed a unified simulation model for describing the different evolutionary processes and performed sensitivity analysis on the model to determine the conditions in which cancer growth is driven by each of the different evolutionary processes. Our sensitivity analysis has successfully provided a series of novel insights into the evolutionary dynamics of cancer. For example, we found that, while a high neutral mutation rate shapes neutral intratumor heterogeneity (ITH) characterized by a fractal-like pattern, a stem cell hierarchy can also contribute to shaping neutral ITH by apparently increasing the mutation rate. Although It has been reported that the evolutionary principle shaping ITH shifts from selection to accumulation of neutral mutations during colorectal tumorigenesis, our simulation revealed the possibility that this evolutionary shift is triggered by drastic evolutionary events that occur in a a short time and confer a marked fitness increase on one or a few cells. This result helps us understand that each process works not separately but simultaneously and continuously as a series of phases of cancer evolution. Collectively, this study serves as a basis to understand in greater depth the diversity of cancer evolution.

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“…Although C A successfully visualizes the spatial clonal architecture assuming a large number of biopsies, we asked the question: can this tool be applicable to smaller datasets? Applying a simulation that mimics the invasive glandular model of tumor growth (Noble et al, 2019), we generated trees and frequency matrices at grid sizes of 3 × 3 and 5 × 5 ( Fig. 6a-b).…”

Section: Simulationsmentioning

confidence: 99%

ClonArch: Visualizing the Spatial Clonal Architecture of Tumors

El-Kebir

2020

Preprint

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Motivation:Cancer is caused by the accumulation of somatic mutations that lead to the formation of distinct populations of cells, called clones. The resulting clonal architecture is the main cause of relapse and resistance to treatment. With decreasing costs in DNA sequencing technology, rich cancer genomics datasets with many spatial sequencing samples are becoming increasingly available, enabling the inference of high-resolution tumor clones and prevalences across different spatial coordinates. While temporal and phylogenetic aspects of tumor evolution, such as clonal evolution over time and clonal response to treatment, are commonly visualized in various clonal evolution diagrams, visual analytics methods that reveal the spatial clonal architecture are missing. Results: This paper introduces ClonArch, a web-based tool to interactively visualize the phylogenetic tree and spatial distribution of clones in a single tumor mass. ClonArch uses the marching squares algorithm to draw closed boundaries representing the presence of clones in a real or simulated tumor. ClonArch enables researchers to examine the spatial clonal architecture of a subset of relevant mutations at different prevalence thresholds and across multiple phylogenetic trees. In addition to simulated tumors with varying number of biopsies, we demonstrate the use of ClonArch on a hepatocellular carcinoma tumor with ∼280 sequencing biopsies. ClonArch provides an automated way to interactively examine the spatial clonal architecture of a tumor, facilitating clinical and biological interpretations of the spatial aspects of intratumor heterogeneity. Availability: https://github.com/elkebir-group/ClonArch

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Spatial structure governs the mode of tumour evolution

Cited by 26 publications

References 43 publications

A unified simulation model for understanding the diversity of cancer evolution

A unified simulation model for understanding the diversity of cancer evolution

Peer Review #1 of "A unified simulation model for understanding the diversity of cancer evolution (v0.1)"

ClonArch: Visualizing the Spatial Clonal Architecture of Tumors

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