Journal
SEMINARS IN CANCER BIOLOGY
Volume 92, Issue -, Pages 61-73Publisher
ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD
DOI: 10.1016/j.semcancer.2023.04.002
Keywords
Clonal interactions; Tumor heterogeneity; Computational biology; Cancer evolution; Mathematical oncology
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Tumors are composed of genetically distinct subclones of cells that can interact with each other, influencing tumor initiation, progression, and metastasis. Previous research has mainly focused on the self-effect of driver mutations in cancer cells. However, recent studies have highlighted the significance of clonal interactions, such as cooperation and competition, in tumor biology. Mathematical and computational models have played a crucial role in understanding the nature of these interactions. Integrating quantitative methods with experimental and clinical data can further unveil the roles of clonal interactions in human cancers.
Tumors consist of different genotypically distinct subpopulations-or subclones-of cells. These subclones can influence neighboring clones in a process called clonal interaction. Conventionally, research on driver mutations in cancer has focused on their cell-autonomous effects that lead to an increase in fitness of the cells containing the driver. Recently, with the advent of improved experimental and computational technologies for investigating tumor heterogeneity and clonal dynamics, new studies have shown the importance of clonal interactions in cancer initiation, progression, and metastasis. In this review we provide an overview of clonal interactions in cancer, discussing key discoveries from a diverse range of approaches to cancer biology research. We discuss common types of clonal interactions, such as cooperation and competition, its mechanisms, and the overall effect on tumorigenesis, with important implications for tumor heterogeneity, resistance to treatment, and tumor suppression. Quantitative models-in coordination with cell culture and animal model experiments-have played a vital role in investigating the nature of clonal interactions and the complex clonal dynamics they generate. We present mathematical and computational models that can be used to represent clonal interactions and provide examples of the roles they have played in identifying and quantifying the strength of clonal interactions in experimental systems. Clonal interactions have proved difficult to observe in clinical data; however, several very recent quantitative approaches enable their detection. We conclude by discussing ways in which researchers can further integrate quantitative methods with experimental and clinical data to elucidate the critical-and often surprising-roles of clonal interactions in human cancers.
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