A computational approach to resolve cell level contributions to early glandular epithelial cancer progression

Three-dimensional (3D) embedded cell cultures provide an appropriate physiological environment to reconstruct features of early glandular epithelial cancer. Although these are orders of magnitude simpler than tissues, they too are complex systems that have proven challenging to understand. We used a...

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Bibliographic Details
Published in:BMC systems biology 2009-12, Vol.3 (1), p.122-122, Article 122
Main Authors: Kim, Sean H J, Debnath, Jayanta, Mostov, Keith, Park, Sunwoo, Hunt, C Anthony
Format: Article
Language:English
Subjects:
Algorithms
Animals
Apoptosis
Bioengineering
Cancer
Cell Culture Techniques - methods
Cell division
Colleges & universities
Computational Biology - methods
Computer Simulation
Development and progression
Disease Models, Animal
Disease Progression
Dogs
Epigenesis, Genetic
Epithelial tumors
Extracellular matrix
Genetic aspects
Genotype & phenotype
Histology
Markov Chains
Models, Biological
Morphogenesis
Morphology
Neoplasms, Glandular and Epithelial - diagnosis
Neoplasms, Glandular and Epithelial - pathology
Principles
Research article
Software
Systems Biology - methods
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Summary:Three-dimensional (3D) embedded cell cultures provide an appropriate physiological environment to reconstruct features of early glandular epithelial cancer. Although these are orders of magnitude simpler than tissues, they too are complex systems that have proven challenging to understand. We used agent-based, discrete event simulation modeling methods to build working hypotheses of mechanisms of epithelial 3D culture phenotype and early cancer progression. Starting with an earlier software analogue, we validated an improved in silico epithelial analogue (ISEA) for cardinal features of a normally developed MDCK cyst. A set of axiomatic operating principles defined simulated cell actions. We explored selective disruption of individual simulated cell actions. New framework features enabled recording detailed measures of ISEA cell activities and morphology. Enabled by a small set of cell operating principles, ISEA cells multiplied and self-organized into cyst-like structures that mimicked those of MDCK cells in a 3D embedded cell culture. Selective disruption of "anoikis" or directional cell division caused the ISEA to develop phenotypic features resembling those of in vitro tumor reconstruction models and cancerous tissues in vivo. Disrupting either process, or both, altered cell activity patterns that resulted in morphologically similar outcomes. Increased disruption led to a prolonged presence of intraluminal cells. ISEA mechanisms, behaviors, and morphological properties may have biological counterparts. To the extent that in silico-to-in vitro mappings are valid, the results suggest plausible, additional mechanisms of in vitro cancer reconstruction or reversion, and raise potentially significant implications for early cancer diagnosis based on histology. Further ISEA development and use are expected to provide a viable platform to complement in vitro methods for unraveling the mechanistic basis of epithelial morphogenesis and cancer progression.
ISSN:1752-0509
1752-0509
DOI:10.1186/1752-0509-3-122