Emerging patterns in tumor systems: simulating the dynamics of multicellular clusters with an agent-based spatial agglomeration model.

Brain cancer cells invade early on surrounding parenchyma, which makes it impossible to surgically remove all tumor cells and thus significantly worsens the prognosis of the patient. Specific structural elements such as multicellular clusters have been seen in experimental settings to emerge within the invasive cell system and are believed to express the systems' guidance toward nutritive sites in a heterogeneous environment. Based on these observations, we developed a novel agent-based model of spatio-temporal search and agglomeration to investigate the dynamics of cell motility and aggregation with the assumption that tumors behave as complex dynamic self-organizing biosystems. In this model, virtual cells migrate because they are attracted by higher nutrient concentrations and to avoid overpopulated areas with high levels of toxic metabolites. A specific feature of our model is the capability of cells to search both globally and locally. This concept is applied to simulate cell-surface receptor-mediated information processing of tumor cells such that a cell searching for a more growth-permissive place "learns" the information content of a brain tissue region within a two-dimensional lattice in two stages, processing first the global and then the local input. In both stages, differences in microenvironment characteristics define distinctions in energy expenditure for a moving cell and thus influence cell migration, proliferation, agglomeration, and cell death. Numerical results of our model show a phase transition leading to the emergence of two distinct spatio-temporal patterns depending on the dominant search mechanism. If global search is dominant, the result is a small number of large clusters exhibiting rapid spatial expansion but shorter lifetime of the tumor system. By contrast, if local search is dominant, the trade-off is many small clusters with longer lifetime but much slower velocity of expansion. Furthermore, in the case of such dominant local search, the model reveals an expansive advantage for tumor cell populations with a lower nutrient-depletion rate. Important implications of these results for cancer research are discussed.

[1]  S Torquato,et al.  Simulated brain tumor growth dynamics using a three-dimensional cellular automaton. , 2000, Journal of theoretical biology.

[2]  M. Klauber,et al.  The role of the epidermal growth factor receptor in human gliomas: I. The control of cell growth. , 1995, Journal of neurosurgery.

[3]  K. Pienta,et al.  Cancer as a complex adaptive system. , 1996, Medical hypotheses.

[4]  P. Waliszewski,et al.  On the holistic approach in cellular and cancer biology: Nonlinearity, complexity, and quasi‐determinism of the dynamic cellular network , 1998, Journal of surgical oncology.

[5]  D. S. Coffey,et al.  Chaotic oscillations in cultured cells: rat prostate cancer. , 1996, Cancer research.

[6]  J. Smolle,et al.  Computer simulation of tumour cell invasion by a stochastic growth model. , 1993, Journal of theoretical biology.

[7]  W. Cavenee,et al.  A mutant epidermal growth factor receptor common in human glioma confers enhanced tumorigenicity. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[8]  X. Zheng,et al.  A cellular automaton model of cancerous growth. , 1993, Journal of theoretical biology.

[9]  M. Berens,et al.  Substrates for astrocytoma invasion. , 1995, Neurosurgery.

[10]  G. Turner,et al.  Some effects of products from necrotic regions of tumours on the in vitro migration of cancer and peritoneal exudate cells , 1980, International journal of cancer.

[11]  K. Kalil,et al.  Common mechanisms underlying growth cone guidance and axon branching. , 2000, Journal of neurobiology.

[12]  J. P. Freyer,et al.  Influence of glucose and oxygen supply conditions on the oxygenation of multicellular spheroids. , 1986, British Journal of Cancer.

[13]  R. Sutherland Cell and environment interactions in tumor microregions: the multicell spheroid model. , 1988, Science.

[14]  N. Shigesada,et al.  A dynamical model for the growth and size distribution of multiple metastatic tumors. , 2000, Journal of theoretical biology.

[15]  Paolo A. Netti,et al.  Solid stress inhibits the growth of multicellular tumor spheroids , 1997, Nature Biotechnology.

[16]  D. Bray,et al.  Intracellular signalling as a parallel distributed process. , 1990, Journal of theoretical biology.

[17]  M Koslow,et al.  Pathways leading to glioblastoma multiforme: a molecular analysis of genetic alterations in 65 astrocytic tumors. , 1994, Journal of neurosurgery.

[18]  D. Tarín,et al.  Clinical and experimental studies on the biology of metastasis. , 1985, Biochimica et biophysica acta.

[19]  G. Eaves The invasive growth of malignant tumours as a purely mechanical process , 1973, The Journal of pathology.

[20]  J. Sherratt,et al.  Biological inferences from a mathematical model for malignant invasion. , 1996, Invasion & metastasis.

[21]  D. Louis A Molecular Genetic Model of Astrocytoma Histopathology , 1997, Brain pathology.

[22]  I. Tannock,et al.  Acid pH in tumors and its potential for therapeutic exploitation. , 1989, Cancer research.

[23]  Futoshi Izumi,et al.  Transmural compression-induced proliferation and DNA synthesis through activation of a tyrosine kinase pathway in rat astrocytoma RCR-1 cells , 1998, Brain Research.

[24]  M. Chaplain,et al.  Modelling the growth of solid tumours and incorporating a method for their classification using nonlinear elasticity theory , 1993, Journal of mathematical biology.

[25]  O. Bogler,et al.  A common mutant epidermal growth factor receptor confers enhanced tumorigenicity on human glioblastoma cells by increasing proliferation and reducing apoptosis. , 1996, Cancer research.

[26]  R. Chignola,et al.  Oscillating growth patterns of multicellular tumour spheroids , 1999, Cell proliferation.

[27]  J. Freyer,et al.  Regulation of growth saturation and development of necrosis in EMT6/Ro multicellular spheroids by the glucose and oxygen supply. , 1986, Cancer research.

[28]  G. Laurie,et al.  Basement membrane complexes with biological activity. , 1986, Biochemistry.

[29]  S. Torquato,et al.  Pattern of self‐organization in tumour systems: complex growth dynamics in a novel brain tumour spheroid model , 2001, Cell proliferation.

[30]  A Romano,et al.  Analysis of a "phase transition" from tumor growth to latency. , 2000, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[31]  P. Rørth,et al.  Guidance of cell migration by EGF receptor signaling during Drosophila oogenesis. , 2001, Science.

[32]  S. Coons,et al.  Dichotomy of astrocytoma migration and proliferation , 1996, International journal of cancer.

[33]  J. Nazzaro,et al.  The role of surgery in the management of supratentorial intermediate and high-grade astrocytomas in adults. , 1990, Journal of neurosurgery.

[34]  Michael E. Berens,et al.  Glioma Cell Motility is Associated with Reduced Transcription of Proapoptotic and Proliferation Genes: A cDNA Microarray Analysis , 2001, Journal of Neuro-Oncology.

[35]  O. Suh,et al.  The development of a technique for the morphometric analysis of invasion in cancer. , 1984, Journal of theoretical biology.

[36]  Michael Kraus,et al.  Structured Biological Modelling: A New Approach to Biophysical Cell Biology , 1995 .

[37]  E. Hudson,et al.  Met and hepatocyte growth factor/scatter factor expression in human gliomas. , 1997, Cancer research.

[38]  D. Silbergeld,et al.  Isolation and characterization of human malignant glioma cells from histologically normal brain. , 1997, Journal of neurosurgery.

[39]  J. Sherratt Chemotaxis and chemokinesis in eukaryotic cells: the Keller-Segel equations as an approximation to a detailed model. , 1994, Bulletin of Mathematical Biology.

[40]  W. Mueller‐Klieser Three-dimensional cell cultures: from molecular mechanisms to clinical applications. , 1997, American journal of physiology. Cell physiology.

[41]  R. Del Maestro,et al.  Implantation of C6 astrocytoma spheroid into collagen type I gels: invasive, proliferative, and enzymatic characterizations. , 1997, Journal of neurosurgery.

[42]  J. Furuyama,et al.  Matrix metalloproteinases and tissue inhibitors of metalloproteinases in human gliomas. , 1995, Journal of neurosurgery.

[43]  M Kraus,et al.  Emergence of self-organization in tumor cells: relevance for diagnosis and therapy. , 1993, Tumour biology : the journal of the International Society for Oncodevelopmental Biology and Medicine.

[44]  R. Bjerkvig,et al.  Epidermal growth factor and laminin receptors contribute to migratory and invasive properties of gliomas. , 1997, Invasion & metastasis.

[45]  C Decaestecker,et al.  Dynamic characterization of glioblastoma cell motility. , 1997, Biochemical and biophysical research communications.

[46]  P. Tracqui From passive diffusion to active cellular migration in mathematical models of tumour invasion , 1995, Acta biotheoretica.

[47]  William Feller,et al.  An Introduction to Probability Theory and Its Applications , 1951 .

[48]  J A Sherratt,et al.  Chemical control of eukaryotic cell movement: a new model. , 1993, Journal of theoretical biology.

[49]  K. Kinzler,et al.  Genetic instabilities in human cancers , 1998, Nature.

[50]  D. S. Coffey Self-organization, complexity and chaos: The new biology for medicine , 1998, Nature Medicine.

[51]  Mu-ming Poo,et al.  Adaptation in the chemotactic guidance of nerve growth cones , 2002, Nature.