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1. Computational modeling of the physical features that influence breast cancer invasion into adipose tissue

Author

Zheng, Yitong, Wang, Dong, Beeghly, Garrett, Fischbach, Claudia, Shattuck, Mark D., and O'Hern, Corey S.

Subjects
Physics - Biological Physics
Abstract

Breast cancer invasion into adipose tissue strongly influences disease progression and metastasis. The degree of cancer cell invasion into adipose tissue depends on numerous biochemical and physical properties of cancer cells, adipocytes, and other key components of adipose tissue. We model breast cancer invasion into adipose tissue as a physical process by carrying out simulations of active, cohesive spherical particles (cancer cells) invading into confluent packings of deformable polyhedra (adipocytes). We quantify the degree of invasion by calculating the interfacial area $A_t$ between cancer cells and adipocytes. We determine the long-time value of $A_t$ versus the activity and strength of the cohesion between cancer cells, as well as mechanical properties of the adipocytes and extracellular matrix (ECM) in which the adipocytes are embedded. We show that the degree of invasion collapses onto a master curve by plotting it versus a dimensionless energy scale $E_c$, which grows linearly with mean-square fluctuations and persistence time of the cancer cell velocities, is inversely proportional to the pressure of the system, and has an offset that increases with the cancer cell cohesive energy. The condition, $E_c \gg 1$, indicates that cancer cells will invade the adipose tissue, whereas for $E_c \ll 1$, the cancer cells and adipocytes remain demixed. We also show that constraints on adipocyte positions by the ECM decrease $A_t$ relative to that obtained for unconstrained adipocytes. Finally, spatial heterogeneity in structural and mechanical properties of the adipocytes in the presence of ECM impedes invasion relative to adipose tissue with uniform properties.

Published
2024
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2. Immunoengineering can overcome the glycocalyx armour of cancer cells

Author

Park, Sangwoo, Colville, Marshall J., Paek, Justin H., Shurer, Carolyn R., Singh, Arun, Secor, Erica J., Sailer, Cooper J., Huang, Ling-Ting, Kuo, Joe Chin-Hun, Goudge, Marc C., Su, Jin, Kim, Minsoo, DeLisa, Matthew P., Neelamegham, Sriram, Lammerding, Jan, Zipfel, Warren R., Fischbach, Claudia, Reesink, Heidi L., and Paszek, Matthew J.

Published
2024
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5. Regulation of Tumor Invasion by the Physical Microenvironment: Lessons from Breast and Brain Cancer

Author

Beeghly, Garrett F, Amofa, Kwasi Y, Fischbach, Claudia, and Kumar, Sanjay

Subjects
Brain Disorders, Brain Cancer, Neurosciences, Breast Cancer, Rare Diseases, Bioengineering, Cancer, Aetiology, 2.1 Biological and endogenous factors, Brain Neoplasms, Glioblastoma, Humans, Neoplasm Invasiveness, Tumor Microenvironment, breast cancer, glioblastoma, physical microenvironment, mechanobiology, tumor invasion, engineering strategies, Biomedical Engineering
Abstract

The success of anticancer therapies is often limited by heterogeneity within and between tumors. While much attention has been devoted to understanding the intrinsic molecular diversity of tumor cells, the surrounding tissue microenvironment is also highly complex and coevolves with tumor cells to drive clinical outcomes. Here, we propose that diverse types of solid tumors share common physical motifs that change in time and space, serving as universal regulators of malignancy. We use breast cancer and glioblastoma as instructive examples and highlight how invasion in both diseases is driven by the appropriation of structural guidance cues, contact-dependent heterotypic interactions with stromal cells, and elevated interstitial fluid pressure and flow. We discuss how engineering strategies show increasing value for measuring and modeling these physical propertiesfor mechanistic studies. Moreover, engineered systems offer great promise for developing and testing novel therapies that improve patient prognosis by normalizing the physical tumor microenvironment.

Published
2022

7. Collagen microarchitecture mechanically controls myofibroblast differentiation

Author

Seo, Bo Ri, Chen, Xingyu, Ling, Lu, Song, Young Hye, Shimpi, Adrian A, Choi, Siyoung, Gonzalez, Jacqueline, Sapudom, Jiranuwat, Wang, Karin, Eguiluz, Roberto Carlos Andresen, Gourdon, Delphine, Shenoy, Vivek B, and Fischbach, Claudia

Subjects
Stem Cell Research, Regenerative Medicine, Bioengineering, Stem Cell Research - Nonembryonic - Human, Adipose Tissue, Biomechanical Phenomena, Cell Differentiation, Cells, Cultured, Collagen, Extracellular Matrix, Fibronectins, Humans, Mechanotransduction, Cellular, Myofibroblasts, Stromal Cells, 3D fibrous matrix mechanics, adipose-derived stem cells, collagen microarchitecture, mechanosignaling, myofibroblast differentiation
Abstract

Altered microarchitecture of collagen type I is a hallmark of wound healing and cancer that is commonly attributed to myofibroblasts. However, it remains unknown which effect collagen microarchitecture has on myofibroblast differentiation. Here, we combined experimental and computational approaches to investigate the hypothesis that the microarchitecture of fibrillar collagen networks mechanically regulates myofibroblast differentiation of adipose stromal cells (ASCs) independent of bulk stiffness. Collagen gels with controlled fiber thickness and pore size were microfabricated by adjusting the gelation temperature while keeping their concentration constant. Rheological characterization and simulation data indicated that networks with thicker fibers and larger pores exhibited increased strain-stiffening relative to networks with thinner fibers and smaller pores. Accordingly, ASCs cultured in scaffolds with thicker fibers were more contractile, expressed myofibroblast markers, and deposited more extended fibronectin fibers. Consistent with elevated myofibroblast differentiation, ASCs in scaffolds with thicker fibers exhibited a more proangiogenic phenotype that promoted endothelial sprouting in a contractility-dependent manner. Our findings suggest that changes of collagen microarchitecture regulate myofibroblast differentiation and fibrosis independent of collagen quantity and bulk stiffness by locally modulating cellular mechanosignaling. These findings have implications for regenerative medicine and anticancer treatments.

Published
2020

16. Obesity-dependent changes in interstitial ECM mechanics promote breast tumorigenesis

Author

Seo, Bo Ri, Bhardwaj, Priya, Choi, Siyoung, Gonzalez, Jacqueline, Andresen Eguiluz, Roberto C, Wang, Karin, Mohanan, Sunish, Morris, Patrick G, Du, Baoheng, Zhou, Xi K, Vahdat, Linda T, Verma, Akanksha, Elemento, Olivier, Hudis, Clifford A, Williams, Rebecca M, Gourdon, Delphine, Dannenberg, Andrew J, and Fischbach, Claudia

Subjects
Medical Biotechnology, Biomedical and Clinical Sciences, Breast Cancer, Nutrition, Obesity, Cancer, Prevention, 2.1 Biological and endogenous factors, Aetiology, Stroke, Oral and gastrointestinal, Cardiovascular, Adipose Tissue, Animals, Breast Neoplasms, Cell Differentiation, Cell Transformation, Neoplastic, Cells, Cultured, Extracellular Matrix, Female, Humans, Mice, Mice, Obese, Biological Sciences, Medical and Health Sciences, Medical biotechnology, Biomedical engineering
Abstract

Obesity and extracellular matrix (ECM) density are considered independent risk and prognostic factors for breast cancer. Whether they are functionally linked is uncertain. We investigated the hypothesis that obesity enhances local myofibroblast content in mammary adipose tissue and that these stromal changes increase malignant potential by enhancing interstitial ECM stiffness. Indeed, mammary fat of both diet- and genetically induced mouse models of obesity were enriched for myofibroblasts and stiffness-promoting ECM components. These differences were related to varied adipose stromal cell (ASC) characteristics because ASCs isolated from obese mice contained more myofibroblasts and deposited denser and stiffer ECMs relative to ASCs from lean control mice. Accordingly, decellularized matrices from obese ASCs stimulated mechanosignaling and thereby the malignant potential of breast cancer cells. Finally, the clinical relevance and translational potential of our findings were supported by analysis of patient specimens and the observation that caloric restriction in a mouse model reduces myofibroblast content in mammary fat. Collectively, these findings suggest that obesity-induced interstitial fibrosis promotes breast tumorigenesis by altering mammary ECM mechanics with important potential implications for anticancer therapies.

Published
2015

17. Stiffening and unfolding of early deposited-fibronectin increase proangiogenic factor secretion by breast cancer-associated stromal cells

Author

Wang, Karin, Eguiluz, Roberto C Andresen, Wu, Fei, Seo, Bo Ri, Fischbach, Claudia, and Gourdon, Delphine

Subjects
Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Cancer, Breast Cancer, Bioengineering, 2.1 Biological and endogenous factors, Aetiology, 3T3-L1 Cells, Animals, Breast Neoplasms, Cell Line, Tumor, Elastic Modulus, Extracellular Matrix, Fibronectins, Humans, Mechanotransduction, Cellular, Mice, Neovascularization, Pathologic, Protein Denaturation, Protein Folding, Stromal Cells, Vascular Endothelial Growth Factor A, Integrin switch, Matrix stiffness, Molecular unfolding, Proangiogenic factor secretion, Tumor-conditioned fibronectin
Abstract

Fibronectin (Fn) forms a fibrillar network that controls cell behavior in both physiological and diseased conditions including cancer. Indeed, breast cancer-associated stromal cells not only increase the quantity of deposited Fn but also modify its conformation. However, (i) the interplay between mechanical and conformational properties of early tumor-associated Fn networks and (ii) its effect on tumor vascularization remain unclear. Here, we first used the Surface Forces Apparatus to reveal that 3T3-L1 preadipocytes exposed to tumor-secreted factors generate a stiffer Fn matrix relative to control cells. We then show that this early matrix stiffening correlates with increased molecular unfolding in Fn fibers, as determined by Förster Resonance Energy Transfer. Finally, we assessed the resulting changes in adhesion and proangiogenic factor (VEGF) secretion of newly seeded 3T3-L1s, and we examined altered integrin specificity as a potential mechanism of modified cell-matrix interactions through integrin blockers. Our data indicate that tumor-conditioned Fn decreases adhesion while enhancing VEGF secretion by preadipocytes, and that an integrin switch is responsible for such changes. Collectively, our findings suggest that simultaneous stiffening and unfolding of initially deposited tumor-conditioned Fn alters both adhesion and proangiogenic behavior of surrounding stromal cells, likely promoting vascularization and growth of the breast tumor. This work enhances our knowledge of cell - Fn matrix interactions that may be exploited for other biomaterials-based applications, including advanced tissue engineering approaches.

Published
2015

23. List of Contributors

Author

Acharya, Abhinav, primary, Ackun-Farmmer, Marian A., additional, Aggas, John R., additional, Andersen, Phillip J., additional, Anderson, James M., additional, Anseth, Kristi, additional, Archer, Paul A., additional, Ashammakhi, Nureddin, additional, Avila, Jose D., additional, Babensee, Julia E., additional, Badylak, Stephen f., additional, Baek, Kiheon, additional, Baker, Aaron B., additional, Bakht, Syeda Mahwish, additional, Bandyopadhyay, Amit, additional, Barchowsky, Aaron, additional, Bass, Garrett, additional, Becker, Matthew L., additional, Belleghem, Sarah Miho Van, additional, Benoit, Danielle S.W., additional, Biesiekierski, Arne, additional, Billiar, Kristen L., additional, Bose, Susmita, additional, Bowman, Christopher, additional, Boyce, Steven, additional, Brown, Bryan N., additional, Brown, Justin L., additional, Capadona, Jeffrey R., additional, Castner, David G., additional, Chang, Calvin, additional, Chang, Philip, additional, Chilkoti, Ashutosh, additional, Christman, Karen L., additional, Chung, Sangwon, additional, Coleman, Kelly P., additional, Conway, Dan, additional, Cook, Keith E., additional, Cooper, Stuart L., additional, Cosgriff-Hernandez, Elizabeth, additional, Coury, Arthur J., additional, Criscione, Joseph D., additional, Culver, Heidi, additional, Curtis, Jim, additional, Deng, Feiyang, additional, Dhavalikar, Prachi, additional, Diaz-Gomez, Luis, additional, Domingues, Rui M.A., additional, Duncan, Elaine, additional, Duran, Pamela, additional, Esbrit, Pedro, additional, Eskin, Suzanne G., additional, Esmail, Michael Y., additional, Ferracane, Jack L., additional, Fischbach, Claudia, additional, Fischman, Gary, additional, Fisher, John P., additional, Francolini, Iolanda, additional, Frey, Steven J., additional, Gaharwar, Akhilesh K., additional, García, Andrés J., additional, Gibson, Iain R., additional, Gilbert, Jeremy L., additional, Ginn, Brian, additional, Goldblatt, Zachary E., additional, Goldenberg, Seth J., additional, Gomes, Manuela E., additional, Gómez-Florit, Manuel, additional, Gonçalves, Inês C., additional, Gorbet, Maud B., additional, Grainger, David W., additional, Grody, Miles, additional, Guda, Teja, additional, Guelcher, Scott A., additional, Guiseppi-Elie, Anthony, additional, Hacking, S. Adam, additional, Hallab, Nadim James, additional, Hall-Stoodley, Luanne, additional, Hanson, Stephen R., additional, Han, Woojin M., additional, Harman, Melinda K., additional, Harrington, Roger, additional, Haschak, Martin J., additional, Heath, Daniel E., additional, Hicks, Emily Anne, additional, Hill, Ryan T., additional, Hoffman, Allan S., additional, Horbett, Thomas A., additional, Hubbell, Jeffrey A., additional, Ipek, Rasim, additional, Jacobs, Joshua J., additional, Jang, Young C., additional, Jiang, Shaoyi, additional, Johnson, Richard J., additional, Jones, Julian R., additional, Jo, Vickie Y., additional, Kane, Ravi S., additional, Kaplan, David L., additional, Kar, Ronit, additional, Keselowsky, Benjamin George, additional, Khademhosseini, Ali, additional, Kim, Yu Seon, additional, King, Martin W., additional, Kohane, Daniel S., additional, Kohn, David H., additional, Kuhn, Liisa T., additional, Kulkarni, Mangesh, additional, Kuo, Catherine K., additional, Lai, Angela, additional, Lambert, Bryron, additional, Lan, Ziyang, additional, Latour, Robert A., additional, Laurencin, Cato T., additional, Lawson, Bryan K., additional, Layland, Shannon Lee, additional, Lee, Jae Sung, additional, Lee-Parritz, David, additional, Lei, Ying, additional, Lemons, Jack E., additional, Levy, Robert J., additional, Lewerenz, Gregory M., additional, Lewis, Jamal S., additional, Liebscher, Simone, additional, Lin, Chien-Chi, additional, Livingston, Natalie K., additional, Li, Yang, additional, Li, Yuncang, additional, Lu, Helen, additional, Macdougall, Laura, additional, Mahadik, Bhushan, additional, Mamidwar, Sachin, additional, Manspeaker, Margaret P., additional, Mao, Hai-Quan, additional, Ma, Peter X., additional, Marcet, Tyler, additional, Martin, Jeffrey, additional, Martins, M. Cristina L., additional, McArthur, Sally L., additional, McGill, Meghan, additional, McIntire, Larry V., additional, Mei, Lei, additional, Mendes, Bárbara B., additional, Mikos, Antonios G., additional, Mitchell, Richard N., additional, Mitra, Indranath, additional, Muirhead, Ben, additional, Munir, Khurram, additional, Murphy, William L., additional, Nguyen, Phong K., additional, Nolfi, Alexis L., additional, Overby, Clyde, additional, Ozan, Sertan, additional, Padera, Robert F., additional, Pearce, Hannah A., additional, Peppas, Nicholas A., additional, Pereira, Andreia T., additional, Pfeifer, Carmem S., additional, Pinto, Artur M., additional, Raia, Nicole R., additional, Rankin, Edward A., additional, Ratner, Buddy D., additional, Regi, Maria Vallet, additional, Reis, Rui L., additional, Ritchie, Alastair Campbell, additional, Sakiyama-Elbert, Shelly E., additional, Salhadar, Karim, additional, Salinas, Antonio J., additional, Schenke-Layland, Katja, additional, Schoen, Frederick J., additional, Schutrum, Brittany E., additional, Sefton, Michael V., additional, Seidman, Michael A., additional, Shah, Darshan S., additional, Sheardown, Heather, additional, Shoffstall, Andrew J., additional, Simon, Carl G., additional, Simon, Josh, additional, Sims Jr., Kenneth R., additional, Slack, Steven M., additional, Slavin, Benjamin, additional, Snodderly, Kirstie Lane, additional, Stayton, Patrick S., additional, Steichen, Stephanie D., additional, Stoodley, Paul, additional, Swanson, W. Benton, additional, Tam, Hobey, additional, Tayab, Aftab, additional, Thomas, Susan N., additional, Traxel, Kellen D., additional, Tuan, Rocky S., additional, Tucker, Erik I., additional, Ukita, Rei, additional, Veith, Austin, additional, Vidal Yucha, Sarah E., additional, Viney, Christopher, additional, Vyavahare, Naren, additional, Wagner, William R., additional, Wang, Min, additional, Wang, Raymond M., additional, Warner, Petra, additional, Wen, Cuie, additional, West, Jennifer L., additional, Whitman, Matthew A., additional, Witte, Frank, additional, Wolf, Michael F., additional, Yao, Zhicheng, additional, Yaszemski, Michael, additional, Yaszemski, Michael J., additional, Yin, Lichen, additional, Zhang, Guigen, additional, Zhang, Peng, additional, Zhong, Zhiyuan, additional, and Ziats, Nicholas P., additional

Published
2020
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27. A physical sciences network characterization of non-tumorigenic and metastatic cells

Author

Agus, David B, Alexander, Jenolyn F, Arap, Wadih, Ashili, Shashanka, Aslan, Joseph E, Austin, Robert H, Backman, Vadim, Bethel, Kelly J, Bonneau, Richard, Chen, Wei-Chiang, Chen-Tanyolac, Chira, Choi, Nathan C, Curley, Steven A, Dallas, Matthew, Damania, Dhwanil, Davies, Paul CW, Decuzzi, Paolo, Dickinson, Laura, Estevez-Salmeron, Luis, Estrella, Veronica, Ferrari, Mauro, Fischbach, Claudia, Foo, Jasmine, Fraley, Stephanie I, Frantz, Christian, Fuhrmann, Alexander, Gascard, Philippe, Gatenby, Robert A, Geng, Yue, Gerecht, Sharon, Gillies, Robert J, Godin, Biana, Grady, William M, Greenfield, Alex, Hemphill, Courtney, Hempstead, Barbara L, Hielscher, Abigail, Hillis, W Daniel, Holland, Eric C, Ibrahim-Hashim, Arig, Jacks, Tyler, Johnson, Roger H, Joo, Ahyoung, Katz, Jonathan E, Kelbauskas, Laimonas, Kesselman, Carl, King, Michael R, Konstantopoulos, Konstantinos, Kraning-Rush, Casey M, Kuhn, Peter, Kung, Kevin, Kwee, Brian, Lakins, Johnathon N, Lambert, Guillaume, Liao, David, Licht, Jonathan D, Liphardt, Jan T, Liu, Liyu, Lloyd, Mark C, Lyubimova, Anna, Mallick, Parag, Marko, John, McCarty, Owen JT, Meldrum, Deirdre R, Michor, Franziska, Mumenthaler, Shannon M, Nandakumar, Vivek, O'Halloran, Thomas V, Oh, Steve, Pasqualini, Renata, Paszek, Matthew J, Philips, Kevin G, Poultney, Christopher S, Rana, Kuldeepsinh, Reinhart-King, Cynthia A, Ros, Robert, Semenza, Gregg L, Senechal, Patti, Shuler, Michael L, Srinivasan, Srimeenakshi, Staunton, Jack R, Stypula, Yolanda, Subramanian, Hariharan, Tlsty, Thea D, Tormoen, Garth W, Tseng, Yiider, van Oudenaarden, Alexander, Verbridge, Scott S, Wan, Jenny C, Weaver, Valerie M, Widom, Jonathan, Will, Christine, Wirtz, Denis, Wojtkowiak, Jonathan, and Wu, Pei-Hsun

Subjects
Biochemistry and Cell Biology, Biological Sciences, Cancer, Breast Cancer, Biotechnology, Aetiology, 2.1 Biological and endogenous factors, Biomarkers, Tumor, Cell Line, Tumor, Cell Movement, Cell Size, Cell Survival, Computer Simulation, Gene Expression Regulation, Neoplastic, Humans, Models, Biological, Neoplasm Metastasis, Neoplasm Proteins, Physical Sciences - Oncology Centers Network
Abstract

To investigate the transition from non-cancerous to metastatic from a physical sciences perspective, the Physical Sciences-Oncology Centers (PS-OC) Network performed molecular and biophysical comparative studies of the non-tumorigenic MCF-10A and metastatic MDA-MB-231 breast epithelial cell lines, commonly used as models of cancer metastasis. Experiments were performed in 20 laboratories from 12 PS-OCs. Each laboratory was supplied with identical aliquots and common reagents and culture protocols. Analyses of these measurements revealed dramatic differences in their mechanics, migration, adhesion, oxygen response, and proteomic profiles. Model-based multi-omics approaches identified key differences between these cells' regulatory networks involved in morphology and survival. These results provide a multifaceted description of cellular parameters of two widely used cell lines and demonstrate the value of the PS-OC Network approach for integration of diverse experimental observations to elucidate the phenotypes associated with cancer metastasis.

Published
2013

28. A physical sciences network characterization of non-tumorigenic and metastatic cells.

Author

Physical Sciences - Oncology Centers Network, Agus, David B, Alexander, Jenolyn F, Arap, Wadih, Ashili, Shashanka, Aslan, Joseph E, Austin, Robert H, Backman, Vadim, Bethel, Kelly J, Bonneau, Richard, Chen, Wei-Chiang, Chen-Tanyolac, Chira, Choi, Nathan C, Curley, Steven A, Dallas, Matthew, Damania, Dhwanil, Davies, Paul CW, Decuzzi, Paolo, Dickinson, Laura, Estevez-Salmeron, Luis, Estrella, Veronica, Ferrari, Mauro, Fischbach, Claudia, Foo, Jasmine, Fraley, Stephanie I, Frantz, Christian, Fuhrmann, Alexander, Gascard, Philippe, Gatenby, Robert A, Geng, Yue, Gerecht, Sharon, Gillies, Robert J, Godin, Biana, Grady, William M, Greenfield, Alex, Hemphill, Courtney, Hempstead, Barbara L, Hielscher, Abigail, Hillis, W Daniel, Holland, Eric C, Ibrahim-Hashim, Arig, Jacks, Tyler, Johnson, Roger H, Joo, Ahyoung, Katz, Jonathan E, Kelbauskas, Laimonas, Kesselman, Carl, King, Michael R, Konstantopoulos, Konstantinos, Kraning-Rush, Casey M, Kuhn, Peter, Kung, Kevin, Kwee, Brian, Lakins, Johnathon N, Lambert, Guillaume, Liao, David, Licht, Jonathan D, Liphardt, Jan T, Liu, Liyu, Lloyd, Mark C, Lyubimova, Anna, Mallick, Parag, Marko, John, McCarty, Owen JT, Meldrum, Deirdre R, Michor, Franziska, Mumenthaler, Shannon M, Nandakumar, Vivek, O'Halloran, Thomas V, Oh, Steve, Pasqualini, Renata, Paszek, Matthew J, Philips, Kevin G, Poultney, Christopher S, Rana, Kuldeepsinh, Reinhart-King, Cynthia A, Ros, Robert, Semenza, Gregg L, Senechal, Patti, Shuler, Michael L, Srinivasan, Srimeenakshi, Staunton, Jack R, Stypula, Yolanda, Subramanian, Hariharan, Tlsty, Thea D, Tormoen, Garth W, Tseng, Yiider, van Oudenaarden, Alexander, Verbridge, Scott S, Wan, Jenny C, Weaver, Valerie M, Widom, Jonathan, Will, Christine, Wirtz, Denis, Wojtkowiak, Jonathan, and Wu, Pei-Hsun

Subjects
Physical Sciences - Oncology Centers Network, Cell Line, Tumor, Humans, Neoplasm Metastasis, Neoplasm Proteins, Cell Movement, Cell Size, Cell Survival, Gene Expression Regulation, Neoplastic, Models, Biological, Computer Simulation, Biomarkers, Tumor, Cancer, Breast Cancer, Biotechnology, 2.1 Biological and endogenous factors
Abstract

To investigate the transition from non-cancerous to metastatic from a physical sciences perspective, the Physical Sciences-Oncology Centers (PS-OC) Network performed molecular and biophysical comparative studies of the non-tumorigenic MCF-10A and metastatic MDA-MB-231 breast epithelial cell lines, commonly used as models of cancer metastasis. Experiments were performed in 20 laboratories from 12 PS-OCs. Each laboratory was supplied with identical aliquots and common reagents and culture protocols. Analyses of these measurements revealed dramatic differences in their mechanics, migration, adhesion, oxygen response, and proteomic profiles. Model-based multi-omics approaches identified key differences between these cells' regulatory networks involved in morphology and survival. These results provide a multifaceted description of cellular parameters of two widely used cell lines and demonstrate the value of the PS-OC Network approach for integration of diverse experimental observations to elucidate the phenotypes associated with cancer metastasis.

Published
2013

31. Endothelial cells metabolically regulate breast cancer invasion toward a microvessel.

Author

Tan, Matthew L., Jenkins-Johnston, Niaa, Huang, Sarah, Schutrum, Brittany, Vadhin, Sandra, Adhikari, Abhinav, Williams, Rebecca M., Zipfel, Warren R., Lammerding, Jan, Varner, Jeffrey D., and Fischbach, Claudia

Subjects
OXYGEN consumption, GLYCOLYSIS, ENDOTHELIAL cells, METASTATIC breast cancer, BREAST cancer, CELL metabolism, GLUCOSE metabolism
Abstract

Breast cancer metastasis is initiated by invasion of tumor cells into the collagen type I-rich stroma to reach adjacent blood vessels. Prior work has identified that metabolic plasticity is a key requirement of tumor cell invasion into collagen. However, it remains largely unclear how blood vessels affect this relationship. Here, we developed a microfluidic platform to analyze how tumor cells invade collagen in the presence and absence of a microvascular channel. We demonstrate that endothelial cells secrete pro-migratory factors that direct tumor cell invasion toward the microvessel. Analysis of tumor cell metabolism using metabolic imaging, metabolomics, and computational flux balance analysis revealed that these changes are accompanied by increased rates of glycolysis and oxygen consumption caused by broad alterations of glucose metabolism. Indeed, restricting glucose availability decreased endothelial cell-induced tumor cell invasion. Our results suggest that endothelial cells promote tumor invasion into the stroma due, in part, to reprogramming tumor cell metabolism. [ABSTRACT FROM AUTHOR]

Published
2023
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32. Supplementary Figure S3 from Influencing the Tumor Microenvironment: A Phase II Study of Copper Depletion Using Tetrathiomolybdate in Patients with Breast Cancer at High Risk for Recurrence and in Preclinical Models of Lung Metastases

Author

Chan, Nancy, primary, Willis, Amy, primary, Kornhauser, Naomi, primary, Ward, Maureen M., primary, Lee, Sharrell B., primary, Nackos, Eleni, primary, Seo, Bo Ri, primary, Chuang, Ellen, primary, Cigler, Tessa, primary, Moore, Anne, primary, Donovan, Diana, primary, Vallee Cobham, Marta, primary, Fitzpatrick, Veronica, primary, Schneider, Sarah, primary, Wiener, Alysia, primary, Guillaume-Abraham, Jessica, primary, Aljom, Elnaz, primary, Zelkowitz, Richard, primary, Warren, J. David, primary, Lane, Maureen E., primary, Fischbach, Claudia, primary, Mittal, Vivek, primary, and Vahdat, Linda, primary

Published
2023
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36. Biomineralogical signatures of breast microcalcifications

Author

Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Kunitake, Jennie AMR, Sudilovsky, Daniel, Johnson, Lynn M, Loh, Hyun-Chae, Choi, Siyoung, Morris, Patrick G, Jochelson, Maxine S, Iyengar, Neil M, Morrow, Monica, Masic, Admir, Fischbach, Claudia, Estroff, Lara A, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Kunitake, Jennie AMR, Sudilovsky, Daniel, Johnson, Lynn M, Loh, Hyun-Chae, Choi, Siyoung, Morris, Patrick G, Jochelson, Maxine S, Iyengar, Neil M, Morrow, Monica, Masic, Admir, Fischbach, Claudia, and Estroff, Lara A

Abstract

Microcalcifications, primarily biogenic apatite, occur in cancerous and benign breast pathologies and are key mammographic indicators. Outside the clinic, numerous microcalcification compositional metrics (e.g., carbonate and metal content) are linked to malignancy, yet microcalcification formation is dependent on microenvironmental conditions, which are notoriously heterogeneous in breast cancer. We interrogate multiscale heterogeneity in 93 calcifications from 21 breast cancer patients using an omics-inspired approach: For each microcalcification, we define a “biomineralogical signature” combining metrics derived from Raman microscopy and energy-dispersive spectroscopy. We observe that (i) calcifications cluster into physiologically relevant groups reflecting tissue type and local malignancy; (ii) carbonate content exhibits substantial intratumor heterogeneity; (iii) trace metals including zinc, iron, and aluminum are enhanced in malignant-localized calcifications; and (iv) the lipid-to-protein ratio within calcifications is lower in patients with poor composite outcome, suggesting that there is potential clinical value in expanding research on calcification diagnostic metrics to include “mineral-entrapped” organic matrix.

Published
2023

40. Biomineralogical signatures of breast microcalcifications

Author

Kunitake, Jennie A. M. R., primary, Sudilovsky, Daniel, additional, Johnson, Lynn M., additional, Loh, Hyun-Chae, additional, Choi, Siyoung, additional, Morris, Patrick G., additional, Jochelson, Maxine S., additional, Iyengar, Neil M., additional, Morrow, Monica, additional, Masic, Admir, additional, Fischbach, Claudia, additional, and Estroff, Lara A., additional

Published
2023
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41. Mucins form a nanoscale physical barrier against immune cell attack

Author

Park, Sangwoo, primary, Colville, Marshall, additional, Shurer, Carolyn, additional, Huang, Ling-Ting, additional, Kuo, Joe, additional, Paek, Justin, additional, Goudge, Marc, additional, Su, Jin, additional, DeLisa, Matthew, additional, Lammerding, Jan, additional, Zipfel, Warren, additional, Fischbach, Claudia, additional, Reesink, Heidi, additional, and Paszek, Matthew, additional

Published
2023
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46. IGF2BP2 promotes cancer progression by degrading the RNA transcript encoding a v-ATPase subunit

Author

Latifkar, Arash, primary, Wang, Fangyu, additional, Mullmann, James J., additional, Panizza, Elena, additional, Fernandez, Irma R., additional, Ling, Lu, additional, Miller, Andrew D., additional, Fischbach, Claudia, additional, Weiss, Robert S., additional, Lin, Hening, additional, Cerione, Richard A., additional, and Antonyak, Marc A., additional

Published
2022
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