A tremendous gap exists between available culture and animal models and methods that can extract detailed information on cell-cell communication networks governing system responses to perturbations, such as an inflammatory cue. Networks inherently operate in a complex, interlinked fashion, and often exhibit non-intuitive outcomes from intervention at a particular point in the network, as evidenced by failure of many targeted therapeutics to operate in the clinical setting after promising results in currently- available preclinical trials. Cell-cell communication networks comprise factors the cells release into the extracellular milieu (e.g., cytokines, proteases) along with intracellular signals. While an immense amount of effort has focused on intracellular signals generated in simple cell culture systems by straightforward treatment with individual stimulatory cues, it is not clear how relevant those are to the signals arising from interplay of multiple cues being produced at sequential time-points by diverse cell types as dynamic cascades. Elucidating vital aspects of the interplay of extracellular factors in multi-population cellular systems is crucial for understanding tissue pathophysiology but is exceedingly difficult to study in vivo or in traditional cell culture systems. In this project, we will develop transformative new methods to integrate real time molecular probes of cell-cell communication networks and consequent cell behavior into complex, physiological 3D cultures, allowing multiplexed, dynamic information to be derived from these cultures in response to specific manipulations of the system variables, including cell populations involved and external perturbations such as inflammatory cues. Our goal is to build models of primary human systems to serve as close mimics of in vivo complexity, hence we focus on developing new methods that do not rely on genetic manipulation of the cell populations to generate information about systems operation. Our overall project will advance via three parallel but interwoven efforts: development of an analytical formalism for communication modes that connects extracellular and intracellular networks and provides a framework for identifying key extracellular nodes from measurements (such as proteomic analysis) of extracellular medium;development of new biomaterials microenvironments that both control and record key nodes in local cell communication signals in the pericellular environment in a multiplexed manner, with high spatial and temporal resolution;and integration of these approaches into microscale perfused culture systems that foster appropriate cellular and tissue physiology through control of factors including extracellular matrix properties, culture geometry, local oxygen tension, and mechanical stresses. A major innovation in our work is linking these approaches in a synergistic manner to provide systems that can be used broadly in a wide variety of tissue systems with application to an array of individual diseases, including those where sexually dimorphic responses are prominent.

Public Health Relevance

The goal of this project is transform our ability to probe cell-cell communication networks in human cell systems via linking systems biology with tissue engineering. Our overall project will advance via three parallel but interwoven efforts: development of an analytical formalism for communication modes that connects extracellular and intracellular networks and provides a framework for identifying key extracellular nodes from measurements (such as proteomic analysis) of extracellular medium;development of new biomaterials microenvironments that both control and record key nodes in local cell communication signals in the pericellular environment in a multiplexed manner, with high spatial and temporal resolution;and integration of these approaches into microscale perfused culture systems that foster appropriate cellular and tissue physiology through control of factors extracellular matrix properties, culture geometry, local oxygen tension, and mechanical stresses.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB010246-03
Application #
8137070
Study Section
Special Emphasis Panel (ZRG1-BCMB-A (51))
Program Officer
Hunziker, Rosemarie
Project Start
2009-09-30
Project End
2014-08-31
Budget Start
2011-09-01
Budget End
2012-08-31
Support Year
3
Fiscal Year
2011
Total Cost
$659,927
Indirect Cost
Name
Massachusetts Institute of Technology
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
001425594
City
Cambridge
State
MA
Country
United States
Zip Code
02139
Ravindra, Kodihalli C; Ahrens, Caroline C; Wang, Yang et al. (2018) Chemoproteomics of matrix metalloproteases in a model of cartilage degeneration suggests functional biomarkers associated with posttraumatic osteoarthritis. J Biol Chem 293:11459-11469
Valdez, Jorge; Cook, Christi D; Ahrens, Caroline Chopko et al. (2017) On-demand dissolution of modular, synthetic extracellular matrix reveals local epithelial-stromal communication networks. Biomaterials 130:90-103
de Picciotto, Seymour; Dickson, Paige M; Traxlmayr, Michael W et al. (2016) Design Principles for SuCESsFul Biosensors: Specific Fluorophore/Analyte Binding and Minimization of Fluorophore/Scaffold Interactions. J Mol Biol 428:4228-4241
Cambria, Elena; Renggli, Kasper; Ahrens, Caroline C et al. (2015) Covalent Modification of Synthetic Hydrogels with Bioactive Proteins via Sortase-Mediated Ligation. Biomacromolecules 16:2316-26
Ahrens, Caroline C; Welch, M Elizabeth; Griffith, Linda G et al. (2015) Uncharged Helical Modular Polypeptide Hydrogels for Cellular Scaffolds. Biomacromolecules 16:3774-83
Shah, Nisarg J; Hyder, Md Nasim; Quadir, Mohiuddin A et al. (2014) Adaptive growth factor delivery from a polyelectrolyte coating promotes synergistic bone tissue repair and reconstruction. Proc Natl Acad Sci U S A 111:12847-52
de Picciotto, Seymour; Imperiali, Barbara; Griffith, Linda G et al. (2014) Equilibrium and dynamic design principles for binding molecules engineered for reagentless biosensors. Anal Biochem 460:9-15
Ebrahimkhani, Mohammad R; Neiman, Jaclyn A Shepard; Raredon, Micha Sam B et al. (2014) Bioreactor technologies to support liver function in vitro. Adv Drug Deliv Rev 69-70:132-57
Griffith, Linda G; Wells, Alan; Stolz, Donna B (2014) Engineering liver. Hepatology 60:1426-34
Sarkar, Aniruddh; Kolitz, Sarah; Lauffenburger, Douglas A et al. (2014) Microfluidic probe for single-cell analysis in adherent tissue culture. Nat Commun 5:3421

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