On-demand Dissolution of Modular, Synthetic Extracellular Matrix Reveals Local Epithelial-stromal Communication Networks

Overview

Journal Biomaterials

Specialty Biomedical Engineering

Date 2017 Apr 4

PMID 28371736

Citations 48

Authors

Jorge Valdez

Christi D Cook

Caroline Chopko Ahrens

Alex J Wang

Alexander Brown

Manu Kumar

Linda Stockdale

Daniel Rothenberg

Kasper Renggli

Elizabeth Gordon

Douglas Lauffenburger

Forest White

Linda Griffith

Affiliations

Soon will be listed here.

Abstract

Methods to parse paracrine epithelial-stromal communication networks are a vital need in drug development, as disruption of these networks underlies diseases ranging from cancer to endometriosis. Here, we describe a modular, synthetic, and dissolvable extracellular matrix (MSD-ECM) hydrogel that fosters functional 3D epithelial-stromal co-culture, and that can be dissolved on-demand to recover cells and paracrine signaling proteins intact for subsequent analysis. Specifically, synthetic polymer hydrogels, modified with cell-interacting adhesion motifs and crosslinked with peptides that include a substrate for cell-mediated proteolytic remodeling, can be rapidly dissolved by an engineered version of the microbial transpeptidase Sortase A (SrtA) if the crosslinking peptide includes a SrtA substrate motif and a soluble second substrate. SrtA-mediated dissolution affected only 1 of 31 cytokines and growth factors assayed, whereas standard protease degradation methods destroyed about half of these same molecules. Using co-encapsulated endometrial epithelial and stromal cells as one model system, we show that the dynamic cytokine and growth factor response of co-cultures to an inflammatory cue is richer and more nuanced when measured from SrtA-dissolved gel microenvironments than from the culture supernate. This system employs accessible, reproducible reagents and facile protocols; hence, has potential as a tool in identifying and validating therapeutic targets in complex diseases.

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