Abstract
Functional evaluation of molecules that are predicted to promote stem cell mediated endogenous repair often requires in vivo transplant studies that are low throughput and hinder the rate of discovery. Here, we offer a strategy to rapidly test and prioritize molecules for functional validation studies. We miniaturized, simplified and expanded the functionality of a previously developed muscle endogenous repair (MEndR) in vitro assay that was shown to capture significant events of the first week of the in vivo muscle endogenous repair process. The new “mini-MEndR assay” consists of miniaturized cellulose scaffolds designed to fit in 96-well plates. The scaffold pores are infiltrated with myoblasts encapsulated in a fibrin-based hydrogel to form thin, engineered skeletal muscle tissues. By evaluating multiple commercially available human primary myoblast lines in 2D and 3D culture, we establish quality assurance metrics for cell line selection that standardize myotube template quality. Pre-adsorbing thrombin to the cellulose scaffolds facilitates in situ tissue polymerization, a critical modification that enables users proficient in myoblast culture to rapidly acquire myotube template fabrication expertise. Following the generation of the 3D myotube template, muscle stem cells (MuSCs), enriched from digested mouse skeletal muscle tissue using an improved magnetic-activated cell sorting protocol, are engrafted onto the engineered human muscle template. A regenerative milieu is then introduced by injuring the muscle tissue with a myotoxin. Addition of a known modulator of MuSC mediated repair recapitulates the in vivo outcomes (enhanced muscle production and Pax7+ cell expansion), but only in the presence of both the stem cells and the regenerative milieu. By fluorescently labeling the mouse MuSCs, we demonstrate the feasibility of co-evaluating human and mouse Pax7+ cell responses to drug treatment, thereby expanding the utility of the assay. Importantly, phenotypic data is collected with a high-content imaging system and is analyzed using CellProfiler-based image analysis pipelines. The miniaturized predictive assay offers a simple, scaled platform with which to co-investigate human and mouse skeletal muscle endogenous repair molecular modulators, and thus is a promising strategy to accelerate the muscle endogenous repair discovery pipeline.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
-Title was edited to adjust focus. -A duplicated image was detected in Figure 3B, and upon thorough review of data, was determined to be a figure placeholder image that has now been updated with the phenotypic data that was generated for the condition (i.e. Day 14, 19F). -The manuscript text was edited to improve clarity.