Optimized multiplex immunofluorescence single-cell analysis reveals tuft cell heterogeneity
Eliot T. McKinley, … , Michael J. Gerdes, Robert J. Coffey
Eliot T. McKinley, … , Michael J. Gerdes, Robert J. Coffey
Published June 2, 2017
Citation Information: JCI Insight. 2017;2(11):e93487. https://doi.org/10.1172/jci.insight.93487.
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Resource and Technical Advance Gastroenterology

Optimized multiplex immunofluorescence single-cell analysis reveals tuft cell heterogeneity

Abstract

Intestinal tuft cells are a rare, poorly understood cell type recently shown to be a critical mediator of type 2 immune response to helminth infection. Here, we present advances in segmentation algorithms and analytical tools for multiplex immunofluorescence (MxIF), a platform that enables iterative staining of over 60 antibodies on a single tissue section. These refinements have enabled a comprehensive analysis of tuft cell number, distribution, and protein expression profiles as a function of anatomical location and physiological perturbations. Based solely on DCLK1 immunoreactivity, tuft cell numbers were similar throughout the mouse small intestine and colon. However, multiple subsets of tuft cells were uncovered when protein coexpression signatures were examined, including two new intestinal tuft cell markers, Hopx and EGFR phosphotyrosine 1068. Furthermore, we identified dynamic changes in tuft cell number, composition, and protein expression associated with fasting and refeeding and after introduction of microbiota to germ-free mice. These studies provide a foundational framework for future studies of intestinal tuft cell regulation and demonstrate the utility of our improved MxIF computational methods and workflow for understanding cellular heterogeneity in complex tissues in normal and disease states.

Authors

Eliot T. McKinley, Yunxia Sui, Yousef Al-Kofahi, Bryan A. Millis, Matthew J. Tyska, Joseph T. Roland, Alberto Santamaria-Pang, Christina L. Ohland, Christian Jobin, Jeffrey L. Franklin, Ken S. Lau, Michael J. Gerdes, Robert J. Coffey

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Figure 1

Improvements in cell segmentation.

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Improvements in cell segmentation. Segmentation of intestinal epithelial...
Segmentation of intestinal epithelial cells was improved by the use of multiple membrane markers. At the crypt (A) and tip of villus (B), the computational addition of membrane markers (NaKATPase, β-catenin, pan-cytokeratin, and villin) resulted in more complete membrane coverage than the use of NaKATPase as a single marker, as utilized in previous cancer studies. Membrane masks, used as one of the inputs to cellular segmentation, revealed a lack of coverage at the basal surface of cells in the bottom of the crypt and an inability to close the apical portion of the cell using NaKATPase as a single marker. These defects were largely ameliorated when the mask was generated using multiple markers (arrowheads). Similarly, the final cell segmentation (red: membrane; green: cytoplasm; blue: nucleus; white: cell border) derived from a single marker demonstrated substantial loss of cells due to the lack of robust membrane delineation that was vastly improved using the multiple marker input. Scale bar: 50 μm.