Automated Analysis of Flow Cytometry Data to Reduce Inter-Lab Variation in the Detection of Major Histocompatibility Complex Multimer-Binding T Cells.

Cliburn Chan,P Anoop Chandran,Sine Reker Hadrup,Richard H Scheuermann,Tim Mosmann,Nadia Viborg Petersen,Rick Stanton,Scott White,Kivin Jakobsen,Jonathan Rebhahn,Mathilde Dalsgaard Hoff,Natasja Wulff Pedersen,Alexandra J Lee,Yu Qian,Cécile Gouttefangeas,Charlotte Halgreen

doi:10.3389/fimmu.2017.00858

Abstract

Manual analysis of flow cytometry data and subjective gate-border decisions taken by individuals continue to be a source of variation in the assessment of antigen-specific T cells when comparing data across laboratories, and also over time in individual labs. Therefore, strategies to provide automated analysis of major histocompatibility complex (MHC) multimer-binding T cells represent an attractive solution to decrease subjectivity and technical variation. The challenge of using an automated analysis approach is that MHC multimer-binding T cell populations are often rare and therefore difficult to detect. We used a highly heterogeneous dataset from a recent MHC multimer proficiency panel to assess if MHC multimer-binding CD8+ T cells could be analyzed with computational solutions currently available, and if such analyses would reduce the technical variation across different laboratories. We used three different methods, FLOw Clustering without K (FLOCK), Scalable Weighted Iterative Flow-clustering Technique (SWIFT), and ReFlow to analyze flow cytometry data files from 28 laboratories. Each laboratory screened for antigen-responsive T cell populations with frequency ranging from 0.01 to 1.5% of lymphocytes within samples from two donors. Experience from this analysis shows that all three programs can be used for the identification of high to intermediate frequency of MHC multimer-binding T cell populations, with results very similar to that of manual gating. For the less frequent populations (<0.1% of live, single lymphocytes), SWIFT outperformed the other tools. As used in this study, none of the algorithms offered a completely automated pipeline for identification of MHC multimer populations, as varying degrees of human interventions were needed to complete the analysis. In this study, we demonstrate the feasibility of using automated analysis pipelines for assessing and identifying even rare populations of antigen-responsive T cells and discuss the main properties, differences, and advantages of the different methods tested.

Highlights

Antigen-specific T cell recognition is an essential component of the adaptive immune response fighting infectious diseases and cancer
To assess the impact of individual manual gating compared with central manual gating on specific T cell identification and quantification, fetal calf serum (FCS) data files obtained from the major histocompatibility complex (MHC) multimer proficiency panel were re-analyzed manually by the same operator
We evaluated the feasibility of using automated gating strategies for the detection of antigen-specific T cells using MHC multimers

Summary

Introduction

Antigen-specific T cell recognition is an essential component of the adaptive immune response fighting infectious diseases and cancer. The T cell receptor (TCR)-based recognition profile of a given T cell population can be determined through interaction with fluorescently labeled multimerized peptide major histocompatibility complexes (pMHC multimers) [1], enabling visualization of specific pMHC-responsive T cells by flow cytometry [2] This analysis has become state of the art for antigen-specific CD8+ T cell detection and is important for pathophysiological understanding, target discovery, and diagnosis of immune-mediated diseases. To minimize gating-associated variation and manual handling as well as to improve standardization, several automated analysis strategies have been developed to analyze flow cytometry data based on computational assessments of the different parameters involved [10, 11] These algorithms are based on computational identification of cell clusters in multidimensional space, taking into account all the different parameters applied to a certain cell type. They consider all associated parameters simultaneously, which forms an additional advantage compared with sequential 2D determinations of “positive” or “negative” categories, and leads to a potentially improved identification of a given cell population

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