Cellular Behavior Analysis from Live-cell Imaging of TCR T Cell-cancer Cell Interactions

Overview

Journal bioRxiv

Date 2024 Nov 28

PMID 39605616

Authors

Archit Verma

Changhua Yu

Stefanie Bachl

Ivan Lopez

Morgan Schwartz

Erick Moen

Nupura Kale

Carter Ching

Geneva Miller

Tom Dougherty

Ed Pao

William Graf

Carl Ward

Siddhartha Jena

Alex Marson

Julia Carnevale

David Van Valen

Barbara E Engelhardt

Affiliations

Soon will be listed here.

Abstract

T cell therapies, such as chimeric antigen receptor (CAR) T cells and T cell receptor (TCR) T cells, are a growing class of anti-cancer treatments. However, expansion to novel indications and beyond last-line treatment requires engineering cells' dynamic population behaviors. Here we develop the tools for of T cells from live-cell imaging, a common and inexpensive experimental setup used to evaluate engineered T cells. We first develop a state-of-the-art segmentation and tracking pipeline, , based on human-in-the-loop deep learning. We then build the pipeline to collect a catalog of phenotypes that characterize cell populations, morphology, movement, and interactions in co-cultures of modified T cells and antigen-presenting tumor cells. We use Caliban and Occident to interrogate how interactions between T cells and cancer cells differ when beneficial knock-outs of and are introduced into TCR T cells. We apply spatiotemporal models to quantify T cell recruitment and proliferation after interactions with cancer cells. We discover that, compared to a safe harbor knockout control, knockout T cells have longer interaction times with cancer cells leading to greater T cell activation and killing efficacy, while knockout T cells have increased proliferation rates leading to greater numbers of T cells for hunting. Together, segmentation and tracking from Caliban and phenotype quantification from Occident enable cellular behavior analysis to better engineer T cell therapies for improved cancer treatment.

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