A quantitative high-throughput chemotaxis assay using bioluminescent reporter cells.

Here we report on a novel biophotonic assay system for the detection and quantitation of chemotaxis, the directed movement of cells in response to chemokine concentration gradients. Our assay employs a firefly luciferase (ffLuc)-generated biophotonic signal to quantify cellular migration in 96-well microplate chemotaxis instruments. When compared to direct cell enumeration, the biophotonic reporter method is superior in accuracy, reproducibility, and sensitivity.

Biophotonic cytotoxicity assay for high-throughput screening of cytolytic killing.

We have developed a highly sensitive biophotonic luciferase assay as an alternative to (51)Cr-release for assessment of cell-mediated cytotoxicity. The luciferin/ATP-dependent luminescent signal of target cells stably or transiently transfected with a firefly luciferase reporter gene (fLuc:Zeo) linearly correlates with viable target cell number. Upon incubation of fLuc:Zeo(+) target cells with CD8(+) CTLs, a rapid decrease in bioluminescence was detected that correlated with antigen-specific target cell lysis.

Genetic engineering of cytolytic T lymphocytes for adoptive T-cell therapy of neuroblastoma.

Background: Disease relapse is the leading cause of mortality for children diagnosed with disseminated neuroblastoma. The adoptive transfer of tumor-specific T cells is an attractive approach to target minimal residual disease following conventional therapies. We describe here the genetic engineering of human cytotoxic T lymphocytes (CTL) to express a chimeric immunoreceptor for re-directed HLA-independent recognition of neuroblastoma.