THE CHARACTERIZATION OF T-CELL MANUFACTURING FOR ADOPTIVE T-CELL THERAPIES

Adoptive T-cell therapy using genetically modified T cells has emerged as a potential therapeutic option for several malignancies. Central to the production of the cellular therapy is the manufacturing using a stimulation, genetic engineering, and expansion methodology. Within this framework, there is a delicate balance between expansion of the cells to a therapeutically relevant dosage and the need to retain the proliferative potential of the ‘living drug’. I show that as T-cells are expanded for elongated periods of time, they lose their proliferative potential and become functionally senescent despite the presence of multiple proliferative cytokines. In addition, I show that expression of CD28 correlates with multiple manufacturing metrics, including final T-cell fold expansion. I propose that the loss of CD28 expression creates a T-cell expansion bottleneck in which certain T-cell clones are heavily favored compared to others during manufacturing. Compounding the multiple correlations, I performed a meta-analysis of available clinical trial data to show that younger patients appear to respond better to T-cell manufacturing involving CD28 costimulation, while older patients appear to respond better to T-cell manufacturing lacking CD28 costimulation

Very rapid cloning, expression and identifying specificity of T-cell receptors for T-cell engineering.

Neoantigens can be predicted and in some cases identified using the data obtained from the whole exome sequencing and transcriptome sequencing of tumor cells. These sequencing data can be coupled with single-cell RNA sequencing for the direct interrogation of the transcriptome, surfaceome, and pairing of αβ T-cell receptors (TCRαβ) from hundreds of single T cells. Using these 2 large datasets, we established a platform for identifying antigens recognized by TCRαβs obtained from single T cells. Our approach is based on the rapid expression of cloned TCRαβ genes as Sleeping Beauty transposons and the determination of the introduced TCRαβs' antigen specificity and avidity using a reporter cell line. The platform enables the very rapid identification of tumor-reactive TCRs for the bioengineering of T cells with redirected specificity