Combined Genetic Ablation of CD54 and CD58 in CAR Engineered Cytotoxic Lymphocytes Effectively Averts Allogeneic Immune Cell Rejection

Allogeneic cell therapies hold promise to be cost effective with scaled manufacturing for multi-dosing and on-demand off-the-shelf availability. A critical consideration for allogeneic cell products is their ability to persist, maintain function and avoid rejection by the patient's immune system. Genetic knockout (KO) of beta-2-microglobulin (B2M) leads to complete loss of cell-surface human leukocyte antigen (HLA) class I expression and efficiently abrogates CD8+ T-cell reactivity. However, loss of HLA class I triggers NK cell-mediated missing-self recognition and manipulation of B2M must therefore be combined with other immune-modulating strategies to limit recipient NK cell reactivity.We hypothesized that rejection by the patient's immune system can be diminished in primary CAR T cells, iPSC-derived T (iT) and NK (iNK) cells by reverse-engineering common tumor escape mechanisms. The adhesion molecules CD54 and CD58 are both present at the target cell side of the immune synapse, and loss of either of these molecules have previously been reported to elicit immune escape. Here, we show that the combined deletion of CD54 and CD58 in allogeneic immune effector cells makes them resistant to rejection by recipient immune cells through unidirectional reduced synapse formation (Figure 1A).HLA class I down-regulation by B2M silencing in primary T and NK cells triggered potent cytotoxicity by resting allogeneic NK cells. This response was mostly driven by educated NK cells expressing either NKG2A or killer cell immunoglobulin-like receptors (KIR) binding to HLA-E and HLA-C, respectively. However, over-expression of HLA-E or single HLA-C ligands in a K562 screening model only shut down the specific response of the NK cell subset carrying the cognate inhibitory receptor, resulting in only partial resistance to NK cells at the bulk level. Notably, the introduction of HLA-E was particularly detrimental in donors with expanded NKG2C+ NK cell subsets, due to its stimulatory effec
QC 20230316