Conclusions
Our findings point to the role of Siglec-sialylated glycan interactions in hypoxic stress-induced NK cell dysfunction and recommend the potential integration of the manipulation of this axis through the targeting of Siglecs in future cancer immunotherapy strategies.
Methods
CD56⁺ CD3- NK cells were isolated from PBMCs along with an NK-92 clone and used as effector cells, while MCF-7 and K562 served as target cells. All cells were incubated under normoxic or hypoxic conditions for 24 h. To assess Siglec-7 and Siglec-9 receptor expression, U937, NK-92, and primary NK cells were stained with PE-labeled antibodies against CD328 Siglec-7/9. Interactions between Siglec-7/9 and their sialylated ligands, along with their functional impact on NK cell activity, were evaluated using polymeric nanoparticles coated with a sialic acid mimetic. Immunological synapse formation and live-cell imaging were performed with a ZEISS LSM 800 with Airyscan at 10× magnification for 24 h.
Results
Our data indicate that hypoxia had no effect on the expression of Siglec-7/9 receptors by NK cells. In contrast, hypoxic stress resulted in an increase in Siglec-7 sialoglycan ligand expression by a sub-population of NK target cells. Using polymeric nanoparticles coated with a sialic acid mimetic that binds both Siglec-7 and -9 (Sig-7/9 NP), we demonstrated that incubation of these nanoparticles with NK cells resulted in increased immunological synapse formation, granzyme B accumulation, and killing of NK target cells. These studies indicate that hypoxic stress may have an impact on NK cell-based therapies and highlight the need to consider the hypoxic microenvironment for tumor-specific glycosylation. Conclusions: Our findings point to the role of Siglec-sialylated glycan interactions in hypoxic stress-induced NK cell dysfunction and recommend the potential integration of the manipulation of this axis through the targeting of Siglecs in future cancer immunotherapy strategies.