Simulated microgravity disarms human NK-cells and inhibits anti-tumor cytotoxicity in vitro

Abstract

Long-duration spaceflight impairs natural killer (NK) cell function, which could compromise immune surveillance in exploration class mission crew. To determine if microgravity can impair NK-cell function, we established a rotary cell culture system to expose human peripheral blood mononuclear cells to simulated microgravity (SMG) in vitro. We found that 12 h of SMG suppressed NK-cell cytotoxic activity (NKCA) by similar to 50% against K562, U266 and 721.221 tumor target cells when returned to the 1G environment. Mass cytometry was used to identify 37 individual markers associated with NK-cell activation, maturation and cytotoxicity, revealing that SMG causes reductions in NK-cell degranulation and effector cytokine production. Extended flow cytometry confirmed that SMG lowered NK cell perforin and granzyme b expression by 25% and 17% respectively, but did not affect the surface expression of various activating (NKG2D, NKp30) and inhibitory (NKG2A, KLRG1) receptors or the ability of NK-cells to conjugate with target cells. Flow cytometry further revealed that SMG impaired NK-cell degranulation (reduced CD107a+ expression) and suppressed TNF alpha and IFN gamma secretion in response to stimulation with K562 target cells. These findings indicate that SMG 'disarms' human NK-cells of cytolytic granules and impairs NKCA against a range of tumor target cells in vitro. Exposure to microgravity could be a factor that contributes to impaired NK-cell function during long duration space travel.