LAUSR

Natural killer (NK) cell-mediated antibody-dependent cellular cytotoxicity (ADCC) through CD16 plays a critical role in antihuman immunodeficiency virus (HIV) responses. CD300a is a surface receptor highly expressed on NK cells that has the capacity to inhibit NK cell-mediated cytotoxicity in healthy donors. The CD300a molecule has been related to several viral infections and is able to diminish the NK cell killing of pseudorabies-infected cells through interactions with its ligands phosphatidylserine and phosphatidylethanolamine. In addition, CD300a expression on B and CD4+ T lymphocytes is altered during HIV-1 infection, and combined antiretroviral therapy (cART) does not restore nonpathological expression levels. However, the expression and function of CD300a on NK cells during HIV-1 infection is still unknown. We have determined the surface expression of CD300a on different NK cell subsets and the capacity of this receptor to inhibit CD16-induced NK cell effector functions in healthy and HIV-1 infected individuals. As HIV-1 infection modulates CD300a expression on some immune cells, we first analyzed the expression of the CD300a receptor on different NK cell subpopulations from healthy donors, untreated HIV-1-infected subjects, and patients on cART by flow cytometry. The samples were provided by the HIV BioBank integrated in the Spanish AIDS Research Network (RIS) (see Supplementary Material). Clinical data from HIV-1-infected patients are shown in Table S1. Three different NK cell subsets were studied: CD56 (CD56NKp80), CD56 (CD56NKp80), and CD56 (CD56NKp80) (Fig. S1). When we examined the CD300a expression, no significant differences were observed between the groups, with the exception of CD56 NK cells, which displayed a higher frequency of CD300a+ cells in untreated HIV-1 infected patients (Fig. S2). Ongoing HIV replication induces the expansion of a dysfunctional CD56 NK cell subset (Fig. S1). Thus, we suggest that the overexpression of the CD300a inhibitory receptor on the CD56 NK cell subset may contribute to the dysfunctionality observed in this expanded population in HIV-1 infected patients, which is partially restored with cART. We also examined CD300a expression on different NK cell subsets selected according to the expression of NKG2A, NKG2C, CD57, and NKp46 (Fig. S3). These receptors are altered during HIV-1 infection, and some of them are commonly used to distinguish NK cell maturation stages. In general, we observed that different CD300a expression levels were associated with the expression of these markers in all subjects (Fig. S4). Specifically, higher CD300a expression was found on NKG2A+ CD56 NK cells, while CD57+ cells displayed lower CD300a expression levels (Fig. S4), indicating that CD300a is more expressed on immature CD56 NK cells, a cell subset that is significantly decreased in HIV-1 infected patients. NK cells express the FcγRIIIA (CD16) surface receptor, which is responsible for ADCC. To investigate the capacity of CD300a to inhibit CD16-mediated NK cell activation in HIV-1-infected patients, we performed a redirected lysis assay (Fig. S5). We cocultured NK cells with the Fc receptor-bearing cell line P815. CD16 and CD300a from NK cells were triggered with specific mAbs, and the MOPC-21 isotype control was utilized as a negative control (Fig. S5). To study NK cell effector functions, we determined the percentage of NK cells positive for the degranulation marker CD107a, the cytokines interferon (IFN)γ and tumor necrosis factor (TNF), and the chemokine macrophage inflammatory protein (MIP)-1β utilizing flow cytometry-based procedures (see Supplementary Material). In agreement with the literature, the CD56 NK cell subset displayed the highest response to CD16-mediated stimulation, and NK cell effector functions were significantly diminished in HIV1 infected patients (Fig. S6). Very importantly, we observed that all NK cell subsets from the three groups exhibited lower effector functions after the CD16-mediated stimulation and cross-linking of CD300a with specific mAbs (Fig. 1a, b). Moreover, when we compared the degranulation and MIP-1β production by different NK cell subsets, we observed that CD56 cells were the most inhibited subset after CD300a cross-linking in all donors (Fig. S7), consistent with the higher CD300a expression in this NK cell subpopulation (Fig. S2). Finally, we observed a higher CD300amediated inhibition of degranulation and MIP-1β production by CD56 and CD56 NK cells from HIV-1 infected patients, particularly from those who were under cART (Fig. 1c). ADCC has been demonstrated as an important factor for the longterm control of HIV-1 infection that subsequently results in better disease prognosis. Furthermore, the relevance of ADCC in new anti-HIV therapies has been emphasized with the introduction of broadly neutralizing antibodies. Nevertheless, decreased HIVspecific effector antibody responses have been found in HIV-1infected individuals, including those receiving cART. Our results