Assessment of the antiviral capacity of primary natural killer cells by optimized in vitro quantification of HIV-1 replication.

Despite a growing number of studies investigating the impact of natural killer (NK) cells on HIV-1 pathogenesis, the exact mechanism by which NK cells recognize HIV-1-infected cells and exert immunological pressure on HIV-1 remains unknown. Previously several groups including ours have introduced autologous HIV-1-infected CD4(+) T cells as suitable target cells to study NK-cell function in response to HIV-1 infection in vitro. Here, we re-evaluated and optimized a standardized in vitro assay that allows assessing the antiviral capacity of NK cells. This includes the implementation of HIV-1 RNA copy numbers as readout for NK-cell-mediated inhibition of HIV-1 replication and the investigation of inter-assay variation in comparison to previous methods, such as HIV-1 p24 Gag production and frequency of p24(+) CD4(+) T cells. Furthermore, we investigated the possibility to hasten the duration of the assay and provide concepts for downstream applications. Autologous CD4(+) T cells and NK cells were obtained from peripheral blood of HIV-negative healthy individuals and were separately enriched through negative selection. CD4(+) T cells were infected with the HIV-1 strain JR-CSF at an MOI of 0.01. Infected CD4(+) T cells were then co-cultured with primary NK cells at various effector:target ratios for up to 14days. Supernatants obtained from media exchanged at days 4, 7, 11 and 14 were used for quantification of HIV-1 p24 Gag and HIV-1 RNA copy numbers. In addition, frequency of infected CD4(+) T cells was determined by flow cytometric detection of intracellular p24 Gag. The assay displayed minimal inter-assay variation when utilizing viral RNA quantification or p24 Gag concentration for the assessment of viral replication. Viral RNA quantification was more rigorous to display magnitude and kinetics of NK-cell-mediated inhibition of HIV-1 replication, longitudinally and between tested individuals. The results of this study demonstrate that NK-cell-mediated inhibition of HIV-1 replication can be reliably quantified in vitro, and that viral RNA quantification is comparable to p24 Gag quantification via ELISA, providing a robust measurement for NK-cell-mediated inhibition of viral replication. Overall, the described assay provides an optimized tool to study the antiviral capacity of NK cells against HIV-1 and an additional experimental tool to investigate the molecular determinants of NK-cell recognition of virus-infected cells.

Increased frequency and function of KIR2DL1-3⁺ NK cells in primary HIV-1 infection are determined by HLA-C group haplotypes.

The acquisition and maintenance of NK-cell function is mediated by inhibitory killer-cell immunoglobulin-like receptors (KIRs) through their interaction with HLA class I molecules. Recently, HLA-C expression levels were shown to be correlated with protection against multiple outcomes of HIV-1 infection; however, the underlying mechanisms are poorly understood. As HLA-C is the natural ligand for the inhibitory receptors KIR2DL1 and KIR2DL2/3, we sought to determine whether HLA-C group haplotypes affect NK-cell responses during primary HIV-1 infection. The phenotypes and functional capacity of NK cells derived from HIV-1-positive and HIV-1-negative individuals were assessed (N = 42 and N = 40, respectively). HIV-1 infection was associated with an increased frequency of KIR2DL1-3(+) NK cells. Further analysis showed that KIR2DL1(+) NK cells were selectively increased in individuals homozygous for HLA-C2, while HLA-C1-homozygous individuals displayed increased proportions of KIR2DL2/3(+) NK cells. KIR2DL1-3(+) NK cells were furthermore more polyfunctional during primary HIV-1 infection in individuals also encoding for their cognate HLA-C group haplotypes, as measured by degranulation and IFN-γ and TNF-α production. These results identify a novel relationship between HLA-C and KIR2DL(+) NK-cell subsets and demonstrate that HLA-C-mediated licensing modulates NK-cell responses to primary HIV-1 infection.

Use of the novel technique of analytical ultracentrifugation with fluorescence detection system identifies a 77S monosomal translation complex.

A fundamental problem in proteomics is the identification of protein complexes and their components. We have used analytical ultracentrifugation with a fluorescence detection system (AU-FDS) to precisely and rapidly identify translation complexes in the yeast Saccharomyces cerevisiae. Following a one-step affinity purification of either poly(A)-binding protein (PAB1) or the large ribosomal subunit protein RPL25A in conjunction with GFP-tagged yeast proteins/RNAs, we have detected a 77S translation complex that contains the 80S ribosome, mRNA, and components of the closed-loop structure, eIF4E, eIF4G, and PAB1. This 77S structure, not readily observed previously, is consistent with the monosomal translation complex. The 77S complex abundance decreased with translational defects and following the stress of glucose deprivation that causes translational stoppage. By quantitating the abundance of the 77S complex in response to different stress conditions that block translation initiation, we observed that the stress of glucose deprivation affected translation initiation primarily by operating through a pathway involving the mRNA cap binding protein eIF4E whereas amino acid deprivation, as previously known, acted through the 43S complex. High salt conditions (1M KCl) and robust heat shock acted at other steps. The presumed sites of translational blockage caused by these stresses coincided with the types of stress granules, if any, which are subsequently formed.