Reconstitution of a ligand-binding competent murine NKp30 receptor.

The activating natural cytotoxicity receptors on natural killer (NK) cells play a fundamental role in immunosurveillance of infections and cancer. Phylogenetic analyses showed that NKp30 is highly conserved in almost all jawed vertebrates and thus, represents one of the most ancient NK cell receptors. However, in contrast to other higher vertebrates, NKp30 is only a pseudogene in mouse, which contains two premature stop codons. To decipher the evolutionary role and biological function of NKp30 in mouse, we removed these premature stop codons and expressed the putative mouse NKp30 (mNKp30) protein as soluble Fc fusion construct and as full-length receptor on A5-GFP reporter cells. Interestingly, even though both NKp30 variants were expressed, maturation and targeting to the plasma membrane were impaired. Previous studies implicated that N-linked glycosylation is crucial for plasma membrane targeting and ligand binding of human NKp30. However, even though present in all other jawed vertebrates analyzed so far, these three N-linked glycosylation sites are missing in mouse NKp30. Interestingly, reconstitution of N-linked glycosylation enabled secretion of a mNKp30-Fc fusion protein which recognized a yet unknown ligand on the plasma membrane of mastocytoma cells. Based on these data, our study is the first to show expression and functional analysis of a mNKp30 protein suggesting that the mouse NKp30 pseudogene is the result of a species-specific loss of function.

The Stalk Domain of NKp30 Contributes to Ligand Binding and Signaling of a Preassembled NKp30-CD3ζ Complex.

The natural cytotoxicity receptor (NCR) NKp30 (CD337) is a key player for NK cell immunosurveillance of infections and cancer. The molecular details of ligand recognition and its connection to CD3ζ signaling remain unsolved. Here, we show that the stalk domain (129KEHPQLGAGTVLLLR143) of NKp30 is very sensitive to sequence alterations, as mutations lead to impaired ligand binding and/or signaling capacity. Surprisingly, the stalk domains of NKp30 and NKp46, another NCR employing CD3ζ for signaling, were not exchangeable without drastic deficiencies in folding, plasma membrane targeting, and/or ligand-induced receptor signaling. Further mutational studies, N-glycosylation mapping, and plasma membrane targeting studies in the absence and presence of CD3ζ suggest two interconvertible types of NCR-CD3ζ assemblies: 1) a signaling incompetent structural NKp30-CD3ζ complex and 2) a ligand-induced signaling competent NKp30-CD3ζ complex. Moreover, we propose that ligand binding triggers translocation of Arg-143 from the membrane interface into the membrane to enable alignment with oppositely charged aspartate residues within CD3ζ and activation of CD3ζ-signaling.

Natural Killer Group 2D Ligand Depletion Reconstitutes Natural Killer Cell Immunosurveillance of Head and Neck Squamous Cell Carcinoma.

Head and neck squamous cell carcinoma (HNSCC) is a highly heterogeneous and aggressive tumor originating from the epithelial lining of the upper aero-digestive tract accounting for 300,000 annual deaths worldwide due to failure of current therapies. The natural killer group 2D (NKG2D) receptors on natural killer (NK) cells and several T cell subsets play an important role for immunosurveillance of HNSCC and are thus targeted by tumor immune evasion strategies in particular by shedding of various NKG2D ligands (NKG2DLs). Based on plasma and tumor samples of 44 HNSCC patients, we found that despite compositional heterogeneity the total plasma level of NKG2DLs correlates with NK cell inhibition and disease progression. Strikingly, based on tumor spheroids and primary tumors of HNSCC patients, we found that NK cells failed to infiltrate HNSCC tumors in the presence of high levels of NKG2DLs, demonstrating a novel mechanism of NKG2DL-dependent tumor immune escape. Therefore, the diagnostic acquisition of the plasma level of all NKG2DLs might be instrumental for prognosis and to decipher a patient cohort, which could benefit from restoration of NKG2D-dependent tumor immunosurveillance. Along these lines, we could show that removal of shed NKG2DLs (sNKG2DLs) from HNSCC patients' plasma restored NK cell function in vitro and in individual patients following surgical removal of the primary tumor. In order to translate these findings into a therapeutic setting, we performed a proof-of-concept study to test the efficacy of adsorption apheresis of sNKG2DLs from plasma after infusion of human MICA in rhesus monkeys. Complete removal of MICA was achieved after three plasma volume exchanges. Therefore, we propose adsorption apheresis of sNKG2DLs as a future preconditioning strategy to improve the efficacy of autologous and adoptively transferred immune cells in cellular cancer immunotherapy.