Oligomeric Architecture of Mouse Activating Nkrp1 Receptors on Living Cells.

Mouse activating Nkrp1 proteins are commonly described as type II transmembrane receptors with disulfide-linked homodimeric structure. Their function and the manner in which Nkrp1 proteins of mouse strain (C57BL/6) oligomerize are still poorly understood. To assess the oligomerization state of Nkrp1 proteins, mouse activating EGFP-Nkrp1s were expressed in mammalian lymphoid cells and their oligomerization evaluated by Förster resonance energy transfer (FRET). Alternatively, Nkrp1s oligomers were detected by Western blotting to specify the ratio between monomeric and dimeric forms. We also performed structural characterization of recombinant ectodomains of activating Nkrp1 receptors. Nkrp1 isoforms c1, c2 and f were expressed prevalently as homodimers, whereas the Nkrp1a displays larger proportion of monomers on the cell surface. Cysteine-to-serine mutants revealed the importance of all stalk cysteines for protein dimerization in living cells with a major influence of cysteine at position 74 in two Nkrp1 protein isoforms. Our results represent a new insight into the oligomerization of Nkrp1 receptors on lymphoid cells, which will help to determine their function.

Solution structure of the lymphocyte receptor Nkrp1a reveals a distinct conformation of the long loop region as compared to in the crystal structure.

Mouse Nkrp1a receptor is a C-type lectin-like receptor expressed on the surface of natural killer cells that play an important role against virally infected and tumor cells. The recently solved crystal structure of Nkrp1a raises questions about a long loop region which was uniquely extended from the central region in the crystal. To understand the functional significance of the loop, the solution structure of Nkrp1a using nuclear magnetic resonance (NMR) spectroscopy was determined. A notable difference between the crystal and NMR structure of Nkrp1a appears in the conformation of the long loop region. While the extended loop points away from the central core and mediates formation of a domain swapped dimer in the crystal, the solution structure is monomeric with the loop tightly anchored to the central region. The findings described the first solution structure in the Nkrp1 family and revealed intriguing similarities and differences to the crystal structure. Proteins 2016; 84:1304-1311. © 2016 Wiley Periodicals, Inc.

Enzymatic synthesis of dimeric glycomimetic ligands of NK cell activation receptors.

This work reveals new structural relationships in the complex process of the interaction between activation receptors of natural killer cells (rat NKR-P1, human CD69) and novel bivalent carbohydrate glycomimetics. The length, glycosylation pattern and linker structure of receptor ligands were examined with respect to their ability to precipitate the receptor protein from solution, which simulates the in vivo process of receptor aggregation during NK cell activation. It was found that di-LacdiNAc triazole compounds show optimal performance, reaching up to 100% precipitation of the present protein receptors, and achieving high immunostimulatory activities without any tendency to trigger activation-induced apoptosis. In the synthesis of the compounds tested, two enzymatic approaches were applied. Whereas a ß-N-acetylhexosaminidase could only glycosylate one of the two acceptor sites available with yields below 10%, the Y284L mutant of human placental ß1,4-galactosyltransferase-1 worked as a perfect synthetic tool, accomplishing even quantitative glycosylation at both acceptor sites and with absolute regioselectivity for the C-4 position. This work insinuates new directions for further ligand structure optimisation and demonstrates the strong synthetic potential of the mutant human placental ß1,4-galactosyltransferase-1 in the synthesis of multivalent glycomimetics and glycomaterials.

Synthesis of multivalent glycoconjugates containing the immunoactive LELTE peptide: effect of glycosylation on cellular activation and natural killing by human peripheral blood mononuclear cells.

Pentapeptide diacidic sequence LELTE, derived from the mycobacterial heat shock protein hsp65, has been recently identified as a "danger" signal of the immune system effective via specific binding to the universal leukocyte triggering receptor CD69. This sequence is not active per se, only after its presentation within the multivalent environment of its parent protein, or after artificial dimerization using a standard bifunctional reagents. Here we describe an entirely new way of presenting of this peptide based on its attachment to a cyclopeptide RAFT scaffold (K-K-K-P-G)(2) through the epsilon-amino group of lysine residues, alone or in combination with the carbohydrate epitope alphaGalNAc. The ability of such RAFT scaffolds to precipitate the target CD69 receptor or to activate CD69-positive cells is enhanced in compounds 2 and 4 possessing combined peptide/carbohydrate expression. Compounds 2 and 4 are highly efficient activators of natural killer lymphocytes, but they are completely inactive from the point of view of activation-induced apoptosis of lymphocytes by the target cells. These unique properties make the combined peptide/carbohydrate RAFTs highly suitable for future evaluation in animal tumor therapies in vivo and predict them to be readily available and efficient immunoactivators.

Carboxylated calixarenes bind strongly to CD69 and protect CD69(+) killer cells from suicidal cell death induced by tumor cell surface ligands.

We have recently identified a new class of high affinity ligands for CD69 leukocyte membrane receptor, carboxylated calixarenes. Of the three compounds investigated here, thiacalix[4]arene had the highest affinity for CD69 in direct binding assays, and proved to be the most specific inhibitor of CD69 identified so far in receptor precipitation and cellular activation experiments. Carboxylated calixarenes also proved effective at protection of CD69(high) lymphocytes from apoptosis triggered by a multivalent ligand or antibody. Thus, carboxylated calixarenes set a new paradigm for noncarbohydrate ligands for CD69 making them attractive for protection of killer cells in combined animal tumor therapies.