RESUMO
Plasma membranes of living cells are compartmentalized into small submicroscopic structures (nanodomains) having potentially relevant biological functions. Despite this, structural features of these nanodomains remain elusive, primarily due to the difficulties in characterizing such small dynamic entities. It is unclear whether nanodomains found in the upper bilayer leaflet are transversally registered with those found in the lower leaflet. Experiments performed on larger microscopic domains indicate that the coupling between the leaflets is strong, forcing the domains to be in perfect registration, but can the same thing be said about the biologically more relevant nanodomains? This work provides experimental evidence that even small nanodomains of variable sizes between 10 and 160 nm are interleaflet coupled. Importantly, the alternative scenarios of partially registered, independent, or antiregistered nanodomains could be excluded.
RESUMO
The cytotoxicity of mouse natural killer (NK) cells in response to pathological changes in target cells is regulated via the Nkrp1b receptor. Here, we characterized the Nkrp1b structure and structural features (stalk, loop, and oligomerization state) that affect its interactions. To study the Nkrp1b protein structure and the functional importance of its stalk, two Nkrp1b protein variants differing by the presence of the stalk were prepared. These variants were studied using a combination of structural mass spectrometry approaches with computational modeling to derive structural models. In addition, information about biological activity and localization in mammalian cells was acquired using scanning microscopy techniques and western blotting. Based on these methods, we obtained the structure of Nkrp1b ectodomain in its monomeric and dimeric conformations, identified the dimerization interface, and determined disulfide connections within the molecule. We found that Nkrp1b occurs as a mixture of monomers and homodimers, both in vitro and in vivo. SIGNIFICANCE: Despite the long-standing assumption that Nkrp1 proteins are homodimers connected by disulfide bonds in the stalk region, our data showed that both Nkrp1b protein variants form monomers and homodimers irrespective of the presence of the stalk. We demonstrated that the stalk is not crucial for protein dimerization or ligand binding and that Nkrp1b interacts with its natural ligands only in its monomeric conformation; therefore, dimers may have another regulatory function. Using a unique combination of computational, biochemical, and biological methods, we revealed the structural conformation and behavior of Nkrp1b in its native state. In addition, it is a first report utilizing the intermolecular chemical cross-linking of light- and heavy-labeled protein chains together with ion mobility-mass spectrometry to design the structural models of protein homodimers.