An evolutionarily conserved charged residue dictates the specificity of heterophilic interactions among nectins.

Nectins are a family of four cell surface glycoproteins belonging to the immunoglobulin superfamily that mediate cell-cell adhesion and associated signalling pathways, thereby regulating several physiological processes including morphogenesis, growth and development of multicellular organisms. Nectins interact among themselves through their extracellular domains from the adjacent cells in both homophilic and heterophilic fashions to support cell-cell adhesion. Although nectins form homodimers as demonstrated in experimental set-ups, only the specific heterophilic interactions among nectins are physiologically relevant as shown by in vivo studies. It has been hypothesised that a conserved charged residue present at the binding interface acts as the molecular switch for heterophilic nectin-nectin recognitions. In this work, we have analysed the energetics of homophilic and heterophilic interactions of nectins, followed by surface plasmon resonance-based binding studies and complementary in silico analyses. Our findings confirm that the conserved charged residues at the binding interfaces dictate the specificity of the nectin-nectin heterophilic interactions. Furthermore, these residues also play a role in conferring higher affinity to the heterophilic interactions, thereby making them physiologically more prevalent compared to homophilic interactions. Thus, this work reveals the molecular basis of heterophilic recognitions among nectins that contribute to their physiological functions.

Tailoring Uptake Efficacy of HSV-1 gD Derived Carrier Peptides.

Regions of the Herpes simplex virus-1 (HSV-1) glycoprotein D (gD) were chosen to design carrier peptides based on the known tertiary structure of the virus entry receptor complexes. These complexes consist of the following: HSV-1 gD-nectin-1 and HSV-1 gD-herpesvirus entry mediator (HVEM). Three sets of peptides were synthesised with sequences covering the (i) N-terminal HVEM- and nectin-1 binding region -5-42, (ii) the 181-216 medium region containing nectin-1 binding sequences and (iii) the C-terminal nectin-1 binding region 214-255. The carrier candidates were prepared with acetylated and 5(6)-carboxyfluorescein labelled N-termini. The peptides were chemically characterised and their conformational features in solution were also determined. In vitro internalisation profile and intracellular localisation were evaluated on SH-SY5Y neuroblastoma cells. Peptide originated from the C-terminal region 224-247 of the HSV-1 gD showed remarkable internalisation compared to the other peptides with low to moderate entry. Electronic circular dichroism secondary structure studies of the peptides revealed that the most effectively internalised peptides exhibit high helical propensity at increasing TFE concentrations. We proved that oligopeptides derived from the nectin-1 binding region are promising candidates-with possibility of Lys237Arg and/or Trp241Phe substitutions-for side-reaction free conjugation of bioactive compounds-drugs or gene therapy agents-as cargos.

Interaction between nectin-1 and the human natural killer cell receptor CD96.

Regulation of Natural Killer (NK) cell activity is achieved by the integration of both activating and inhibitory signals acquired at the immunological synapse with potential target cells. NK cells express paired receptors from the immunoglobulin family which share common ligands from the nectin family of adhesion molecules. The activating receptor CD226 (DNAM-1) binds to nectin-2 and CD155, which are also recognized by the inhibitory receptor TIGIT. The third receptor in this family is CD96, which is less well characterized and may have different functions in human and mouse models. Human CD96 interacts with CD155 and ligation of this receptor activates NK cells, while in mice the presence of CD96 correlates with decreased NK cell activation. Mouse CD96 also binds nectin-1, but the effect of this interaction has not yet been determined. Here we show that human nectin-1 directly interacts with CD96 in vitro. The binding site for CD96 is located on the nectin-1 V-domain, which comprises a canonical interface that is shared by nectins to promote cell adhesion. The affinity of nectin-1 for CD96 is lower than for other nectins such as nectin-3 and nectin-1 itself. However, the affinity of nectin-1 for CD96 is similar to its affinity for herpes simplex virus glycoprotein D (HSV gD), which binds the nectin-1 V-domain during virus entry. The affinity of human CD96 for nectin-1 is lower than for its known activating ligand CD155. We also found that human erythroleukemia K562 cells, which are commonly used as susceptible targets to assess NK cell cytotoxicity did not express nectin-1 on their surface and were resistant to HSV infection. When expressed in K562 cells, nectin-1-GFP accumulated at cell contacts and allowed HSV entry. Furthermore, overexpression of nectin-1-GFP led to an increased susceptibility of K562 cells to NK-92 cell cytotoxicity.

Molecular and structural bases of interaction between extracellular domains of nectin-2 and N-cadherin.

Cell adhesion molecules such as nectins and cadherins play important role in the formation of adherens junction. While nectins interact through their extracellular domains in both homophilic and heterophilic manner among themselves, extracellular domains of cadherins participate only in homophilic fashion to mediate cell-cell adhesion. It is well established that nectins recruit cadherins in the adhesion sites through an interplay of adaptor molecules in the cytoplasmic side thereby increasing the effective concentration of both the adhesion molecules on the cell surface. This study provides molecular and structural bases of the novel interaction between extracellular domains of nectin-2 and N-cadherin, by which nectins can also recruit cadherins at the site of adherens junction through an adaptor-independent mechanism. Surface plasmon resonance study demonstrates that nectin-2 can directly recognize N-cadherin with a KD of 3.5 ± 0.6 µM which is physiologically relevant considering the affinities between other cell adhesion molecules including cadherin dimerization. Furthermore, structural analysis of currently available homodimeric structures of both nectin-2 and N-cadherin followed by molecular docking as well as complementary mutagenesis studies revealed the binding interface of this novel interaction.

Structural basis of nectin-1 recognition by pseudorabies virus glycoprotein D.

An early and yet indispensable step in the alphaherpesvirus infection is the engagement of host receptors by the viral envelope glycoprotein D (gD). Of the thus-far identified gD receptors, nectin-1 is likely the most effective in terms of its wide usage by multiple alphaherpesviruses for cell entry. The molecular basis of nectin-1 recognition by the gD protein is therefore an interesting scientific question in the alphaherpesvirus field. Previous studies focused on the herpes simplex virus (HSV) of the Simplexvirus genus, for which both the free gD structure and the gD/nectin-1 complex structure were reported at high resolutions. The structural and functional features of other alphaherpesviral gDs, however, remain poorly characterized. In the current study, we systematically studied the characteristics of nectin-1 binding by the gD of a Varicellovirus genus member, the pseudorabies virus (PRV). We first showed that PRV infects host cells via both human and swine nectin-1, and that its gD exhibits similar binding affinities for nectin-1 of the two species. Furthermore, we demonstrated that removal of the PRV gD membrane-proximal residues could significantly increase its affinity for the receptor binding. The structures of PRV gD in the free and the nectin-1-bound states were then solved, revealing a similar overall 3D fold as well as a homologous nectin-1 binding mode to its HSV counterpart. However, several unique features were observed at the binding interface of PRV gD, enabling the viral ligand to utilize different gD residues (from those of HSV) for nectin-1 engagement. These observed binding characteristics were further verified by the mutagenesis study using the key-residue mutants of nectin-1. The structural and functional data obtained in this study, therefore, provide the basis of receptor recognition by PRV gD.

Nectins and nectin-like molecules (Necls): Recent findings and their role and regulation in spermatogenesis.

Nectins and nectin-like molecules (Necls) belong to Ca2+-independent immunoglobulin superfamily of cell adhesion molecules and they are ubiquitously expressed in most tissues. They not only interact in trans-homo and trans-hetero with others, but also interact in cis with growth factor receptors and integrins. Owning to these properties, nectins and Necls exert their role far beyond cell-cell adhesion. Nectins and Necls are crucial for various cellular processes not limited to cell movement, cell proliferation and polarization. They are involved in organogenesis and developmental processes such as spermatogenesis. This review aims to provide an overview and highlight some recent findings on nectins and Necls in the field with emphasis on studies in the testis, upon which future studies can be designed to delineate the role and regulation of nectins and Necls in spermatogenesis.