Abstract OR-3: Integrative Structural Study of the Complex of Snake Toxin WTX with α7-type Nicotinic Acetylcholine Receptor

Background: Nicotinic acetylcholine receptors are ligand-gated ion channels present in the nervous system, epithelium, and the immune system. The α7-type nicotinic receptor (α7-nAChR) is a homopentameric membrane protein containing five ligand binding sites located at the interface between subunits in the extracellular domain of the receptor. α7-nAChR is considered a promising target for the treatment of cancer and cognitive dysfunction in Alzheimer's disease, schizophrenia, and depression. WTX is a non-conventional three-finger neurotoxin from the Naja kaouthia venom inhibiting α7-nAChR. WTX structure consists of three loops protruding from the “head” (core) stabilized by a system of disulfide bonds. Methods: The complex of the α7-nAChR extracellular domain with a recombinant analogue of WTX was studied by cryo-electron microscopy. The structure of the complex of full-length α7-nAChR with the toxin in the membrane environment was reconstructed by in silico molecular modeling. Interaction of WTX with the lipid membrane was confirmed by NMR-spectroscopy. Results: Analysis of electronic images confirmed the homopentameric organization of the extracellular domain with a diameter of ~ 9 nm and a height of ~ 7 nm. On the electron density map, additional regions corresponding to five WTX molecules located at the intersubunit interfaces of the domain were observed. Fitting the known spatial structures of the extracellular domain and the WTX toxin into the obtained electron density made it possible to reconstruct the structure of the complex (although with a low resolution of ~ 8 Ǻ due to the predominant orientation of particles in the ice) and to determine the topology of the toxin-receptor interaction. It was revealed that WTX interacts with the extracellular domain of α7-nAChR by the loop II, while the loop I and the toxin’s head seem to interact with the surface of the lipid membrane surrounding the receptor. Model of the complex of the full-length α7-nAChR receptor with WTX in the membrane environment corresponding to the neuronal membrane was constructed using computer simulation methods. Molecular dynamics for >1500 ns confirmed the stability of the complex. The predicted membrane-active site of the WTX molecule includes residues Lys13 and Arg18. The study of WTX and its mutants Lys13Ala and Arg18Ala by NMR-spectroscopy confirmed the importance of these residues for interaction with lipid membrane. Conclusion: Interaction mode of non-conventional neurotoxins with nAChR has been determined for the first time

Structural Diversity and Dynamics of Human Three-Finger Proteins Acting on Nicotinic Acetylcholine Receptors

Ly-6/uPAR or three-finger proteins (TFPs) contain a disulfide-stabilized β-structural core and three protruding loops (fingers). In mammals, TFPs have been found in epithelium and the nervous, endocrine, reproductive, and immune systems. Here, using heteronuclear NMR, we determined the three-dimensional (3D) structure and backbone dynamics of the epithelial secreted protein SLURP-1 and soluble domains of GPI-anchored TFPs from the brain (Lynx2, Lypd6, Lypd6b) acting on nicotinic acetylcholine receptors (nAChRs). Results were compared with the data about human TFPs Lynx1 and SLURP-2 and snake α-neurotoxins WTX and NTII. Two different topologies of the β-structure were revealed: one large antiparallel β-sheet in Lypd6 and Lypd6b, and two β-sheets in other proteins. α-Helical segments were found in the loops I/III of Lynx2, Lypd6, and Lypd6b. Differences in the surface distribution of charged and hydrophobic groups indicated significant differences in a mode of TFPs/nAChR interactions. TFPs showed significant conformational plasticity: the loops were highly mobile at picosecond-nanosecond timescale, while the β-structural regions demonstrated microsecond-millisecond motions. SLURP-1 had the largest plasticity and characterized by the unordered loops II/III and cis-trans isomerization of the Tyr39-Pro40 bond. In conclusion, plasticity could be an important feature of TFPs adapting their structures for optimal interaction with the different conformational states of nAChRs

Sensitive Immunofluorescent Detection of the PRAME Antigen Using a Practical Antibody Conjugation Approach

Bioconjugation of antibodies with various payloads has diverse applications across various fields, including drug delivery and targeted imaging techniques. Fluorescent immunoconjugates provide a promising tool for cancer diagnostics due to their high brightness, specificity, stability and target affinity. Fluorescent antibodies are widely used in flow cytometry for fast and sensitive identification and collection of cells expressing the target surface antigen. Nonetheless, current approaches to fluorescent labeling of antibodies most often use random modification, along with a few rather sophisticated site-specific techniques. The aim of our work was to develop a procedure for fluorescent labeling of immunoglobulin G via periodate oxidation of antibody glycans, followed by oxime ligation with fluorescent oxyamines. Here, we report a novel technique based on an in situ oxime ligation of ethoxyethylidene-protected aminooxy compounds with oxidized antibody glycans. The approach is suitable for easy modification of any immunoglobulin G, while ensuring that antigen-binding domains remain intact, thus revealing various possibilities for fluorescent probe design. The technique was used to label an antibody to PRAME, a cancer-testis protein overexpressed in a number of cancers. A 6H8 monoclonal antibody to the PRAME protein was directly modified with protected-oxyamine derivatives of fluorescein-type dyes (FAM, Alexa488, BDP-FL); the stoichiometry of the resulting conjugates was characterized spectroscopically. The immunofluorescent conjugates obtained were applied to the analysis of bone marrow samples from patients with oncohematological diseases and demonstrated high efficiency in flow cytometry quantification. The approach can be applied for the development of various immunofluorescent probes for detection of diagnostic and prognostic markers, which can be useful in anticancer therapy