Lidia Mosyak

Three-Dimensional Structure and Biophysical Characterization of Staphylococcus aureus Cell Surface Antigen–Manganese Transporter MntC

MntC is a metal-binding protein component of the Mn²⁺-specific mntABC transporter from the pathogen Staphylococcus aureus. The protein is expressed during the early stages of infection and was proven to be effective at reducing both S. aureus and Staphylococcus epidermidis infections in a murine animal model when used as a vaccine antigen. MntC is currently being tested in human clinical trials as a component of a multiantigen vaccine for the prevention of S. aureus infections. To better understand the biological function of MntC, we are providing structural and biophysical characterization of the protein in this work. The three-dimensional structure of the protein was solved by X-ray crystallography at 2.2Å resolution and suggests two potential metal binding modes, which may lead to reversible as well as irreversible metal binding. Precise Mn²⁺-binding affinity of the protein was determined from the isothermal titration calorimetry experiments using a competition approach. Differential scanning calorimetry experiments confirmed that divalent metals can indeed bind to MntC reversibly as well as irreversibly. Finally, Mn²⁺-induced structural and dynamics changes have been characterized using spectroscopic methods and deuterium-hydrogen exchange mass spectroscopy. Results of the experiments show that these changes are minimal and are largely restricted to the structural elements involved in metal coordination. Therefore, it is unlikely that antibody binding to this antigen will be affected by the occupancy of the metal-binding site by Mn²⁺.

Structure-based design of carboxybiphenylindole inhibitors of the ZipA–FtsZ interaction

Structural features of two weak inhibitors of the ZipA-FtsZ protein-protein interaction which were found to bind to overlapping but different areas of the key binding site were combined in one new series of carboxybiphenyl-indoles with improved inhibitory activity.

Crystal Structure of A Human IκB Kinase β Asymmetric Dimer

Background: IκB kinase β is a key regulator in the NκB signaling pathway. Results: Crystal structure of a human IKKβ asymmetric dimer shows one kinase active site phosphorylated and in the active conformation and the other unphosphorylated and inactive. Conclusion: Depending on the phosphorylation state, IKKβ can adopt distinct dimeric geometry. Significance: High resolution structure of hIKKβ provides structural basis for its activation and potential use of inhibitor design. Phosphorylation of inhibitor of nuclear transcription factor κB (IκB) by IκB kinase (IKK) triggers the degradation of IκB and migration of cytoplasmic κB to the nucleus where it promotes the transcription of its target genes. Activation of IKK is achieved by phosphorylation of its main subunit, IKKβ, at the activation loop sites. Here, we report the 2.8 Å resolution crystal structure of human IKKβ (hIKKβ), which is partially phosphorylated and bound to the staurosporine analog K252a. The hIKKβ protomer adopts a trimodular structure that closely resembles that from Xenopus laevis (xIKKβ): an N-terminal kinase domain (KD), a central ubiquitin-like domain (ULD), and a C-terminal scaffold/dimerization domain (SDD). Although hIKKβ and xIKKβ utilize a similar dimerization mode, their overall geometries are distinct. In contrast to the structure resembling closed shears reported previously for xIKKβ, hIKKβ exists as an open asymmetric dimer in which the two KDs are further apart, with one in an active and the other in an inactive conformation. Dimer interactions are limited to the C-terminal six-helix bundle that acts as a hinge between the two subunits. The observed domain movements in the structures of IKKβ may represent trans-phosphorylation steps that accompany IKKβ activation.

Atypical Antigen Recognition Mode of a Shark Immunoglobulin New Antigen Receptor (IgNAR) Variable Domain Characterized by Humanization and Structural Analysis

Background: Single domain variable regions of shark antibodies (V-NARs) are promising biotherapeutic candidates. Results: A V-NAR specific for human serum albumin was humanized, and its crystal structure in complex with the antigen was solved, revealing an unusual recognition mode. Conclusion: Humanization preserved antigen binding properties and activity of the parental shark antibody. Significance: A structural framework for humanization of shark antibodies was established. The immunoglobulin new antigen receptors (IgNARs) are a class of Ig-like molecules of the shark immune system that exist as heavy chain-only homodimers and bind antigens by their single domain variable regions (V-NARs). Following shark immunization and/or in vitro selection, V-NARs can be generated as soluble, stable, and specific high affinity monomeric binding proteins of ∼12 kDa. We have previously isolated a V-NAR from an immunized spiny dogfish shark, named E06, that binds specifically and with high affinity to human, mouse, and rat serum albumins. Humanization of E06 was carried out by converting over 60% of non-complementarity-determining region residues to those of a human germ line Vκ1 sequence, DPK9. The resulting huE06 molecules have largely retained the specificity and affinity of antigen binding of the parental V-NAR. Crystal structures of the shark E06 and its humanized variant (huE06 v1.1) in complex with human serum albumin (HSA) were determined at 3- and 2.3-Å resolution, respectively. The huE06 v1.1 molecule retained all but one amino acid residues involved in the binding site for HSA. Structural analysis of these V-NARs has revealed an unusual variable domain-antigen interaction. E06 interacts with HSA in an atypical mode that utilizes extensive framework contacts in addition to complementarity-determining regions that has not been seen previously in V-NARs. On the basis of the structure, the roles of various elements of the molecule are described with respect to antigen binding and V-NAR stability. This information broadens the general understanding of antigen recognition and provides a framework for further design and humanization of shark IgNARs.

Engineering novel Lec1 glycosylation mutants in CHO-DUKX cells: molecular insights and effector modulation of N-acetylglucosaminyltransferase I.

Many secreted or cell surface proteins are post‐translationally modified by carbohydrate chains which are a primary source of heterogeneity. The Lec1 mutant, which is defective in Golgi N‐acetylglucosaminyltransferase I (GnTI) activity, produces relatively homogeneous Man5GlcNAc2 glycan modifications, and is widely used for various applications. To facilitate the investigation of GnTI, its Man5 glycan endproduct, and the impact of Man5 on effector function, the present study has established several novel Lec1 mutants in dhfr− CHO–DUKX cells through chemical mutagenesis and lectin selection. A total of nine clonal lines exhibiting the Lec1‐phenotype are characterized, six of which harbor non‐sense mutations leading to a truncated GnTI, and three (R415K, D291N, and P138L) of which are novel loss‐of‐function sense mutations. Analysis of the rabbit GnTI structure (Unligil et al., 2000 ) indicates that D291 is the proposed catalytic base and R415 is a crucial residue in forming the substrate binding pocket, whereas P138 is key to maintaining two β strands in proximity to the substrate binding pocket. Computational modeling reveals that the oligomannose glycan backbone of a glycoprotein (the acceptor substrate) fits nicely into the unoccupied channel of the substrate binding pocket partly through hydrogen bonding with R415 and D291. This finding is consistent with the ordered sequential Bi Bi kinetic mechanism suggested for GnTI, in which binding of UDP–GlcNAc (the donor substrate)/Mn2+ induces conformational changes that promote acceptor binding. When an anti‐human CD20 antibody protein is stably expressed in one CHO–DUKX–Lec1 line, it is confirmed that N‐glycans are predominantly Man5GlcNAc2 and they do not contain an α1,6‐fucose linked to the innermost GlcNAc. Furthermore, this Man5GlcNAc2 modified antibody exhibits a significantly increased ADCC activity than the wild‐type protein, while displaying a lower CDC activity. The data support the hypothesis that modulating GnTI activity can influence antibody effector functions for proteins with an IgG1 immunoglobulin Fc domain. Biotechnol. Bioeng. 2012; 109:1723–1734.

Engineering a Monomeric Fc Domain Modality by N-Glycosylation for the Half-life Extension of Biotherapeutics

Background: The bivalency of IgG and Fc fusion could cause undesired therapeutic properties. Results: We developed a stable monomeric Fc modality by N-glycosylation engineering, enabling the generation of crystal structure. Conclusion: The monomeric Fc prolonged the half-life of Fab domain through the interaction with neonatal Fc receptor. Significance: The monomeric Fc will be used for pharmacokinetics enhancement of biotherapeutics that require monovalent properties. Human IgG is a bivalent molecule that has two identical Fab domains connected by a dimeric Fc domain. For therapeutic purposes, however, the bivalency of IgG and Fc fusion proteins could cause undesired properties. We therefore engineered the conversion of the natural dimeric Fc domain to a highly soluble monomer by introducing two Asn-linked glycans onto the hydrophobic CH3-CH3 dimer interface. The monomeric Fc (monoFc) maintained the binding affinity for neonatal Fc receptor (FcRn) in a pH-dependent manner. We solved the crystal structure of monoFc, which explains how the carbohydrates can stabilize the protein surface and provides the rationale for molecular recognition between monoFc and FcRn. The monoFc prolonged the in vivo half-life of an antibody Fab domain, and a tandem repeat of the monoFc further prolonged the half-life. This monoFc modality can be used to improve the pharmacokinetics of monomeric therapeutic proteins with an option to modulate the degree of half-life extension.

High Resolution Mapping of Bactericidal Monoclonal Antibody Binding Epitopes on Staphylococcus aureus Antigen MntC.

The Staphylococcus aureus manganese transporter protein MntC is under investigation as a component of a prophylactic S.aureus vaccine. Passive immunization with monoclonal antibodies mAB 305-78-7 and mAB 305-101-8 produced using MntC was shown to significantly reduce S. aureus burden in an infant rat model of infection. Earlier interference mapping suggested that a total of 23 monoclonal antibodies generated against MntC could be subdivided into three interference groups, representing three independent immunogenic regions. In the current work binding epitopes for selected representatives of each of these interference groups (mAB 305-72-5 – group 1, mAB 305-78-7 – group 2, and mAB 305-101-8 – group 3) were mapped using Hydrogen-Deuterium Exchange Mass Spectrometry (DXMS). All of the identified epitopes are discontinuous, with binding surface formed by structural elements that are separated within the primary sequence of the protein but adjacent in the context of the three-dimensional structure. The approach was validated by co-crystallizing the Fab fragment of one of the antibodies (mAB 305-78-7) with MntC and solving the three-dimensional structure of the complex. X-ray results themselves and localization of the mAB 305-78-7 epitope were further validated using antibody binding experiments with MntC variants containing substitutions of key amino acid residues. These results provided insight into the antigenic properties of MntC and how these properties may play a role in protecting the hostagainst S. aureus infection by preventing the capture and transport of Mn2+, a key element that the pathogen uses to evade host immunity.