In silico evaluation of the role of Fab glycosylation in cetuximab antibody dynamics.

Introduction: N-glycosylation is a post-translational modification that is highly important for the development of monoclonal antibodies (mAbs), as it regulates their biological activity, particularly in terms of immune effector functions. While typically added at the Fc level, approximately 15-25% of circulating antibodies exhibit glycosylation in the Fab domains as well. To the best of our knowledge, cetuximab (Erbitux®) is the only therapeutic antibody presenting Fab glycosylation approved world-wide targeting the epidermal growth factor receptor for the treatment of metastatic-colorectal and head and neck cancers. Additionally, it can trigger antibody-dependent cell cytotoxicity (ADCC), a response that typically is influenced by N-glycosylation at Fc level. However, the role of Fab glycosylation in cetuximab remains poorly understood. Hence, this study aims to investigate the structural role of Fab glycosylation on the conformational behavior of cetuximab. Methods: The study was performed in silico via accelerated molecular dynamics simulations. The commercial cetuximab was compared to its form without Fab glycosylation and structural descriptors were evaluated to establish conformational differences. Results: The results clearly show a correlation between the Fab glycosylation and structural descriptors that may modulate the conformational freedom of the antibody, potentially affecting Fc effector functions, and suggesting a negative role of Fab glycosylation on the interaction with FcγRIIIa. Conclusion: Fab glycosylation of cetuximab is the most critical challenge for biosimilar development, but the differences highlighted in this work with respect to its aglycosylated form can improve the knowledge and represent also a great opportunity to develop novel strategies of biotherapeutics.

Molecular Modeling of the Deamidation Reaction in Solution: A Theoretical-Computational Study.

In this work, a theoretical-computational method is applied to study the deamidation reaction, a critical post-translational modification in proteins, using a simple model molecule in solution. The method allows one to comprehensively address the environmental effect, thereby enabling one to accurately derive the kinetic rate constants for the three main steps of the deamidation process. The results presented, in rather good agreement with the available experimental data, underline the necessity for a rigorous treatment of environmental factors and a precise kinetic model to correctly assess the overall kinetics of the deamidation reaction.

Effect of Fc core fucosylation and light chain isotype on IgG1 flexibility.

N-glycosylation plays a key role in modulating the bioactivity of monoclonal antibodies (mAbs), as well as the light chain (LC) isotype can influence their physicochemical properties. However, investigating the impact of such features on mAbs conformational behavior is a big challenge, due to the very high flexibility of these biomolecules. In this work we investigate, by accelerated molecular dynamics (aMD), the conformational behavior of two commercial immunoglobulins G1 (IgG1), representative of κ and λ LCs antibodies, in both their fucosylated and afucosylated forms. Our results show, through the identification of a stable conformation, how the combination of fucosylation and LC isotype modulates the hinge behavior, the Fc conformation and the position of the glycan chains, all factors potentially affecting the binding to the FcγRs. This work also represents a technological enhancement in the conformational exploration of mAbs, making aMD a suitable approach to clarify experimental results.

Asn25 Deamidation as an Allosteric Tool to Increase IFNß-1a Biological Activity.

Interferon beta (IFNß) is a well-known cytokine, belonging to the type I family, that exerts antiviral, immunomodulatory, and antiproliferative activity. It has been reported that the artificially deamidated form of recombinant IFNß-1a at Asn25 position shows an increased biological activity. As a deepening of the previous study, the molecular mechanism underlying this biological effect was investigated in this work by combining experimental and computational techniques. Specifically, the binding to IFNAR1 and IFNAR2 receptors and the canonical pathway of artificially deamidated IFNß-1a molecule were analyzed in comparison to the native form. As a result, a change in receptor affinity of deamidated IFNß-1a with respect to the native form was observed, and to better explore this molecular interaction, molecular dynamics simulations were carried out. Results confirmed, as previously hypothesized, that the N25D mutation can locally change the interaction network of the mutated residue but also that this effect can be propagated throughout the molecule. In fact, many residues not involved in the interaction with IFNAR1 in the native form participate to the recognition in the deamidated molecule, enhancing the binding to IFNAR1 receptor and consequently an increase of signaling cascade activation. In particular, a higher STAT1 phosphorylation and interferon-stimulated gene expression was observed under deamidated IFNß-1a cell treatment. In conclusion, this study increases the scientific knowledge of deamidated IFNß-1a, deciphering its molecular mechanism, and opens new perspectives to novel therapeutic strategies.

IgG1 conformational behavior: elucidation of the N-glycosylation role via molecular dynamics.

Currently, monoclonal antibodies (mAbs) are the most used biopharmaceuticals for human therapy. One of the key aspects in their development is the control of effector functions mediated by the interaction between fragment crystallizable (Fc) and Fcγ receptors, which is a secondary mechanism of the action of biotherapeutics. N-glycosylation at the Fc portion can regulate these mechanisms, and much experimental evidence suggests that modifications of glycosidic chains can affect antibody binding to FcγRIIIa, consequently impacting the immune response. In this work, we try to elucidate via in silico procedures the structural role exhibited by glycans, particularly fucose, in mAb conformational freedom that can potentially affect the receptor recognition. By using adalimumab, a marketed IgG1, as a general template, after rebuilding its three-dimensional (3D) structure through homology modeling approaches, we carried out molecular dynamics simulations of three differently glycosylated species: aglycosylated, afucosylated, and fucosylated antibody. Trajectory analysis showed different dynamical behaviors and pointed out that sugars can influence the overall 3D structure of the antibody. As a result, we propose a putative structural mechanism by which the presence of fucose introduces conformational constraints in the whole antibody and not only in the Fc domain, preventing a conformation suitable for the interaction with the receptor. As secondary evidence, we observed a high flexibility of the antibodies that is translated into an asymmetric behavior of Fab portions shown by all the simulated biopolymers, making the dynamical asymmetry a new, to our knowledge, molecular aspect that may be further investigated. In conclusion, these findings can help understand the contribution of sugars on the structural architecture of mAbs, paving the way to novel strategies of pharmaceutical development.

[Corrigendum] TOOLBOX: Strep­Tagged nano­assemblies of antibody­drug­conjugates (ADC) for modular and conditional cancer drugging.

Following the publication of the above article, the authors have requested a change in the authorship on the paper, and the revised list of authors is presented above; essentially, the ninth intended author, Giuseppe Salvo (G.S.), was inadverently omitted from the author list. G.S. contributed towards the T design and the preparation of the tagged ScFv. Therefore, the revised authors' names and affiliations, as they should have been presented in the original version of this paper, are as follows: Elisa Tremante1, Leonardo Sibilio2,7, Fabio Centola2,8, Nadine Knutti3,9, Gerd Holzapfel4, Isabella Manni5, Matteo Allegretti1, Paolo Lombardi6, Giuseppe Salvo2,10, Loredana Cecchetelli2, Karlheinz Friedrich3, Joachim BertraM4 and Patrizio Giacomini1. 1Oncogenomics and Epigenetics, IRCCS Regina Elena National Cancer Institute, Rome; 2Ibi Lorenzini, Aprilia, Italy; 3University Hospital Jena, Institute of Biochemistry II, Jena; 4IBA GmbH, Göttingen, Germany; 5SAFU, IRCCS Regina Elena National Cancer Institute, Rome; 6NaxosPharma, Novate Milanese, Milan, Italy. Correspondence to: Dr Patrizio Giacomini. Oncogenomics and Epigenetics, IRCCS Regina Elena National Cancer Institute, Via Elio Chianesi 53, 00144 Rome, Italy. E­mail: patrizio.giacomini@ifo.gov.it. Present address: 7Menarini Biotech, Pomezia, Rome, Italy. Present address: 8Merck Serono Spa, Global Analytical Department, Guidonia Montecelio, Rome, Italy. Present address: 9University Hospital Jena Institute for Clinical Chemistry and Laboratory Diagnostics, Jena, Germany. Present address: 10External Quality Assurance (ExM), MSD Italia S.r.l., Via Vitorchiano 151, 00189 Rome.Italy. Furthermore, the Authors' contributions section should be amended to read as follows: Authors' contributions: ET and MA tested the TOOLBOX concept and performed the flow cytometry experiments. LS, FC, GS and LC designed and prepared the tagged ScFv. NK and KF designed and prepared the GFP promoter­reporter construct. GH and JB designed and manufactured Strep­Tactins. ET and IM performed animal studies. PL designed and manufactured NAX and NAXT compounds. PG conceptualized TOOLBOX and wrote the manuscript with the contribution of all authors. All authors have approved the final version of the manuscript. All the authors agree with the inclusion of Giuseppe Salvo as an author on this paper, and are grateful to the Editor for allowing them the opportunity to publish this Corrigendum. Furthermore, they apologize to the readership of the Journal for any inconvenience caused. [the original article was published in Oncology Reports 45: 77, 2021; DOI: 10.3892/or.2021.8028].

TOOLBOX: Strep­Tagged nano­assemblies of antibody­drug­conjugates (ADC) for modular and conditional cancer drugging

Herein, we describe TOOLBOX, a 3­step modular nano­assembly targeting system that permits the combinatorial exchange of antibody specificities and toxic payloads, introducing modularity in antibody­drug conjugate (ADC) manufacturing. TOOLBOX integrates 3 building blocks: i) a recombinant antibody fragment (that in the selected setting targets the proto­oncogene ERBB2) genetically fused to an 8 amino acid Strep­Tag®; ii) a multivalent protein adapter, called Strep­Tactin®; iii) two anticancer agents, e.g. DNA nanobinders and the maytansinoid DM1, both carrying a chemically attached Strep­Tag that reversibly turns them into inactive prodrugs. Stoichiometrically optimized complexes of Strep­Tagged antibody fragments and drugs, bridged by Strep­Tactin, were specifically uptaken by breast cancer cells expressing ERBB2, and this unexpectedly resulted in conditional prodrug reactivation. A promoter­reporter system showed that TOOLBOX inhibited downstream ERBB2 signaling not only in ERBB2­overexpressing/­amplified SK­BR­3 cells grown in vitro, but also in ERBB2­low/non­amplified BRC230 triple­negative breast carcinoma cells xenotransplanted in nude mice. Thus, TOOLBOX is a modular ADC­like nano­assembly platform for precision oncology.

Bloch Surface Waves Biosensors for High Sensitivity Detection of Soluble ERBB2 in a Complex Biological Environment.

We report on the use of one-dimensional photonic crystals to detect clinically relevant concentrations of the cancer biomarker ERBB2 in cell lysates. Overexpression of the ERBB2 protein is associated with aggressive breast cancer subtypes. To detect soluble ERBB2, we developed an optical set-up which operates in both label-free and fluorescence modes. The detection approach makes use of a sandwich assay, in which the one-dimensional photonic crystals sustaining Bloch surface waves are modified with monoclonal antibodies, in order to guarantee high specificity during the biological recognition. We present the results of exemplary protein G based label-free assays in complex biological matrices, reaching an estimated limit of detection of 0.5 ng/mL. On-chip and chip-to-chip variability of the results is addressed too, providing repeatability rates. Moreover, results on fluorescence operation demonstrate the capability to perform high sensitive cancer biomarker assays reaching a resolution of 0.6 ng/mL, without protein G assistance. The resolution obtained in both modes meets international guidelines and recommendations (15 ng/mL) for ERBB2 quantification assays, providing an alternative tool to phenotype and diagnose molecular cancer subtypes.

Heme d1 nitrosyl complex of cd1 nitrite reductase studied by high-field-pulse electron paramagnetic resonance spectroscopy.

W-band (95 GHz) HYSCORE and pulse ENDOR are used to characterize the nitrosyl d(1) heme complex (d(1)NO) of cd(1) nitrite reductase from Pseudomonas aeruginosa in the wild type and the Y10F mutant. The spectra and the derived (14)N hyperfine and quadrupole interactions were found to be the same for wt and Y10F. This suggests that Tyr10 does not influence the NO ligand orientation in the reduced state in solution. This study is the first application of HYSCORE at high fields and shows its potential for characterizing low gamma nuclei with large hyperfine couplings.

Critical role of His369 in the reactivity of Pseudomonas aeruginosa cytochrome cd1 nitrite reductase with oxygen.

In the denitrification pathway, Pseudomonas aeruginosa cytochrome cd1 nitrite reductase catalyzes the reduction of nitrite to nitric oxide; in vitro, this enzyme is also competent in the reduction of O2 to 2H2O. In this article, we present a comparative kinetic study of the O2 reaction in the wild-type nitrite reductase and in three site-directed mutants (Tyr10-->Phe, His369-->Ala and His327-->Ala/His369-->Ala) of the amino acid residues close to the d1 heme on the distal side. The results clearly indicate that His369 is the key residue in the control of reactivity, as its substitution with Ala, previously shown to affect the reduction of nitrite, also impairs the reaction with O2, affecting both the properties and lifespan of the intermediate species. Our findings allow the presentation of an overall picture for the reactivity of cytochrome cd1 nitrite reductase and extend our previous conclusion that the conserved distal histidines are essential for the binding to reduced d1 heme of different anions, whether a substrate such as nitrite, a ligand such as cyanide, or an intermediate in the O2 reduction. Moreover, we propose that His369 also exerts a protective role against degradation of the d1 heme, by preventing the formation and adverse effects of the reactive O2 species (never present in significant amounts in wild-type cytochrome cd1 nitrite reductase), a finding with clear physiological implications.

NO production by Pseudomonas aeruginosa cd1 nitrite reductase.

The structural and catalytic properties of Pseudomonas aeruginosa cd1 nitrite reductase, a key enzyme in bacterial denitrification, are reviewed in this paper. The mechanism of reduction of nitrite to NO is discussed in detail with special attention to the structural interpretation of function. The ability to stabilize negatively charged molecules, such as the substrate (nitrite) and other ligands (hydroxide and cyanide), is a key feature of catalysis in cd1NIRs. The positive potential in the active site is largely due to the presence of the two conserved distal histidines, which are involved in both substrate binding and product release.