Mapping paratopes of nanobodies using native mass spectrometry and ultraviolet photodissociation

In-Cell Mass Spectrometry and Ultraviolet Photodissociation Navigates the Intracellular Protein Heterogeneity

Directly probing the heterogeneous conformations of intracellular proteins within their native cellular environment remains a significant challenge in mass spectrometry (MS). Here, we establish an in-cell MS and ultraviolet photodissociation (UVPD) strategy that directly ejects proteins from living cells into a mass spectrometer, followed by 193 nm UVPD for structural analysis. Applying this approach to calmodulin (CaM), we reveal that it adopts more extended conformations within living cells compared with purified samples in vitro, highlighting the unique influence of intracellular environments on protein folding. Furthermore, UVPD analysis of calcium ion (Ca2+)-binding variants of CaM unveils not only the conformational heterogeneity induced by multiple Ca2+ modulations but also reveals distinct preferences of Ca2+ binding sites across different conformations. This strategy provides a powerful tool for interrogating the structure-function relationships of intracellular protein variants with sophisticated metal ion binding, paving the way for a deeper understanding of protein conformations within their native cellular context.

Development of Top-Down Mass Spectrometry Strategies in the Chromatographic Time Scale (LC-TD-MS) for the Extended Characterization of an Anti-EGFR Single-Domain Antibody-Drug Conjugate in Both Reduced and Nonreduced Forms

Even though mAbs have attracted the biggest interest in the development of therapeutic proteins, next-generation therapeutics such as single-domain antibodies (sdAb) are propelling increasing attention as new alternatives with appealing applications in different clinical areas. These constructs are small therapeutic proteins formed by a variable domain of the heavy chain of an antibody with multiple therapeutic and production benefits compared with their mAb counterparts. These proteins can be subjected to different bioconjugation processes to form single-domain antibody-drug conjugates (sdADCs) and hence increase their therapeutic potency, and akin to other therapeutic proteins, nanobodies and related products require dedicated analytical strategies to fully characterize their primary structure prior to their release to the market. In this study, we report for the first time the extensive sequence characterization of a conjugated anti-EGFR 14 kDa sdADC by using state-of-the-art top-down mass spectrometry strategies in combination with liquid chromatography (LC-TD-MS). Mass analysis revealed a highly homogeneous sample with one conjugated molecule. Subsequently, the reduced sdADC was submitted to different fragmentation techniques, namely, higher-energy collisional dissociation, electron-transfer dissociation, and electron-transfer higher-energy collision dissociation, allowing to unambiguously assess the conjugation site with 24 diagnostic fragment ions and 85% of global sequence coverage. The sequence coverage of the nonreduced protein was significantly lower (around 16%); however, the analysis of the fragmentation spectra corroborated the presence of the intramolecular disulfide bridge along with the localization of the conjugation site. Altogether, our results pinpoint the difficulties and challenges associated with the fragmentation of sdAb-derived formats in the LC time scale due to their remarkable stability as a consequence of the intramolecular disulfide bridge. However, the use of complementary activation techniques along with the identification of specific ion fragments allows an improved sequence coverage, the characterization of the intramolecular disulfide bond, and the unambiguous localization of the conjugation site.

Nanobodies: From High-Throughput Identification to Therapeutic Development

The camelid single-domain antibody fragment, commonly referred to as a nanobody, achieves the targeting power of conventional monoclonal antibodies (mAbs) at only a fraction of their size. Isolated from camelid species (including llamas, alpacas, and camels), their small size at ∼15 kDa, low structural complexity, and high stability compared with conventional antibodies have propelled nanobody technology into the limelight of biologic development. Nanobodies are proving themselves to be a potent complement to traditional mAb therapies, showing success in the treatment of, for example, autoimmune diseases and cancer, and more recently as therapeutic options to treat infectious diseases caused by rapidly evolving biological targets such as the SARS-CoV-2 virus. This review highlights the benefits of applying a proteomic approach to identify diverse nanobody sequences against a single antigen. This proteomic approach coupled with conventional yeast/phage display methods enables the production of highly diverse repertoires of nanobodies able to bind the vast epitope landscape of an antigen, with epitope sampling surpassing that of mAbs. Additionally, we aim to highlight recent findings illuminating the structural attributes of nanobodies that make them particularly amenable to comprehensive antigen sampling and to synergistic activity-underscoring the powerful advantage of acquiring a large, diverse nanobody repertoire against a single antigen. Lastly, we highlight the efforts being made in the clinical development of nanobodies, which have great potential as powerful diagnostic reagents and treatment options, especially when targeting infectious disease agents.

The role of venom proteomics and single-domain antibodies for antivenoms: Progress in snake envenoming treatment

Single-domain antibodies (sdAbs) hold promise for developing new biopharmaceuticals to treat neglected tropical diseases (NTDs), including snakebites, which are severe and occur frequently. In addition, limitations of conventional snakebite treatments, especially in terms of local action, and the global antivenom crisis incentivize the use of this biotechnological tool to design next-generation snakebite antivenoms. Conventional antivenoms for snakebite treatment are usually composed of immunoglobulin G or F(ab')2 fragments derived from the plasma of immunized animals. sdAbs, the smallest antigen-binding fragments, are derived from the variable domains of camelid heavy-chain antibodies. sdAbs may have some advantages over conventional antivenoms for local toxicity, such as better penetration into tissues due to their small size, and high solubility and affinity for venom antigens due to their unique antigen-binding loops and ability to access cryptic epitopes. We present an overview of current antivenom therapy in the context of sdAb development for toxin neutralization. Furthermore, strategies are presented for identifying snake venom's major toxins as well as for developing antisnake toxin sdAbs by employing proteomic tools for toxin neutralization.

Seeing the complete picture: proteins in top-down mass spectrometry

Top-down protein mass spectrometry can provide unique insights into protein sequence and structure, including precise proteoform identification and study of protein–ligand and protein–protein interactions. In contrast with the commonly applied bottom-up approach, top-down approaches do not include digestion of the protein of interest into small peptides, but instead rely on the ionization and subsequent fragmentation of intact proteins. As such, it is fundamentally the only way to fully characterize the composition of a proteoform. Here, we provide an overview of how a top-down protein mass spectrometry experiment is performed and point out recent applications from the literature to the reader. While some parts of the top-down workflow are broadly applicable, different research questions are best addressed with specific experimental designs. The most important divide is between studies that prioritize sequence information (i.e., proteoform identification) versus structural information (e.g., conformational studies, or mapping protein–protein or protein–ligand interactions). Another important consideration is whether to work under native or denaturing solution conditions, and the overall complexity of the sample also needs to be taken into account, as it determines whether (chromatographic) separation is required prior to MS analysis. In this review, we aim to provide enough information to support both newcomers and more experienced readers in the decision process of how to answer a potential research question most efficiently and to provide an overview of the methods that exist to answer these questions.