Development Of Single-domain Antibodies Research Articles

Design and Construction of Antibody Fusion Proteins Incorporating Variable New Antigen Receptor (VNAR) Domains.

Antibody therapeutics have become a cornerstone of the pharmaceutical market due to their precise molecular targeting, favorable pharmacokinetic properties, and multitiered mechanisms of action. Since the first monoclonal antibody was clinically approved 35years ago, there have been considerable advances in antibody technology. A major breakthrough has been the design of multispecific antibodies and antibody fusion proteins, which introduce the possibility of recognizing two or more targets with a single molecule. However, despite tremendous progress in the antibody engineering field, challenges in formulation, stability, and tissue penetration necessitate the design of novel antibody formats with improved pharmaceutical properties. There is a growing interest in development of single-domain antibodies, which harbor advantages such as high solubility, robust thermostability, and unique geometries that allow for access to cryptic epitopes. Chondrichthyes such as sharks and rays provide a source of single-domain antibody fragments known as variable new antigen receptors (VNARs), which have been exploited as molecular targeting agents. Here, we describe methods to engineer antibody fusion proteins that incorporate VNARs. We present multiple fusion topologies, and detail the design, expression, and purification for each format. These novel antibody fusion proteins hold great promise for a range of applications in biomedical research and therapeutic design.

Structure and development of single domain antibodies as modules for therapeutics and diagnostics.

Since their discovery just over 25 years ago, the single variable domain from heavy-chain-only antibodies plays a role in an increasing number of antibody-based applications. Structural and biophysical studies have revealed that the small, ∼15 kDa, single variable domain found in camelids displays versatility in target recognition. Such insight has served as the foundation to develop and engineer VHH domains with enhanced properties capable of targeting a range of therapeutically relevant protein antigens or low-molecular weight haptens. Furthermore, the modular nature of VHH domains allows them to be introduced into constructs that are simply not possible with conventional antibodies. Here, we review the structural and biophysical properties of VHH domains, highlight recent VHH-based therapeutics and diagnostics, and provide insight into VHH engineering that may pave the way to next-generation single domain antibody applications.Impact statementThe development of novel antibody formats, beyond conventional antibodies, opens new possibilities in medical therapies, diagnostics, and general life science applications requiring affinity reagents. The camelid VHH domain, from heavy-chain-only antibodies, has emerged as a jack-of-all-trades module for novel affinity reagents. Applications include targeted cancer therapies, novel antimicrobial agents, conformation specific reagents, and tailor-made molecular switch entities. The breadth of unique uses for the VHH will continue to grow, opening new opportunities to treat and understand disease.

Nanobody Engineering: Toward Next Generation Immunotherapies and Immunoimaging of Cancer.

In the last decade, cancer immunotherapies have produced impressive therapeutic results. However, the potency of immunotherapy is tightly linked to immune cell infiltration within the tumor and varies from patient to patient. Thus, it is becoming increasingly important to monitor and modulate the tumor immune infiltrate for an efficient diagnosis and therapy. Various bispecific approaches are being developed to favor immune cell infiltration through specific tumor targeting. The discovery of antibodies devoid of light chains in camelids has spurred the development of single domain antibodies (also called VHH or nanobody), allowing for an increased diversity of multispecific and/or multivalent formats of relatively small sizes endowed with high tissue penetration. The small size of nanobodies is also an asset leading to high contrasts for non-invasive imaging. The approval of the first therapeutic nanobody directed against the von Willebrand factor for the treatment of acquired thrombotic thrombocypenic purpura (Caplacizumab, Ablynx), is expected to bolster the rise of these innovative molecules. In this review, we discuss the latest advances in the development of nanobodies and nanobody-derived molecules for use in cancer immunotherapy and immunoimaging.

Physicochemical improvement of rabbit derived single-domain antibodies by substitutions with amino acids conserved in camelid antibodies

Recently, we showed that immunized rabbit heavy chain variable regions (rVHs) can have strong antigen binding activity comparable to that of the camelid variable domain of the heavy chain of heavy chain antibody (VHH). These rVHs lack the light chain variable regions (rVLs), which exist in the authentic Fab format; thus, molecular surfaces at the interface region of rVHs are exposed to solvent. This physical feature may change physicochemical properties, such as causing reduced stability. By overcoming potential physicochemical issues through engineering the interface region, rVHs could become more useful as single-domain antibodies. In this study, we substituted amino acid residues conserved at the interface region of rVHs with those of VHHs. These substitutions included V37F, involving substitution of a residue in the hydrophobic core with a bulkier hydrophobic amino acid, and G44E/L45R, involving double substitutions of highly exposed residues with more hydrophilic ones. As expected, biophysical and structural characterizations showed that the V37F substitution markedly enhanced the thermal stability through increased hydrophobic packing, while G44E/L45R substitutions greatly reduced hydrophobicity of the interface. The quadruple substitutions of V37F/G44E/L45R/F91Y resulted in not only enhancements of thermal stability and reduction in hydrophobicity, both in an additive manner, but also synergistic improvement of purification yield. This quadruple mutant exhibited greatly reduced non-specific binding with improved colloidal stability owing to the reduced hydrophobicity. The approach used in this study should further enhance the utility of rVHs and promote research and development of single-domain antibodies.