Abstract
In the particular case of the Camelidae family, immunoglobulin proteins have evolved into a unique and more simplified architecture with only heavy chains. The variable domains of these chains, named VHHs, have a number of Complementary Determining Regions (CDRs) reduced by half, and can function as single domains making them good candidates for molecular tools. 3D structure prediction of these domains is a beneficial and advantageous step to advance their developability as molecular tools. Nonetheless, the conformations of CDRs loops in these domains remain difficult to predict due to their higher conformational diversity. In addition to CDRs loop diversity, our earlier study has established that Framework Regions (FRs) are also not entirely conformationally conserved which establishes a need for more rigorous analyses of these regions that could assist in template selection. In the current study, VHHs models using different template selection strategies for comparative modeling using Modeller have been extensively assessed. This study analyses the conformational changes in both CDRs and FRs using an original strategy of conformational discretization based on a structural alphabet. Conformational sampling in selected cases is precisely reported. Some interesting outcomes of the structural analyses of models also draw attention towards the distinct difficulty in 3D structure prediction of VHH domains.
Highlights
Immunoglobulins or antibodies are crucial proteins of the immune system in jawed vertebrates
Amongst the large family of immunoglobulin, immunoglobulin gamma (IgG) has been extensively analyzed, as it is more abundant compared to the rest of the isoforms
This study addresses the problem of the impact of template conformations on the VHH domain modeling, especially when using single and multi-templates
Summary
Immunoglobulins or antibodies are crucial proteins of the immune system in jawed vertebrates The rest of the sequence is organized into successive conserved domains (CL in light chain and CH1, CH2, CH3, etc., in the heavy chain). The CDRs exhibit the largest variability in terms of sequence, length, and composition of amino acids, resulting in conformational variability. This large diversity explains the ability of the antibodies to recognize a large number of epitopes. Due to their sensitivity and specificity to bind specific antigens, antibodies have become useful molecules for biotechnological and pharmaceuticals development [2]. 3D structure prediction of antibody structure is of crucial importance for the development of applications
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