Exploiting sequence and stability information for directing nanobody stability engineering

• Published in: Biochimica et biophysica acta Vol. 1861; no. 9; pp. 2196 - 2205
• Main Authors: Kunz, Patrick, Flock, Tilman, Soler, Nicolas, Zaiss, Moritz, Vincke, Cécile, Sterckx, Yann, Kastelic, Damjana, Muyldermans, Serge, Hoheisel, Jörg D.
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.09.2017
• Subjects: aggregation behavior; Amino Acid Sequence; amino acids; antibodies; Camelidae; chemical elements; diagnostic techniques; engineering; mutation; prediction; Protein Aggregates; Protein aggregation; Protein Conformation; Protein design; Protein Engineering; Protein Stability; proteinases; proteins; Single-Domain Antibodies - chemistry; Single-domain antibody (sdAb, nanobody); therapeutics; thermal stability; Protein engineering; CD; Protein aggregation; GSS algorithm; HM; Protein stability; Single-domain antibody (sdAb, nanobody); GdmCl; CDR; VH; Protein design; DSF; VL; VHH; MSA
• ISSN: 0304-4165; 0006-3002; 1872-8006; 1878-2434
• DOI: 10.1016/j.bbagen.2017.06.014

Variable domains of camelid heavy-chain antibodies, commonly named nanobodies, have high biotechnological potential. In view of their broad range of applications in research, diagnostics and therapy, engineering their stability is of particular interest. One important aspect is the improvement of thermostability, because it can have immediate effects on conformational stability, protease resistance and aggregation propensity of the protein. We analyzed the sequences and thermostabilities of 78 purified nanobody binders. From this data, potentially stabilizing amino acid variations were identified and studied experimentally. Some mutations improved the stability of nanobodies by up to 6.1°C, with an average of 2.3°C across eight modified nanobodies. The stabilizing mechanism involves an improvement of both conformational stability and aggregation behavior, explaining the variable degree of stabilization in individual molecules. In some instances, variations predicted to be stabilizing actually led to thermal destabilization of the proteins. The reasons for this contradiction between prediction and experiment were investigated. The results reveal a mutational strategy to improve the biophysical behavior of nanobody binders and indicate a species-specificity of nanobody architecture. This study illustrates the potential and limitations of engineering nanobody thermostability by merging sequence information with stability data, an aspect that is becoming increasingly important with the recent development of high-throughput biophysical methods. •Nanobody thermostability is engineered combining sequence and stability information.•The mechanism of stabilization improves stability and aggregation behavior.•A species-specificity of nanobody architecture is proposed.