Thermal Unfolding of a Llama Antibody Fragment: A Two-State Reversible Process

Abstract

Camelids produce functional “heavy chain” antibodies which are devoid of light chains and CH1 domains [Hamers-Casterman, C., et al. (1993) Nature 363, 446−448]. It has been shown that the variable domains of these heavy chain antibodies (the V_HH fragments) are functional at or after exposure to high temperatures, in contrast to conventional antibodies [Linden van der, R. H. J., et al. (1999) Biochim. Biophys. Acta 1431, 37−44]. For a detailed understanding of the higher thermostability of these V_HH fragments, knowledge of their structure and conformational dynamics is required. As a first step toward this goal, we report here the essentially complete ¹H and ¹⁵N NMR backbone resonance assignments of a llama V_HH antibody fragment, and an extensive analysis of the structure at higher temperatures. The H−D exchange NMR data at 300 K indicate that the framework of the llama V_HH fragment is highly protected with a ΔG_ex of >5.4 kcal/mol, while more flexibility is observed for surface residues, particularly in the loops and the two outer strands (residues 4−7, 10−13, and 58−60) of the β-sheet. The CD data indicate a reversible, two-state unfolding mechanism with a melting transition at 333 K and a ΔH_m of 56 kcal/mol. H−D exchange studies using NMR and ESI-MS show that below 313 K exchange occurs through local unfolding events whereas above 333 K exchange mainly occurs through global unfolding. The lack of a stable core at high temperatures, observed for V_HH fragments, has also been observed for conventional antibody fragments. The main distinction between the llama V_HH fragment and conventional antibody fragments is the reversibility of the thermal unfolding process, explaining its retained functionality after exposure to high temperatures.