Abstract
The immunoglobulin (Ig) constant CH2 domain is critical for antibody effector functions. Isolated CH2 domains are promising scaffolds for construction of libraries containing diverse binders that could also confer some effector functions. We have shown previously that an isolated human CH2 domain is relatively unstable to thermally induced unfolding, but its stability can be improved by engineering an additional disulfide bond (Gong, R., Vu, B. K., Feng, Y., Prieto, D. A., Dyba, M. A., Walsh, J. D., Prabakaran, P., Veenstra, T. D., Tarasov, S. G., Ishima, R., and Dimitrov, D. S. (2009) J. Biol. Chem. 284, 14203-14210). We have hypothesized that the stability of this engineered antibody domain could be further increased by removing unstructured residues. To test our hypothesis, we removed the seven N-terminal residues that are in a random coil as suggested by our analysis of the isolated CH2 crystal structure and NMR data. The resulting shortened engineered CH2 (m01s) was highly soluble, monomeric, and remarkably stable, with a melting temperature (T(m)) of 82.6 °C, which is about 10 and 30 °C higher than those of the original stabilized CH2 (m01) and CH2, respectively. m01s and m01 were more resistant to protease digestion than CH2. A newly identified anti-CH2 antibody that recognizes a conformational epitope bound to m01s significantly better (>10-fold higher affinity) than to CH2 and slightly better than to m01. m01s bound to a recombinant soluble human neonatal Fc receptor at pH 6.0 more strongly than CH2. These data suggest that shortening the m01 N terminus significantly increases stability without disrupting its conformation and that our approach for increasing stability and decreasing size by removing unstructured regions may also apply to other proteins.
Highlights
Rui Gong‡, Yanping Wang‡§, Yang Feng‡, Qi Zhao‡, and Dimiter S
We have shown previously that an isolated human CH2 domain is relatively unstable to thermally induced unfolding, but its stability can be improved by engineering an additional disulfide bond
We have proposed that the CH2 domain (CH2 of IgG, IgA, and IgD and CH3 of IgE and IgM) could be used as a scaffold and could offer additional advantages compared with engineered antibody domains based on other domains because it contains binding sites or portions of binding sites conferring effector and stability functions [7]
Summary
It bound to m01s significantly better (Ͼ10-fold higher affinity) than to CH2 and slightly better than to m01. On the basis of these data, we suggest that m01s could be used as a scaffold for development of engineered antibody domains. These results demonstrate for the first time that the stability of constant antibody domains can be further increased by decreasing their size. Shortening the m01 N terminus significantly increases stability, it retains or increases some other properties of CH2 (e.g. binding to shFcRn). It may apply to other proteins as a method to increase stability and decrease size
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