Engineering of a femtomolar affinity binding protein to human serum albumin

doi:10.1093/protein/gzn028

PEDS Advance Access published online on May 22, 2008
Protein Engineering Design and Selection, doi:10.1093/protein/gzn028

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Engineering of a femtomolar affinity binding protein to human serum albumin

Andreas Jonsson¹^,2, Jakob Dogan², Nina Herne¹, Lars Abrahmsén¹ and Per-Åke Nygren²^,3

¹ Affibody AB, Voltavägen 13, SE-161 02 Bromma ² Department of Molecular Biotechnology, Royal Institute of Technology (KTH), School of Biotechnology, Roslagstullsbacken 21, SE-106 91 Stockholm, Sweden

³ To whom correspondence should be addressed. E-mail: perake{at}biotech.kth.se (P-Å.N.)

We describe the development of a novel serum albumin bindingprotein showing an extremely high affinity (K_D) for HSA in thefemtomolar range. Using a naturally occurring 46-residue three-helixbundle albumin binding domain (ABD) of nanomolar affinity forHSA as template, 15 residues were targeted for a combinatorialprotein engineering strategy to identify variants showing improvedHSA affinities. Sequencing of 55 unique phage display-selectedclones showed a strong bias for wild-type residues at nine positions,whereas various changes were observed at other positions, includingcharge shifts. Additionally, a few non-designed substitutionsappeared. On the basis of the sequences of 12 variants showinghigh overall binding affinities and slow dissociation rate kinetics,a set of seven ‘second generation’ variants wereconstructed. One variant denoted ABD035 displaying wild-type-likesecondary structure content and excellent thermal denaturation/renaturationproperties showed an apparent affinity for HSA in the rangeof 50–500 fM, corresponding to several orders of magnitudeimprovement compared with the wild-type domain. The ABD035 variantalso showed an improved affinity toward serum albumin from anumber of other species, and a capture experiment involvinghuman serum indicated that the selectivity for serum albuminhad not been compromised from the affinity engineering.

Keywords: affinity/combinatorial protein engineering/femtomolar/human serum albumin/phage display

Received January 28, 2008; revised April 8, 2008; accepted April 19, 2008.

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