Cell-penetrating Alphabody protein scaffolds for intracellular drug targeting.

The therapeutic scope of antibody and nonantibody protein scaffolds is still prohibitively limited against intracellular drug targets. Here, we demonstrate that the Alphabody scaffold can be engineered into a cell-penetrating protein antagonist against induced myeloid leukemia cell differentiation protein MCL-1, an intracellular target in cancer, by grafting the critical B-cell lymphoma 2 homology 3 helix of MCL-1 onto the Alphabody and tagging the scaffold's termini with designed cell-penetration polypeptides. Introduction of an albumin-binding moiety extended the serum half-life of the engineered Alphabody to therapeutically relevant levels, and administration thereof in mouse tumor xenografts based on myeloma cell lines reduced tumor burden. Crystal structures of such a designed Alphabody in complex with MCL-1 and serum albumin provided the structural blueprint of the applied design principles. Collectively, we provide proof of concept for the use of Alphabodies against intracellular disease mediators, which, to date, have remained in the realm of small-molecule therapeutics.

Structural basis of IL-23 antagonism by an Alphabody protein scaffold.

Protein scaffolds can provide a promising alternative to antibodies for various biomedical and biotechnological applications, including therapeutics. Here we describe the design and development of the Alphabody, a protein scaffold featuring a single-chain antiparallel triple-helix coiled-coil fold. We report affinity-matured Alphabodies with favourable physicochemical properties that can specifically neutralize human interleukin (IL)-23, a pivotal therapeutic target in autoimmune inflammatory diseases such as psoriasis and multiple sclerosis. The crystal structure of human IL-23 in complex with an affinity-matured Alphabody reveals how the variable interhelical groove of the scaffold uniquely targets a large epitope on the p19 subunit of IL-23 to harness fully the hydrophobic and hydrogen-bonding potential of tryptophan and tyrosine residues contributed by p19 and the Alphabody, respectively. Thus, Alphabodies are suitable for targeting protein-protein interfaces of therapeutic importance and can be tailored to interrogate desired design and binding-mode principles via efficient selection and affinity-maturation strategies.

Structural characterisation of the hepatitis C envelope glycoprotein E1 ectodomain derived from a mammalian and a yeast expression system.

The structure of the ectodomain of the hepatitis C envelope glycoprotein E1 (E1s) was characterised by spectroscopic methods. Monomeric E1s was purified from a mammalian and from a Hansenula polymorpha cell lysate, and cysteine-blocked monomers were reconstituted into stable particles. Particles from yeast E1s and mammalian E1s showed a comparable reactivity in ELISA with sera from human chronic HCV carriers, similar antibody titers in the sera of immunised mice as well as a comparable structure as analyzed by spectroscopic methods (tryptophan fluorescence, circular dichroism, and Fourier transform infrared spectroscopy). The overall secondary structure of E1s was neither influenced by the degree of glycosylation nor by the nature of cysteine modification used during purification. The structural comparability of mammalian- and H. polymorpha-expressed E1s opens new perspectives for further development of E1s-based therapeutics as yeast systems generally allow a more easy scaling up.