Affilin

Structure

Two proteins, gamma-B crystallin and ubiquitin, have been described as scaffolds for Affilin proteins. Certain amino acids in these proteins can be substituted by others without losing structural integrity, a process creating regions capable of binding different antigens, depending on which amino acids are exchanged. In both types, the binding region is typically located in a beta sheet structure,{{Cite journal

Based on gamma crystallin

Historically, Affilin molecules were based on gamma crystallin, a family of proteins found in the eye lens of vertebrates, including humans. It consists of two identical domains with mainly beta sheet structure and a total molecular mass of about 20 kDa.{{Cite journal

Based on ubiquitin

Ubiquitin, as the name suggests, is a highly conserved protein occurring ubiquitously in eukaryotes. It consists of 76 amino acids in three and a half alpha helix windings and five strands constituting a beta sheet. For example, the eight surface-exposed exchangeable amino acids 2, 4, 6, 62, 63, 64, 65, and 66 are located at the beginning of the first N-terminal beta strand (2, 4, 6), at the nearby beginning of the C-terminal strand and the loop leading up to it (63–66). The resulting Affilin proteins are about 10 kDa in mass.

Properties

The molecular mass of crystallin and ubiquitin based Affilin proteins is only one eighth or one sixteenth of an IgG antibody, respectively. This leads to an improved tissue permeability, heat stability up to 90 °C (195 °F), and stability towards proteases as well as acids and bases. The latter enables Affilin proteins to pass through the intestine, but like most proteins they are not absorbed into the bloodstream. Renal clearance, another consequence of their small size, is the reason for their short plasma half-life, generally a disadvantage for potential drugs.

Production

Molecular libraries of Affilin proteins are generated by randomizing sets of amino acids by mutagenesis methods. Substituting selected amino acids at the potential binding site gives 198 ≈ 17,000,000,000 possible combinations (e.g.: eight amino acids substituted by 19 amino acids). Cysteine is excluded because of its liability to form disulfide bonds. In an Affilin protein comprising two modified ubiquitin molecules, for example, up to 14 amino acids are exchanged, resulting in 8 × 1017 combinations, but not all of these are realized in a given library.

The next step is the selection of Affilin proteins that bind the desired target protein. To this end display techniques such as phage display or ribosome display are used. The fitting species are isolated and characterized physically, chemically and pharmacologically. Subsequent dimerisation or multimerisation can increase plasma half-life and, due to avidity, affinity to the target protein. Alternatively, multispecific Affilin molecules can be generated, binding different targets simultaneously. Radionuclides or cytotoxins can be conjugated to Affilin proteins, making them potential tumour therapeutics and diagnostics. Conjugation of cytokines has also been tested in vitro.

Large-scale production of Affilin proteins is facilitated by E. coli and other organisms commonly used in biotechnology.

References

References

1. Abbas AK and Lichtman AH. (2003). "Cellular and Molecular Immunology". Saunders, Philadelphia.
2. {{Patent. WO. 0104144. Fabrication of beta-plated sheet proteins with specific binding properties. Fiedler, U.; Rudolph, R. Publication date: 2001-01-18.
3. {{Patent. WO. 2006040129. Protein conjugates for use in therapy, diagnosis and chromatography. Fiedler, E.; Ebersbacher, H.; Hey, Th.; Fiedler, U. / Scil Proteins GmbH. Publication date: 2006-04-20.
4. "Affilin Scaffold". Scil Proteins.
5. "Affilin Conjugates". Scil Proteins.