Creating new enzymes - From Triosephosphate Isomerase to Kealases Marco G. Casteleijn 1, Markus Alahuhta 2, Mikko Salin 2, Matti Vaismaa 3, Ritva Juvani 3, Nanna Alho 3, Sampo Mattila 3, Marja Lajunen 3, Jouni Pursiainen 3, Rik K. Wierenga 2#, Peter Neubauer 1#. 1) University of Oulu (Finland), Bioprocess Engineering Laboratory, Dept. of Process and Environm. Engineering; 2) University of Oulu (Finland), Dept. of Biochemistry; 3) University of Oulu (Finland), Dept. of Chemistry. # corresponding Triose phosphate isomerase (TIM) is a glycolytic enzyme with very high substrate specificity (fig 1). The wild type enzyme is a dimer, and each subunit has the classical TIM-barrel fold [1]. Several loop modifications resulted in a monomeric enzyme (ml1TIM) [2,3] which remains active, although less so than the wild-type. Subsequently this has resulted in in a new variant (A-TIM) with a much more extensive binding [4,5]. Our current studies attempt to change the substrate specificity of monomeric TIM. Introduction 1.Kursula, I., and Wierenga, R.K. (2003) Crystal structure of triosephosphate isomerase complexed with 2-phospho-glycolate at 0.83Å resolution. J. Biol. Chem 278, Thanki, N., Zeelen, J.Ph., Mathieu, M, Jaenicke, R, Abagyan, R.A.A., Wierenga, R.K., Schliebs, W. (1997) Protein engineering with monomeric triophosphate isomerase (monoTIM): the modeling and structure verification of a seven-residue loop. Protein Engin. 10(2), Thanki N, Zeelen JP, Mathieu M, Jaenicke R, Abagyan RA, Wierenga RK, Schliebs W Protein engineering with monomeric triosephosphate isomerase (monoTIM): the modelling and structure verification of a seven-residue loop Protein Eng. v10, p Norledge, B.V., Lambeir, A.M., Abagyan, R.A., Rottmann, A., Fernandez, A. M., Filimonov, V.V., Peter, M.G., Wierenga, R.K Modelling, mutagenesis and structural studies on the fully conserved phosphate binding loop (loop-8) of triosephosphate isomerase: towards a new substrate specificity. Proteins 42, Markus Alahuhta, Mikko Salin, Marco G. Casteleijn, Kristian Kemmer, Peter Neubauer, Rik K. Wierenga. Structure-based enzyme engineering efforts with an inactive monomeric TIM variant: the importance of a single point mutation for generating a competent active site. Manuscript 6. [Kealases and Biocat projects] 7.Casteleijn MG, Alahuhta M, Groebel K, El-Sayed I, Augustyns K, Lambeir AM, Neubauer P, Wierenga RK. Functional Role of the Conserved Active Site Proline of Triosephosphate Isomerase. Biochemistry Dec 26;45(51): References The right starting point Our aim is to build a platform of TIM variants (Kealases) with a widened substrate range. Therefore we established by rational design a library of TIM variants, which resulted in a candidate for further development: A-TIM (fig. 2). A break through observation is that newly designed ligands bind into this pocket (fig. 3b; example). The use of the analytical tools available on the Oulu campus have shown to drive protein engineering development and the creation of tailored ligands for the new active site of A-TIM. Overall, A-TIM is an ideal test case for directed evolution approaches aiming at fine tuning its catalytic properties, and a very suitable starting protein for a bio-catalytic platform for the following reasons: The goal: Kealases Wild type and binding studies are focused on the binding and catalysis dynamics of the active site. Loop 7 is responsible for initiating conformational changes within the active site by “capturing” (together with loop 8) the anchor moiety (A; fig. 1) of the ligand [7]. In figure 3 the understanding of the structure and its catalytic machinery is summarized in respect to the creation of new enzymes which interconvert α-hydroxykentones and α-hydroxyaldehydes. Conclusions ►Monomeric TIM is a good scaffold for enzyme engineering. ►The newly engineered A-TIM has a competent active site and binds novel ligands. Figure 1 Wild type TIM (Wt-TIM) has high substrate specificity, and only catalyses the interconversion of the α-hydroxykentone DHAP and the α-hydroxyaldehyde D-GAP. The transition state analogue, 2-phosphoglycolate (2-PG), can be seen on the right. Red box: reactive head group (R) Green box: anchor moiety (A) Figure 2 Input and out put of the project. In blue are the mutagenesis experiments, in yellow the analytical tools available on the Oulu campus, and in purple the final goal. Results so far: A-TIM, Binders, Novel compounds. Acknowledgements This work is supported by the Academy of Finland (project & ). The authors would also like to thank Prof. Dr. Koen Augustyns from the University of Antwerp (Belgium) for providing us with Bromohydrogen-acteone phosphate (BHAP), and Ville Ratas 2 for his technical support. Shown are the new binding groove and the binding of a novel ligand for TIM. Structures of A-TIM liganded with 2-PG (fig.1) and a suicide inhibitor Bromo- hydroxyacetone phopsphate (BHAP), and NMR studies with original substrates (fig. 1 and 4) show that A-TIM still has a competent active site. A-TIM variants, derived from randomized mutagenesis, that can convert new ligands will be called Kealases. i.Small size, monomeric protein (very suitable for NMR; easily crystallized) ii.Highly expressed in E. coli as a soluble protein iii.Stable molecule, which tolerates many mutations iv.The current set of X-ray structures suggest that it is a “flexible” molecule, and therefore an ideal starting point for directed evolution experiments v.TIM does not require any cofactors vi.In the closed conformation the binding site is an extended groove vii.Its wild type precursor is the extensively studied TIM [6] Figure 3a Connolly surface picture of the new extended groove (at 1.06Å). The side chains of Lys13 (catalytic residue) and Lys239 (rim residue) are shown in transparent mode. Regions of negative electrostatic potential are colored red, and positive electrostatic potential are colored blue. Active site New binding groove R A Figure 3b A Novel Sulphonate binds A-TIM (1.7 Å). The red regions in A-TIM are targeted for site-directed mutagenesis. In grey is shown the backbone and in white the catalytic residues. Both pictures were made with ICM ( Figure 4 1-D NMR spectrum of the conversion of D-GAP into DHAP under the influence of ATIM D-GAP DHAP