TY - JOUR A1 - Speck, Janina A1 - Räuber, Christina A1 - Kükenshöner, Tim A1 - Niemöller, Christoph A1 - Mueller, Katelyn J. A1 - Schleberger, Paula A1 - Dondapati, Padmarupa A1 - Hecky, Jochen A1 - Arndt, Katja Maren A1 - Müller, Kristian M. T1 - TAT hitchhiker selection expanded to folding helpers, multimeric interactions and combinations with protein fragment complementation JF - Protein engineering design & selection N2 - The twin-arginine translocation (TAT) pathway of the bacterial cytoplasmic membrane mediates translocation only of proteins that accomplished a native-like conformation. We deploy this feature in modular selection systems for directed evolution, in which folding helpers as well as dimeric or oligomeric proteinprotein interactions enable TAT-dependent translocation of the resistance marker TEM -lactamase (L). Specifically, we demonstrate and analyze selection of (i) enhancers for folding by direct TAT translocation selection of a target protein interposed between the TorA signal sequence and L, (ii) dimeric or oligomeric proteinprotein interactions by hitchhiker translocation (HiT) selection of proteins fused to the TorA signal sequence and to the L, respectively and (iii) heterotrimeric proteinprotein interactions by combining HiT with protein fragment complementation selection of proteins fused to two split L fragments and TorA, respectively. The lactamase fragments were additionally engineered for improved activity and stability. Applicability was benchmarked with interaction partners of known affinity and multimerization whereby cellular fitness correlated well with biophysical protein properties. Ultimately, the HiT selection was employed to identify peptides, which specifically bind to leukemia- and melanoma-relevant target proteins (MITF and ETO) by coiled-coil or tetra-helix-bundle formation with high affinity. The various versions of TAT selection led to inhibiting peptides (iPEPs) of disease-promoting interactions and enabled so far difficult to achieve selections. KW - HiT selection KW - NHR2 KW - TAT selection KW - three hybrid KW - two hybrid Y1 - 2013 U6 - https://doi.org/10.1093/protein/gzs098 SN - 1741-0126 VL - 26 IS - 3 SP - 225 EP - 242 PB - Oxford Univ. Press CY - Oxford ER - TY - JOUR A1 - Speck, Janina A1 - Hecky, Jochen A1 - Tam, Heng-Keat A1 - Arndt, Katja Maren A1 - Einsle, Oliver A1 - Müller, Kristian M. T1 - Exploring the molecular linkage of protein stability traits for enzyme optimization by iterative truncation and evolution JF - Biochemistry N2 - The stability of proteins is paramount for their therapeutic and industrial use and, thus, is a major task for protein engineering. Several types of chemical and physical stabilities are desired, and discussion revolves around whether each stability trait needs to be addressed separately and how specific and compatible stabilizing mutations act. We demonstrate a stepwise perturbation-compensation strategy, which identifies mutations rescuing the activity of a truncated TEM beta-lactamase. Analyses relating structural stress with the external stresses of heat, denaturants, and proteases reveal our second-site suppressors as general stability centers that also improve the full-length enzyme. A library of lactamase variants truncated by 15 N-terminal and three C-terminal residues (Bla-N Delta 15C Delta 3) was subjected to activity selection and DNA shuffling. The resulting clone with the best in vivo performance harbored eight mutations, surpassed the full-length wild-type protein by 5.3 degrees C in T-m, displayed significantly higher catalytic activity at elevated temperatures, and showed delayed guanidine-induced denaturation. The crystal structure of this mutant was determined and provided insights into its stability determinants. Stepwise reconstitution of the N- and C-termini increased its thermal, denaturant, and proteolytic resistance successively, leading to a full-length enzyme with a T-m increased by 15.3 degrees C and a half-denaturation concentration shifted from 0.53 to 1.75 M guanidinium relative to that of the wild type. These improvements demonstrate that iterative truncation-optimization cycles can exploit stability-trait linkages in proteins and are exceptionally suited for the creation of progressively stabilized variants and/or downsized proteins without the need for detailed structural or mechanistic information. Y1 - 2012 U6 - https://doi.org/10.1021/bi2018738 SN - 0006-2960 VL - 51 IS - 24 SP - 4850 EP - 4867 PB - American Chemical Society CY - Washington ER -