Structure-function Studies of an Engineered Scaffold Protein Derived from Stefin A. I: Development of the SQM Variant

Overview

Journal Protein Eng Des Sel

Publisher Oxford University Press

Specialties Biochemistry
Biotechnology

Date 2010 Feb 25

PMID 20179045

Citations 12

Authors

Toni Hoffmann

Lukas Kurt Josef Stadler

Michael Busby

Qifeng Song

Anthony T Buxton

Simon D Wagner

Jason J Davis

Paul Ko Ferrigno

Affiliations

Soon will be listed here.

Abstract

Non-antibody scaffold proteins are used for a range of applications, especially the assessment of protein-protein interactions within human cells. The search for a versatile, robust and biologically neutral scaffold previously led us to design STM (stefin A triple mutant), a scaffold derived from the intracellular protease inhibitor stefin A. Here, we describe five new STM-based scaffold proteins that contain modifications designed to further improve the versatility of our scaffold. In a step-by-step approach, we introduced restriction sites in the STM open reading frame that generated new peptide insertion sites in loop 1, loop 2 and the N-terminus of the scaffold protein. A second restriction site in 'loop 2' allows substitution of the native loop 2 sequence with alternative oligopeptides. None of the amino acid changes interfered significantly with the folding of the STM variants as assessed by circular dichroism spectroscopy. Of the five scaffold variants tested, one (stefin A quadruple mutant, SQM) was chosen as a versatile, stable scaffold. The insertion of epitope tags at varying positions showed that inserts into loop 1, attempted here for the first time, were generally well tolerated. However, N-terminal insertions of epitope tags in SQM had a detrimental effect on protein expression.

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