Activation of an Autoregulated Protein Kinase by Conditional Protein Splicing

Mootz, Henning D.; Blum, Elyse S.; Muir, Tom W.

doi:10.1002/anie.200460941

Cited by 43 publications

(28 citation statements)

References 22 publications

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“…SURF represents an attractive alternative when the protein of interest is known to take part in protein-protein interactions or multimeric complexes as rescue is inextricably linked to generation of the native protein. In the future this cleavage-dependent rescue technology could be expanded to include other methods of protein regulation such as mislocalization or autoinhibition (34).…”

Section: Discussionmentioning

confidence: 99%

Small-molecule-mediated rescue of protein function by an inducible proteolytic shunt

Pratt

Schwartz²,

Muir³

2007

Proc. Natl. Acad. Sci. U.S.A.

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Section: Discussionmentioning

confidence: 99%

Small-molecule-mediated rescue of protein function by an inducible proteolytic shunt

Pratt

Schwartz²,

Muir³

2007

Proc. Natl. Acad. Sci. U.S.A.

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“…Although natural inteins splice spontaneously, inteins that undergo splicing in a small-molecule-dependent manner have been developed by fusing intein halves with proteins that dimerize in the presence of a small molecule (Mootz and Muir, 2002; Mootz et al, 2003; Shi and Muir, 2005), or by directed evolution in which a library of intact inteins fused to a ligand-binding domain was screened to splice in the presence, but not the absence, of a small molecule (Buskirk et al, 2004). These small-molecule-dependent inteins have enabled protein function in cells to be controlled post-translationally by the addition of an exogenous, cell-permeable molecule (Mootz and Muir, 2002, Mootz et al, 2003, Buskirk et al, 2004; Mootz et al, 2004; Shi and Muir, 2005; Yuen et al, 2006; Schwartz et al, 2007; Hartley and Madhani, 2009). …”

Section: Introductionmentioning

confidence: 99%

Directed Evolution of a Small-Molecule-Triggered Intein with Improved Splicing Properties in Mammalian Cells

Peck

Chen

Liu

2011

Chemistry & Biology

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Summary Laboratory-created small-molecule-dependent inteins enable protein structure and function to be controlled post-translationally in living cells. Previously we evolved two inteins (2-4 and 3-2) that splice efficiently in the presence, but not the absence, of the cell-permeable small molecule 4-hydroxytamoxifen (4-HT) in a variety of extein contexts in Saccharomyces cerevisiae. In mammalian cells, however, the 2-4 and 3-2 inteins exhibited significantly lower splicing efficiencies and slower splicing in the presence of 4-HT, as well as higher background splicing in the absence of 4-HT, than in yeast cells. In this work we evolved the 2-4 and 3-2 inteins through several additional rounds of mutation, recombination, and screening in S. cerevisiae at both 30 °C and 37 °C. The resulting second-generation evolved inteins exhibit substantially improved (~2- to 5-fold higher) splicing yields in yeast compared to the parental 2-4 and 3-2 inteins and significantly faster splicing kinetics. The improved properties of these evolved inteins carried over to mammalian cells, in which the newly evolved inteins spliced with substantially greater (~2- to 8-fold) efficiency in the presence of 4-HT while maintaining background splicing levels in the absence of 4-HT that are comparable to or better than the levels observed with the 2-4 or 3-2 inteins. In total, these inteins were tested in four different protein contexts in yeast and human cells and found to exhibit their substantially improved properties in all contexts tested, typically resulting in 50–90% spliced protein in the presence of 4-HT and < 5% splicing in the absence of 4-HT. The second-generation evolved inteins augment the promise of ligand-dependent protein splicing as an effective and broadly applicable approach to probing protein function in mammalian cells.

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“…This has allowed the development of so-called conditional protein splicing systems in which the splicing reaction is triggered by induced proximity of the intein fragments through either the use of small molecule or light stimulation. [31][32][33] We have shown that conditional protein splicing can be used to for the rapid and tunable activation of proteins in a variety of cell types 34 and even in a living animal. 35 …”

Section: Protein Splicingmentioning

confidence: 99%

Studying protein structure and function using semisynthesis

Muir

2008

Biopolymers

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In this review, which is more or less a transcript of my du Vigneaud Award Lecture, I cover the development and application of the protein semisynthesis technique, Expressed Protein Ligation (EPL). EPL allows the assembly of modified proteins from recombinant and synthetic peptide building blocks. The approach has been widely used since its introduction in 1998 and has allowed a number of biochemical problems to be solved through the use of CEdesigner proteins. In this article, the utility of the approach is illustrated through work in my own lab and with an emphasis on the use of EPL to study the role of protein post-translational modifications.

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Activation of an Autoregulated Protein Kinase by Conditional Protein Splicing

Cited by 43 publications

References 22 publications

Small-molecule-mediated rescue of protein function by an inducible proteolytic shunt

Small-molecule-mediated rescue of protein function by an inducible proteolytic shunt

Directed Evolution of a Small-Molecule-Triggered Intein with Improved Splicing Properties in Mammalian Cells

Studying protein structure and function using semisynthesis

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