Steffen Brenzel scite author profile

Steffen Brenzel

4Publications

113Citation Statements Received

96Citation Statements Given

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109

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Philipps University of Marburg, TU Dortmund University

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Engineering Artificially Split Inteins for Applications in Protein Chemistry: Biochemical Characterization of the Split Ssp DnaB Intein and Comparison to the Split Sce VMA Intein

2006

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In protein trans-splicing, an intein domain split into two polypeptide chains mediates linkage of the flanking amino acid sequences, the N- and C-terminal exteins, with a native peptide bond. This process can be exploited to assemble proteins from two separately prepared fragments, e.g., for the segmental labeling with isotopes for NMR studies or the incorporation of chemical and biophysical probes. Split inteins can be artificially generated by genetic means; however, the purified inteinN and inteinC fragments usually require a denaturation and renaturation treatment to fold into the active intein, thus preventing their application to proteins that cannot be refolded. Here, we report that the purified fragments of the artificially split DnaB helicase of Synechocystis spp. PCC6803 (Ssp DnaB) intein are active under native conditions. The first-order rate constant of the protein trans-splicing reaction was 7.1 x 10(-4) s(-1). The previously described split vacuolar ATPase of Saccharomyces cerevisiae (Sce VMA) intein is the only other artificially split intein that is active under native conditions; however, it requires induced complex formation of the intein fragments by auxiliary dimerization domains for efficient protein trans-splicing. In contrast, fusion of the dimerization domains to the split Ssp DnaB intein fragments had no effect on activity. This difference was also reflected by a higher thermostability of the split Ssp DnaB intein. Further investigations of the split Sce VMA intein under optimized conditions revealed a first-order rate constant of 9.4 x 10(-4) s(-1) for protein trans-splicing and 1.7 x 10(-3) s(-1) for C-terminal cleavage involving a Cys1Ala mutant. Finally, we show that the two split inteins are orthogonal, suggesting further applications for the assembly of proteins from more than two parts.

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Expanding the Scope of Protein Trans‐Splicing to Fragment Ligation of an Integral Membrane Protein: Towards Modulation of Porin‐Based Ion Channels by Chemical Modification

et al. 2009

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Design of an Intein that Can Be Inhibited with a Small Molecule Ligand

Brenzel

Mootz

2005

J. Am. Chem. Soc.

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Protein splicing is a process in which an intervening sequence, the intein, catalyzes its own excision out of a larger polypeptide precursor by joining the flanking sequences, the exteins, with a native peptide bond. Inteins are almost completely promiscuous toward the nature of their extein sequences and can be inserted into virtually any host protein. The intein-mediated formation of a peptide bond between two polypeptides offers great potential to modulate protein structure and, hence, protein function on the post-translational level. In this work, we report the design of an intein that can be inhibited by the addition of a specific small molecule ligand. Our design strategy involved the generation of a trans-splicing intein, in which the intein domain is split into two-halves that are located on two separate polypeptides, each joined with the respective N- or C-terminal extein. To turn these fragments into an active intein with an incorporated "off" switch, each was fused at its newly created terminus with the F36M mutant of FKBP12, referred to as the FM domain. The F36M substitution was reported to effect a homodimerization of the usually monomeric FKBP12 protein; however, addition of the small molecule ligand, rapamycin, or synthetic derivatives thereof leads to a dissociation of the dimer. This phenomenon was exploited by first reconstituting the active intein on the basis of FM domain dimerization. Second, addition of the small molecule ligand prevented formation of the active intein complex and inhibited protein trans-splicing. This intein exhibited unexpected kinetic properties and provides a new and potentially very general means to control protein function on the post-translational level.

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Switchable Inteins: New Tools to Control Protein Function by using Regulated Protein Splicing

Brenzel

Ludwig

Mootz

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Steffen Brenzel

Engineering Artificially Split Inteins for Applications in Protein Chemistry: Biochemical Characterization of the Split Ssp DnaB Intein and Comparison to the Split Sce VMA Intein

Expanding the Scope of Protein Trans‐Splicing to Fragment Ligation of an Integral Membrane Protein: Towards Modulation of Porin‐Based Ion Channels by Chemical Modification

Design of an Intein that Can Be Inhibited with a Small Molecule Ligand

Switchable Inteins: New Tools to Control Protein Function by using Regulated Protein Splicing

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