Your search keyword '"Deu E"' showing total 5 results

1. A coupled protein and probe engineering approach for selective inhibition and activity-based probe labeling of the caspases.

Author

Xiao J, Broz P, Puri AW, Deu E, Morell M, Monack DM, and Bogyo M

Subjects

Binding Sites, Caspase 1 analysis, Caspase 8 analysis, Cell Line, Humans, Models, Molecular, Molecular Imaging, Mutation, Recombinant Proteins analysis, Recombinant Proteins genetics, Recombinant Proteins metabolism, Substrate Specificity, Caspase 1 genetics, Caspase 1 metabolism, Caspase 8 genetics, Caspase 8 metabolism, Protein Engineering methods

Abstract

Caspases are cysteine proteases that play essential roles in apoptosis and inflammation. Unfortunately, their highly conserved active sites and overlapping substrate specificities make it difficult to use inhibitors or activity-based probes to study the function, activation, localization, and regulation of individual members of this family. Here we describe a strategy to engineer a caspase to contain a latent nucleophile that can be targeted by a probe containing a suitably placed electrophile, thereby allowing specific, irreversible inhibition and labeling of only the engineered protease. To accomplish this, we have identified a non-conserved residue on the small subunit of all caspases that is near the substrate-binding pocket and that can be mutated to a non-catalytic cysteine residue. We demonstrate that an active-site probe containing an irreversible binding acrylamide electrophile can specifically target this cysteine residue. Here we validate the approach using the apoptotic mediator, caspase-8, and the inflammasome effector, caspase-1. We show that the engineered enzymes are functionally identical to the wild-type enzymes and that the approach allows specific inhibition and direct imaging of the engineered targets in cells. Therefore, this method can be used to image localization and activation as well as the functional contributions of individual caspase proteases to the process of cell death or inflammation.

Published

2013

2. Coupling protein engineering with probe design to inhibit and image matrix metalloproteinases with controlled specificity.

Author

Morell M, Nguyen Duc T, Willis AL, Syed S, Lee J, Deu E, Deng Y, Xiao J, Turk BE, Jessen JR, Weiss SJ, and Bogyo M

Subjects

Amino Acid Sequence, Animals, Cell Line, Cysteine analysis, Cysteine genetics, Cysteine metabolism, Humans, Matrix Metalloproteinase 1 genetics, Matrix Metalloproteinase 1 metabolism, Matrix Metalloproteinase 12 genetics, Matrix Metalloproteinase 12 metabolism, Mice, Models, Molecular, Molecular Sequence Data, Optical Imaging, Sequence Alignment, Zebrafish, Matrix Metalloproteinase 1 analysis, Matrix Metalloproteinase 12 analysis, Molecular Probe Techniques, Protein Engineering methods

Abstract

Matrix metalloproteinases (MMPs) are zinc endopeptidases that play roles in numerous pathophysiological processes and therefore are promising drug targets. However, the large size of this family and a lack of highly selective compounds that can be used for imaging or inhibition of specific MMPs members has limited efforts to better define their biological function. Here we describe a protein engineering strategy coupled with small-molecule probe design to selectively target individual members of the MMP family. Specifically, we introduce a cysteine residue near the active-site of a selected protease that does not alter its overall activity or function but allows direct covalent modification by a small-molecule probe containing a reactive electrophile. This specific engineered interaction between the probe and the target protease provides a means to both image and inhibit the modified protease with absolute specificity. Here we demonstrate the feasibility of the approach for two distinct MMP proteases, MMP-12 and MT1-MMP (or MMP-14).

Published

2013

3. The partially folded homodimeric intermediate of Escherichia coli aspartate aminotransferase contains a "molten interface" structure.

Author

Deu E, Dhoot J, and Kirsch JF

Subjects

Alanine metabolism, Amino Acid Sequence, Amino Acid Substitution, Aspartate Aminotransferases genetics, Aspartate Aminotransferases metabolism, Binding Sites, Circular Dichroism, Enzyme Stability, Escherichia coli genetics, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Hydrogen Bonding, Kinetics, Models, Biological, Molecular Sequence Data, Molecular Weight, Protein Denaturation, Protein Folding, Protein Structure, Quaternary, Protein Structure, Secondary, Protein Structure, Tertiary, Static Electricity, Thermodynamics, Urea pharmacology, Aspartate Aminotransferases chemistry, Escherichia coli enzymology, Escherichia coli Proteins chemistry

Abstract

The role of intersubunit side chain-side chain interactions in the stability of the Escherichia coli aspartate aminotransferase (eAATase) homodimer was investigated by directed mutagenesis at 10 different interface contacts. The urea-mediated unfolding pathway of this enzyme proceeds through the formation of a dimeric intermediate, D*, that retains only 40% of the native enzyme secondary structure as judged by circular dichroism. Disruption of any single intersubunit interaction results in a >2.6 kcal mol(-1) decrease in native state stability, independent of its location or nature. However, the stability of D* with respect to U, the unfolded monomer, is the same for all mutants. The stability of the eAATase interface cannot be ascribed to the contribution of a few hot spots, or to the accumulation of a large number of weak interactions, but only to the presence of multiple important and interconnected interactions. It is proposed that a "molten interface" structure, flexible enough to accommodate point mutations, accounts for the stability of D*. Nuclei of tertiary structure, which are not involved in native intersubunit contacts, likely provide a scaffold for the unstructured interface of D*. Such a scaffold would account for the cooperative unfolding of the intermediate.

Published

2009

4. Cofactor-directed reversible denaturation pathways: the cofactor-stabilized Escherichia coli aspartate aminotransferase homodimer unfolds through a pathway that differs from that of the apoenzyme.

Author

Deu E and Kirsch JF

Subjects

Circular Dichroism, Enzyme Stability, Escherichia coli enzymology, Guanidine pharmacology, Holoenzymes chemistry, Protein Folding, Protein Renaturation drug effects, Protein Structure, Quaternary, Pyridoxal Phosphate pharmacology, Pyridoxamine analogs & derivatives, Pyridoxamine chemistry, Spectrometry, Fluorescence, Thermodynamics, Urea pharmacology, Aspartate Aminotransferases chemistry, Protein Denaturation drug effects, Pyridoxal Phosphate chemistry

Abstract

While the urea-mediated unfolding pathway of the Escherichia coli aspartate aminotransferase (eAATase) homodimer proceeds through a reversible three-state process with a partially folded dimeric intermediate, D D* 2U (E. Deu and J. F. Kirsch, accompanying paper), that of a cofactor-stabilized form differs. Pyridoxal phosphate, which binds at the intersubunit active sites, stabilizes the native form by 6 kcal mol-1 and dissociates during the D <==> D* transition. Reductive trapping of the cofactor to a nondissociable derivative (PPL-eAATase) precludes the formation of D*. A novel monomeric intermediate (M'-PPL) with 70% of the native secondary structure (circular dichroism) was identified in the unfolding pathway of PPL-eAATase: D-PPL2 <==> 2M'-PPL <==> 2U-PPL. The combined results define two structural regions with distinct stabilities: the active site region (ASR) and the generally more stable, dimerization region (DMR). The DMR includes the key intersubunit contacts. It is responsible for the multimeric nature of D*, and its disorder leads to dimer dissociation. Selective strengthening of the ASR-cofactor interactions by cofactor trapping reverses the relative stabilities of the two regions (from DMR > ASR in the apoenzyme to ASR > DMR in PPL-eAATase) and results in a reordering of the eAATase denaturation pathway.

Published

2007

5. The unfolding pathway for Apo Escherichia coli aspartate aminotransferase is dependent on the choice of denaturant.

Author

Deu E and Kirsch JF

Subjects

Circular Dichroism, Escherichia coli enzymology, Protein Folding, Protein Structure, Quaternary, Spectrometry, Fluorescence, Temperature, Apoenzymes chemistry, Aspartate Aminotransferases chemistry, Guanidine pharmacology, Protein Denaturation drug effects, Urea pharmacology

Abstract

The guanidine hydrochloride (GdnHCl) mediated denaturation pathway for the apo form of homodimeric Escherichia coli aspartate aminotransferase (eAATase) (molecular mass = 43.5 kDa/monomer) includes a partially folded monomeric intermediate, M* [Herold, M., and Kirschner, K. (1990) Biochemistry 29, 1907-1913; Birolo, L., Dal Piaz, F., Pucci, P., and Marino, G. (2002) J. Biol. Chem. 277, 17428-17437]. The present investigation of the urea-mediated denaturation of eAATase finds no evidence for an M* species but uncovers a partially denatured dimeric form, D*, that is unpopulated in GdnHCl. Thus, the unfolding process is a function of the employed denaturant. D* retains less than 50% of the native secondary structure (circular dichroism), conserves significant quaternary and tertiary interactions, and unfolds cooperatively (mD*<==>U = 3.4 +/- 0.3 kcal mol-1 M-1). Therefore, the following equilibria obtain in the denaturation of apo-eAATase: D <==> 2M 2M* <==> 2U in GdnHCl and D <==> D* <==> 2U in urea (D = native dimer, M = folded monomer, and U = unfolded state). The free energy of unfolding of apo-eAATase (D <==> 2U) is 36 +/- 3 kcal mol-1, while that for the D* 2U transition is 24 +/- 2 kcal mol-1, both at 1 M standard state and pH 7.5.

Published

2007