Your search keyword '"Threonine Aspartase 1"' showing total 3 results

1. Allosteric inhibition of Taspase1's pathobiological activity by enforced dimerization in vivo

Author

Lena Kunst, Markus Kaiser, Oliver H. Krämer, Shirley K. Knauer, Sabine Scheiding, Désirée Wünsch, Christian Ottmann, Carolin Bier, Roland H. Stauber, and Chemical Biology

Subjects

Immunoprecipitation, medicine.medical_treatment, Mutant, Allosteric regulation, Threonine Aspartase 1, Chemical biology, Medizin, Biology, Protein Engineering, SDG 3 – Goede gezondheid en welzijn, Cleavage (embryo), Biochemistry, Allosteric Regulation, SDG 3 - Good Health and Well-being, In vivo, Cell Line, Tumor, Endopeptidases, Genetics, medicine, Humans, Protease Inhibitors, Molecular Biology, Protease, Protein Multimerization, Biologie, Biotechnology

Abstract

Taspase1 mediates cleavage of the mixed lineage leukemia (MLL) protein and leukemia-provoking MLL fusions and promotes solid malignancies. Currently, no effective and specific Taspase1 inhibitors are available, precluding its therapeutic exploitation. As the Taspase1 proenzyme is autoproteolytically cleaved and assumed to assemble into an active alpha beta beta alpha heterodimer, we attempted to interfere with its activity by targeting Taspase1's dimerization. Notably, enforced expression of inactive Taspase1 mutants, aiming to inhibit formation of active protease dimers, was not inhibitory. Immunoprecipitation, gel filtration, and in vivo protein interaction assays revealed that active Taspase1 exists predominantly as an alpha beta monomer in living cells, providing an explanation why overexpression of inactive mutants was not trans-dominant. To alternatively test the biological consequences of enforced dimerization, we engineered Taspase1 variants containing the Jun/Fos dimerization motif. In absence of the respective interaction partners, the protease fusions were fully active, while enforcing dimerization by coexpression significantly inhibited processing of several target proteins in living cells. Our study provides the first evidence that Taspase1 is already active as an alpha beta monomer, arguing against heterocomplex formation being required for its pathobiological activity. Thus, it clearly supports strategies aiming to inhibit the cancer-promoting activity of Taspase1 by the identification of chemical decoys enforcing its dimerization.-Bier, C., Knauer, S. K., Wunsch, D., Kunst, L., Scheiding, S., Kaiser, M., Ottmann, C., Kramer, O. H., Stauber, R. H. Allosteric inhibition of Taspase1's pathobiological activity by enforced dimerization in vivo. FASEB J. 26, 3421-3429 (2012). www.fasebj.org

Published

2012

2. Bioassays to monitor taspase1 function for the identification of pharmacogenetic inhibitors

Author

Roland H. Stauber, Bettina Hofmann, Rolf Marschalek, Samaneh Sabiani, Sandra Friedl, Verena Fetz, Eugen Proschak, Eckhard Thines, Thomas Kindler, Jens Rabenstein, Carolin Bier, Shirley K. Knauer, Elisabeth Schröder, Lena Kunst, and Gisbert Schneider

Subjects

Proteomics, Cytoplasm, Hydrolases, medicine.medical_treatment, Threonine Aspartase 1, Drug Evaluation, Preclinical, lcsh:Medicine, Biosensing Techniques, Biochemistry, Mice, Molecular Cell Biology, Basic Cancer Research, lcsh:Science, Multidisciplinary, Enzyme Classes, Proteomic Databases, 3T3 Cells, Small molecule, Cellular Structures, Enzymes, Oncology, Medicine, Biological Assay, Biologie, Research Article, Proteases, Cell Survival, In silico, Biology, Cleavage (embryo), In vivo, Genetic Mutation, ddc:570, Endopeptidases, Chemical Biology, Consensus sequence, medicine, Genetics, Animals, Humans, Protease Inhibitors, Cell Nucleus, Protease, lcsh:R, Proteins, Pharmacogenetics, Small Molecules, Mutagenesis, lcsh:Q

Abstract

Background Threonine Aspartase 1 (Taspase1) mediates cleavage of the mixed lineage leukemia (MLL) protein and leukemia provoking MLL-fusions. In contrast to other proteases, the understanding of Taspase1's (patho)biological relevance and function is limited, since neither small molecule inhibitors nor cell based functional assays for Taspase1 are currently available. Methodology/Findings Efficient cell-based assays to probe Taspase1 function in vivo are presented here. These are composed of glutathione S-transferase, autofluorescent protein variants, Taspase1 cleavage sites and rational combinations of nuclear import and export signals. The biosensors localize predominantly to the cytoplasm, whereas expression of biologically active Taspase1 but not of inactive Taspase1 mutants or of the protease Caspase3 triggers their proteolytic cleavage and nuclear accumulation. Compared to in vitro assays using recombinant components the in vivo assay was highly efficient. Employing an optimized nuclear translocation algorithm, the triple-color assay could be adapted to a high-throughput microscopy platform (Z'factor = 0.63). Automated high-content data analysis was used to screen a focused compound library, selected by an in silico pharmacophor screening approach, as well as a collection of fungal extracts. Screening identified two compounds, N-[2-[(4-amino-6-oxo-3H-pyrimidin-2-yl)sulfanyl]ethyl]benzenesulfonamide and 2-benzyltriazole-4,5-dicarboxylic acid, which partially inhibited Taspase1 cleavage in living cells. Additionally, the assay was exploited to probe endogenous Taspase1 in solid tumor cell models and to identify an improved consensus sequence for efficient Taspase1 cleavage. This allowed the in silico identification of novel putative Taspase1 targets. Those include the FERM Domain-Containing Protein 4B, the Tyrosine-Protein Phosphatase Zeta, and DNA Polymerase Zeta. Cleavage site recognition and proteolytic processing of these substrates were verified in the context of the biosensor. Conclusions The assay not only allows to genetically probe Taspase1 structure function in vivo, but is also applicable for high-content screening to identify Taspase1 inhibitors. Such tools will provide novel insights into Taspase1's function and its potential therapeutic relevance., PLoS ONE, 6 (5), ISSN:1932-6203

Published

2011

3. Cell-based analysis of structure-function activity of threonine aspartase 1

Author

Andrea Schweitzer, Roland H. Stauber, Rolf Marschalek, Alexander Klapthor, Alexander Rekik, Shirley K. Knauer, Oliver H. Krämer, and Carolin Bier

Subjects

Proteases, Cytoplasm, medicine.medical_treatment, Threonine Aspartase 1, Chemical biology, Threonine protease, Gene Expression, Biosensing Techniques, Biology, Cleavage (embryo), Biochemistry, Cell Line, Substrate Specificity, Mice, Structure-Activity Relationship, Recognition sequence, Endopeptidases, medicine, Animals, Humans, Nuclear protein, Molecular Biology, Cell Nucleus, Protease, Cell Biology, Mutation, Biologie, Genome-Wide Association Study

Abstract

Taspase1 is a threonine protease responsible for cleaving intracellular substrates. As such, (de)regulated Taspase1 function is expected not only to be vital for ordered development but may also be relevant for disease. However, the full repertoires of Taspase1 targets as well as the exact biochemical requirements for its efficient and substrate-specific cleavage are not yet resolved. Also, no cellular assays for this protease are currently available, hampering the exploitation of the (patho)biological relevance of Taspase1. Here, we developed highly efficient cell-based translocation biosensor assays to probe Taspase1 trans-cleavage in vivo. These modular sensors harbor variations of Taspase1 cleavage sites and localize to the cytoplasm. Expression of Taspase1 but not of inactive Taspase1 mutants or of unrelated proteases triggers proteolytic cleavage and nuclear accumulation of the biosensors. Employing our assay combined with scanning mutagenesis, we identified the sequence and spatial requirements for efficient Taspase1 processing in liquid and solid tumor cell lines. Collectively, our results defined an improved Taspase1 consensus recognition sequence, Q(3)(F/I/L/V)(2)D(1)↓G(1)'X(2)'D(3)'D(4)', allowing the first genome-wide bioinformatic identification of the human Taspase1 degradome. Among the 27 most likely Taspase1 targets are cytoplasmic but also nuclear proteins, such as the upstream stimulatory factor 2 (USF2) or the nuclear RNA export factors 2/5 (NXF2/5). Cleavage site recognition and proteolytic processing of selected targets were verified in the context of the biosensor and for the full-length proteins. We provide novel mechanistic insights into the function and bona fide targets of Taspase1 allowing for a focused investigation of the (patho)biological relevance of this type 2 asparaginase.

Published

2011