Moonil Kim

Large-scale preparation of active caspase-3 in E. coli by designing its thrombin-activatable precursors

BackgroundCaspase-3, a principal apoptotic effector that cleaves the majority of cellular substrates, is an important medicinal target for the treatment of cancers and neurodegenerative diseases. Large amounts of the protein are required for drug discovery research. However, previous efforts to express the full-length caspase-3 gene in E. coli have been unsuccessful.ResultsOverproducers of thrombin-activatable full-length caspase-3 precursors were prepared by engineering the auto-activation sites of caspase-3 precursor into a sequence susceptible to thrombin hydrolysis. The engineered precursors were highly expressed as soluble proteins in E. coli and easily purified by affinity chromatography, to levels of 10–15 mg from 1 L of E. coli culture, and readily activated by thrombin digestion. Kinetic evaluation disclosed that thrombin digestion enhanced catalytic activity (kcat/KM) of the precursor proteins by two orders of magnitude.ConclusionA novel method for a large-scale preparation of active caspase-3 was developed by a strategic engineering to lack auto-activation during expression with amino acid sequences susceptible to thrombin, facilitating high-level expression in E. coli. The precursor protein was easily purified and activated through specific cleavage at the engineered sites by thrombin, generating active caspase-3 in high yields.

Comparative Proteomic Analysis of Mouse Melanoma Cell Line B16, a Metastatic Descendant B16F10, and B16 Overexpressing the Metastasis-Associated Tyrosine Phosphatase PRL-3

Metastasis is a complex, multistep process by which a cancer cell leaves the primary tumor, travels to a distant site via the circulatory system, and establishes a secondary cancer. A deeper understanding of the molecular events underlying metastasis will provide information that will be useful for the development of new diagnostic and therapeutic strategies. The B16 and B16F10 mouse melanoma cell lines are widely used as model system for studying many aspects of cancer biology including metastasis. Compared with B16, which has a low metastatic potential, the highly metastatic cell line B16F10 displayed a higher metastatic ability along with higher expression levels of the metastasis-associated phosphatase of regenerating liver-3 (PRL-3). B16 cells transfected with PRL-3 cDNA (B16-PRL3) had metastatic abilities comparable to those of Bl16F10 cells. To study the molecular mechanisms that underlie metastasis, the proteomes of the B16, B16F10, and B16-PRL3 cell lines were compared using two-dimensional differential in-gel electrophoresis. Proteins that varied significantly in levels between these cell lines were selected and identified using mass spectrometry. Interestingly, many proteins, especially those present in membrane fractions, were similarly up- or downregulated in both the Bl16F10 and B16-PRL3 cells lines compared to B16 cell lines. The list of similarly regulated proteins included heat shock protein 70, fascin-1, septin-6, ATP synthase beta subunit, and bone morphogenic protein receptor type IB. These proteins may play a causal role in PRL-3-mediated metastasis. These investigations open an avenue for the further characterization of the molecular mechanisms that underlie metastasis.

Large-scale expression in Escherichia coli and efficient purification of precursor and active caspase-7 by introduction of thrombin cleavage sites

Caspases are a family of cysteine proteases that have critical roles in the apoptotic pathway. Caspase-7 is a well-known apoptotic effector that cleaves a variety of cellular substrates, and is known to be an important target in the treatment of many diseases. For efficient research, large amounts of the protein are required. However, it has been difficult to obtain sufficient quantities of either the precursor or active caspase-7 from Escherichia coli strain. In the present study, we constructed thrombin-activatable caspase-7 precursors by changing the auto-activation sites of the caspase-7 precursor into sequences susceptible to thrombin cleavage. These engineered precursors were highly expressed as soluble proteins in E. coli, and were easily purified by affinity chromatography (to levels of 10-15 mg per liter of E. coli culture), and were then readily activated by treatment with thrombin. In vitro cleavage assays and kinetic analyses revealed that the engineered active caspase-7 proteins had characteristics similar to those of wild-type caspase-7. This novel method is valuable for obtaining both precursor and active caspase-7, thereby contributing to the development of caspase-7-specific drugs to treat various diseases, including cancer and neurodegenerative conditions.