Purification and Preliminary Characterization of the TM0727 Protein from Thermotoga maritima

The TM0727 gene of Thermotoga maritima is responsible for encoding what has been reported to be a modulator of DNA gyrase (pmbA). Although the function of pmbA is still unknown, it is believedto be involved in cell division, carbon storage regulation, and the synthesis of the antibiotic peptide microcin B17. It is suggested that it serves together with tldD, a known zinc dependent protease, tomodulate DNA gyrase. TM0727 is believed to be a zinc dependent protease that binds zinc in the central active site of the molecule, located between two equivalent monomeric units. However, thecrystal structure determined by Wilson et al. (2005) did not contain zinc. It therefore remains to be seen if TM0727 requires zinc for activity, or regulation, and if the protein is indeed a protease. To begin studying this protein, the gene was expressed in BL21(DE3) pLysS cells and the induction time was optimized. Using affinity and ion exchange chromatography, the protein has been successfully purified. The purification procedure can be replicated to obtain sufficient protein for characterization. Purification results show that the protein loses stability after 24 hours and remains stable under an imidazole-free lysis workup. Preliminary characterization of TM0727 has focused on understanding the protein’s structuralproperties through tryptophan fluorescence anisotropy measurements. The four tryptophan residues located within the TM0727 dimer fluoresce at different maximum wavelengths and with differentintensities upon excitation with 295nm light. These emission properties are highly sensitive to the environment (solvent, surrounding residues) of each tryptophan residue. The low number oftryptophans allows for a specific monitoring of the protein’s structure as it denatures. As more denaturant is added to the protein, its tryptophan environments have clearly altered. This is indicative of unfolding and increased solvent exposure of the protein. This unfolding has been confirmed with the addition of a fluorescent quencher. Additionally, fluorescence anisotropy measurements have been carried out on the protein to gain a preliminary understanding of the rotational dynamics of the tryptophan residues. These experiments excite the tryptophan residues within the sample using a polarized light source. Polarized emission is then detected, the degree of which depends on the rotational dynamics and local environment of the tryptophan residues. The protein was denatured and the changes in emission were recorded to detect these structural changes. Results have shown a large change in quaternary structure, consistent with a dimer to monomer transition, occurs at 1.5M Guandidine HCl. There has also been an examination of the crystal structure for the location of a potential active site. The inner cavity of the protein was inspected visually to locate a potential location for a catalytic triad, specifically the amino acids found in the active sites of serine, cyteine, and aspartateproteases. It was found that a potential aspartic protease active site may be located between the Asparate286 and Aspartate287 residues. Further investigation is warranted to test this remotepossibility.

Efficient and Accurate Characterization of the Bergman Cyclization for an Expanded Substructure of Esperamicin A1

Incorporation of enediynes into anticancer drugs remains an intriguing yet elusive strategy for the design of therapeutically active agents. Density functional theory was used to locate reactants, products, and transition states along the Bergman cyclization pathways connecting enediynes to reactive para-biradicals. Sum method correction to low-level calculations confirmed B3LYP/6-31G(d,p) as the method of choice in investigating enediynes. Herein described as MI:Sum, calculated reaction enthalpies differed from experiment by an average of 2.1 kcal·mol−1 (mean unsigned error). A combination of strain energy released across the reaction coordinate and the critical intramolecular distance between reacting diynes explains reactivity differences. Where experimental and calculated barrier heights are in disagreement, higher level multireference treatment of the enediynes confirms lower level estimates. Previous work concerning the chemically reactive fragment of esperamcin, MTC, is expanded to our model system MTC2.