Electron paramagnetic resonance spin label titration: a novel method to investigate random and site-specific immobilization of enzymes onto polymeric membranes with different properties

The immobilization of biological molecules onto polymeric membranes to produce biofunctional membranes is used for selective catalysis, separation, analysis, and artificial organs. Normally, random immobilization of enzymes onto polymeric membranes leads to dramatic reduction in activity due to chemical reactions involved in enzyme immobilization, multiple-point binding, etc., and the extent of activity reduction is a function of membrane hydrophilicity (e.g. activity in cellulosic membrane?polysulfone membrane). We have used molecular biology to effect site-specific immobilization of enzymes in a manner that orients the active site away from the polymeric membrane surface, thus resulting in higher enzyme activity that approaches that in solution and in increased stability of the enzyme relative to the enzyme in solution. A prediction of this site-specific method of enzyme immobilization, which in this study with subtilisin and organophosphorus hydrolase consists of a fusion tag genetically added to these enzymes and subsequent immobilization via the anti-tag antibody and membrane-bound protein A, is that the active site conformation will more closely resemble that of the enzyme in solution than is the case for random immobilization. This hypothesis was confirmed using a new electron paramagnetic resonance (EPR) spin label active site titration method that determines the amount of spin label bound to the active site of the immobilized enzyme. This value nearly perfectly matched the enzyme activity, and the results suggested: (a) a spectroscopic method for measuring activity and thus the extent of active enzyme immobilization in membrane, which may have advantages in cases where optical methods can not be used due to light scattering interference; (b) higher spin label incorporation (and hence activity) in enzymes that had been site-specifically immobilized versus random immobilization; (c) higher spin label incorporation in enzymes immobilized onto hydrophilic bacterial cellulose membranes versus hydrophobic modified poly(ether)sulfone membranes. These results are discussed with reference to analysis and utilization of biofunctional membranes.     

Minimalist protein design: a beta-hairpin peptide that binds ssDNA

A 28-residue beta-hairpin dimer (WKWK)2 with two Trp and two Lys residues on one face of each beta-sheet was shown to form a complex with single-stranded oligonucleotides at low micromolar concentrations. Each beta-hairpin of the dimer contains a cross-strand Trp-Trp pair in a diagonal orientation which has previously been shown to create a cleft for the intercalation of aromatic guests such as adenine (J. Am. Chem. Soc. 2003, 125, 9580). The beta-hairpin dimer binds 5-residue ssDNA sequences 5'-AAAAA-3', 5'-TTTTT-3', and 5'-CCCCC-3' in water with dissociation constants in the range of 12-30 muM. A weak energetic preference for binding to sequence 5'-AAAAA-3' was observed, which is believed to result from stronger stacking interactions between Trp and the adenine base. The interaction of 5'-AAAAA-3' with the Lys and Trp residues of the peptide was evident by NMR, and a 1:1 association was demonstrated. The recognition of an 11-residue ssDNA sequence occurred with a dissociation constant of 3 muM under near-physiological ionic strength and pH, demonstrating that the beta-hairpin dimer binds ssDNA as strongly as many naturally occurring proteins. The salt dependence of the interaction of the 11-residue oligonucleotide with the peptide dimer indicates that Trp-nucleobase stacking interactions contribute about -4 kcal/mol to recognition, which is much greater than the contribution of nonionic interactions in unstructured peptides containing Trp. Moreover, recognition of the ssDNA demonstrated reduced salt dependence relative to the corresponding duplex, resulting in selectivity for ssDNA under high salt conditions. Peptide (WKWK)2 is a relevant mimic of OB-fold (oligonucleotide/oligosaccharide-binding) proteins which bind ssDNA on the surface of a beta-sheet.     

Determination of gadolinium-based MRI contrast agents in biological and environmental samples: A review

The development of analytical methods and strategies to determine gadolinium and its complexes in biological and environmental matrices is evaluated in this review.     

Genetic Manipulation of the Fusarium fujikuroi Fusarin Gene Cluster Yields Insight into the Complex Regulation and Fusarin Biosynthetic Pathway

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Photoactivatable V-Shaped Bifunctional Quinone Methide Precursors as a New Class of Selective G-quadruplex Alkylating Agents

Combining the selectivity of G-quadruplex (G4) ligands with the spatial and temporal control of photochemistry is an emerging strategy to elucidate the biological relevance of these structures. In this work, we developed six novel V-shaped G4 ligands that can, upon irradiation, form stable covalent adducts with G4 structures via the reactive intermediate, quinone methide (QM). We thoroughly investigated the photochemical properties of the ligands and their ability to generate QMs. Subsequently, we analyzed their specificity for various topologies of G4 and discovered a preferential binding towards the human telomeric sequence. Finally, we tested the ligand ability to act as photochemical alkylating agents, identifying the covalent adducts with G4 structures. This work introduces a novel molecular tool in the chemical biology toolkit for G4s.     

Exploiting the Potential of Meroterpenoid Cyclases to Expand the Chemical Space of Fungal Meroterpenoids

Fungal meroterpenoids are a diverse group of hybrid natural products with impressive structural complexity and high potential as drug candidates. In this work, we evaluate the promiscuity of the early structure diversity-generating step in fungal meroterpenoid biosynthetic pathways: the multibond-forming polyene cyclizations catalyzed by the yet poorly understood family of fungal meroterpenoid cyclases. In total, 12 unnatural meroterpenoids were accessed chemoenzymatically using synthetic substrates. Their complex structures were determined by 2D NMR studies as well as crystalline-sponge-based X-ray diffraction analyses. The results obtained revealed a high degree of enzyme promiscuity and experimental results which together with quantum chemical calculations provided a deeper insight into the catalytic activity of this new family of non-canonical, terpene cyclases. The knowledge obtained paves the way to design and engineer artificial pathways towards second generation meroterpenoids with valuable bioactivities based on combinatorial biosynthetic strategies.