Biochemical basis for the regulation of biosynthesis of antiparasitics by bacterial hormones.

Diffusible small molecule microbial hormones drastically alter the expression profiles of antibiotics and other drugs in actinobacteria. For example, avenolide (a butenolide) regulates the production of avermectin, derivatives of which are used in the treatment of river blindness and other parasitic diseases. Butenolides and γ-butyrolactones control the production of pharmaceutically important secondary metabolites by binding to TetR family transcriptional repressors.

Structure-Guided Analyses of a Key Enzyme Involved in the Biosynthesis of an Antivitamin.

RosB catalyzes the formation of 8-aminoriboflavin 5'-phosphate (AFP), the key intermediate in roseoflavin biosynthesis, from the metabolic precursors riboflavin 5'-phosphate (RP, also known as FMN) and glutamate. The conversion of the aromatic methyl group at position 8 in RP into the aromatic amine in AFP occurs via two intermediates, namely, the aldehyde 8-formyl-RP and the acid 8-carboxy-RP. To gain insights into the mechanism for this chemically challenging transformation, we utilized a structure-based approach to identify active site variants of RosB that stall the reaction at various points along the reaction coordinate.

Integrating Display and Delivery Functionality with a Cell Penetrating Peptide Mimic as a Scaffold for Intracellular Multivalent Multitargeting.

The construction of a multivalent ligand is an effective way to increase affinity and selectivity toward biomolecular targets with multiple-ligand binding sites. Adopting this strategy, we used a known cell-penetrating peptide (CPP) mimic as a scaffold to develop a series of multivalent ligand constructs that bind to the expanded dCTG (CTG(exp)) and rCUG nucleotide repeats (CUG(exp)) known to cause myotonic dystrophy type I (DM1), an incurable neuromuscular disease. By assembling this polyvalent construct, the hydrophobic ligands are solubilized and delivered into cell nuclei, and their enhanced binding affinity leads to the inhibition of ribonuclear foci formation and a reversal of splicing defects, all at low concentrations.