Active groups of bicyclomycin and the reaction with thiols

Natural products synthesis: enabling tools to penetrate Nature's secrets of biogenesis and biomechanism

Selected examples from our laboratory of how synthetic technology platforms developed for the total synthesis of several disparate families of natural products was harnessed to penetrate biomechanistic and/or biosynthetic queries is discussed. Unexpected discoveries of biomechanistic reactivity and/or penetrating the biogenesis of naturally occurring substances were made possible through access to substances available only through chemical synthesis. Hypothesis-driven total synthesis programs are emerging as very useful conceptual templates for penetrating and exploiting the inherent reactivity of biologically active natural substances. In many instances, new enabling synthetic technologies were required to be developed. The examples demonstrate the often untapped richness of complex molecule synthesis to provide powerful tools to understand, manipulate and exploit Nature's vast and creative palette of secondary metabolites.

Evidence for the location of bicyclomycin binding to the Escherichia coli transcription termination factor Rho

The commercial antibiotic bicyclomycin (Bcm) has been shown to target the essential transcription termination factor Rho in Escherichia coli. Little is known about the Bcm binding domain in Rho. A recent structure-activity relationship study led us to evaluate the reductive amination probe, 5a-(3-formylanilino)dihydrobicyclomycin (FD-Bcm). Biochemical studies showed that FD-Bcm possessed inhibitory activities comparable to Bcm in Rho-dependent ATPase and transcription termination assays. Incubation of Rho with FD-Bcm, ATP, and poly(C) followed by NaBH4 reduction and dialysis led to an appreciable loss of ATPase activity. Inclusion of Bcm with FD-Bcm in the reductive amination reaction protected Rho, indicating that Bcm and FD-Bcm competed for the same binding site in Rho. Incubation of Rho with FD-Bcm and poly(C) followed by NaBH4 reduction provided a sample with residual ATPase activity (12%). Mass spectrometric analysis indicated the presence of two proteins in an approximate 1.2:1 ratio, whose masses corresponded to wild-type Rho (47,010 Da) and lysine-modified Rho (47,417 Da), respectively. Trypsin digestion of the Rho sample followed by high performance liquid chromatography separation and tandem mass spectrometry analysis identified the site of modification as Lys181 within the combined tryptic fragment, Gly-Leu-Ile-Val-Ala-Pro-Pro-Lys-Ala-Gly-Lys (residues 174-184). Similar analysis of a lesser modified sample (following incubation with inclusion of ATP) showed that addition had again occurred at Lys181. These findings provide the first structural information concerning the site of Bcm binding in Rho.