Pentacyclic nitrofurans that rapidly kill nifurtimox-resistant trypanosomes.

OBJECTIVES: In response to reports of Trypanosoma brucei resistance to the nitroaromatic drug nifurtimox, we evaluated the potential of antituberculosis nitrofuran isoxazolines as inhibitors of trypanosome growth. METHODS: The susceptibility of T. brucei brucei was assessed in vitro. The lowest effective concentration to inhibit growth (EC90) against drug-susceptible and -resistant parasites, time-kill kinetics, reversibility of inhibition and propensity for P-glycoprotein-mediated exclusion from the blood-brain barrier were determined. RESULTS: Nitrofuran isoxazolines were potent inhibitors of T. brucei brucei proliferation at nanomolar concentrations, with pentacyclic nitrofurans being 100-fold more potent than nifurtimox. Activity was sustained against nifurtimox-resistant parasites, suggesting the possibility of a unique mechanism of activation and potential for use in the treatment of drug-resistant infections. Exposure of parasites to the maximum concentrations of Compound 15 achieved in vivo with oral dosing yielded >2 logs of irreversible killing in <4 h, indicating rapid trypanocidal activity. CONCLUSIONS: Pentacyclic nitrofuran isoxazolines warrant further development for the treatment of drug-susceptible and nifurtimox-resistant trypanosome infections.

Mechanistic Insight on the Mode of Action of Colletoic Acid.

The natural product colletoic acid (CA) is a selective inhibitor of 11ß-hydroxysteroid dehydrogenase type 1 (11ß-HSD1), which primarily converts cortisone to the active glucocorticoid (GC) cortisol. Here, CA's mode of action and its potential as a chemical tool to study intracellular GC signaling in adipogenesis are disclosed. 11ß-HSD1 biochemical studies of CA indicated that its functional groups at C-1, C-4, and C-9 were important for enzymatic activity; an X-ray crystal structure of 11ß-HSD1 bound to CA at 2.6 Å resolution revealed the nature of those interactions, namely, a close-fitting and favorable interactions between the constrained CA spirocycle and the catalytic triad of 11ß-HSD1. Structure-activity relationship studies culminated in the development of a superior CA analogue with improved target engagement. Furthermore, we demonstrate that CA selectively inhibits preadipocyte differentiation through 11ß-HSD1 inhibition, suppressing other relevant key drivers of adipogenesis (i.e., PPARγ, PGC-1α), presumably by negatively modulating the glucocorticoid signaling pathway. The combined findings provide an in-depth evaluation of the mode of action of CA and its potential as a tool compound to study adipose tissue and its implications in metabolic syndrome.

The Supragingival Biofilm in Early Childhood Caries: Clinical and Laboratory Protocols and Bioinformatics Pipelines Supporting Metagenomics, Metatranscriptomics, and Metabolomics Studies of the Oral Microbiome.

Early childhood caries (ECC) is a biofilm-mediated disease. Social, environmental, and behavioral determinants as well as innate susceptibility are major influences on its incidence; however, from a pathogenetic standpoint, the disease is defined and driven by oral dysbiosis. In other words, the disease occurs when the natural equilibrium between the host and its oral microbiome shifts toward states that promote demineralization at the biofilm-tooth surface interface. Thus, a comprehensive understanding of dental caries as a disease requires the characterization of both the composition and the function or metabolic activity of the supragingival biofilm according to well-defined clinical statuses. However, taxonomic and functional information of the supragingival biofilm is rarely available in clinical cohorts, and its collection presents unique challenges among very young children. This paper presents a protocol and pipelines available for the conduct of supragingival biofilm microbiome studies among children in the primary dentition, that has been designed in the context of a large-scale population-based genetic epidemiologic study of ECC. The protocol is being developed for the collection of two supragingival biofilm samples from the maxillary primary dentition, enabling downstream taxonomic (e.g., metagenomics) and functional (e.g., transcriptomics and metabolomics) analyses. The protocol is being implemented in the assembly of a pediatric precision medicine cohort comprising over 6000 participants to date, contributing social, environmental, behavioral, clinical, and biological data informing ECC and other oral health outcomes.