NIX-mediated mitophagy regulate metabolic reprogramming in phagocytic cells during mycobacterial infection.

RNASeq analysis of PBMCs from treatment naïve TB patients and healthy controls revealed that M. tuberculosis (Mtb) infection dysregulates several metabolic pathways and upregulates BNIP3L/NIX receptor mediated mitophagy. Analysis of publicly available transcriptomic data from the NCBI-GEO database indicated that M. bovis (BCG) infection also induces similar rewiring of metabolic and mitophagy pathways. Mtb chronic infection and BCG in-vitro infection both downregulated oxidative phosphorylation and upregulated glycolysis and mitophagy; therefore, we used non-pathogenic mycobacterial species BCG as a model for Mtb infection to gain molecular insights and outcomes of this phenomenon. BCG infection in PBMCs and THP-1 macrophages induce mitophagy and glycolysis, leading to differentiation of naïve macrophage to M1 phenotype. Glucose consumption and lactate production were quantified by NMR, while the mitochondrial mass assessment was performed by mitotracker red uptake assay. Infected macrophages predominantly exhibit M1-phenotype, which is indicated by an increase in M1 specific cytokines (IL-6, TNF-α, and IL-1ß) and increased NOS2/ARG1, CD86/CD206 ratio. NIX knockdown abrogates this upregulation of glycolysis, mitophagy, and secretion of pro-inflammatory cytokines in BCG infected cells, indicating that mycobacterial infection-induced immunometabolic changes are executed via NIX mediated mitophagy and are essential for macrophage differentiation and resolution of infection.

Bioengineered chimeric spider silk-uranium binding proteins.

Heavy metals constitute a source of environmental pollution. Here, novel functional hybrid biomaterials for specific interactions with heavy metals are designed by bioengineering consensus sequence repeats from spider silk of Nephila clavipes with repeats of a uranium peptide recognition motif from a mutated 33-residue of calmodulin protein from Paramecium tetraurelia. The self-assembly features of the silk to control nanoscale organic/inorganic material interfaces provides new biomaterials for uranium recovery. With subsequent enzymatic digestion of the silk to concentrate the sequestered metals, options can be envisaged to use these new chimeric protein systems in environmental engineering, including to remediate environments contaminated by uranium.