NICOTINAMIDE-ADENINE DINUCLEOTIDE-GLYCOHYDROLASE ACTIVITY IN EXPERIMENTAL TUBERCULOSIS

Niacinamide Antimicrobial Efficacy and Its Mode of Action via Microbial Cell Cycle Arrest

Niacinamide is a versatile compound widely used in the personal care industry for its ample skin benefits. As a precursor to nicotinamide adenine dinucleotide (NAD+), essential for ATP production and a substrate for poly-ADP-ribose polymerase-1 (PARP-1), studies have highlighted its roles in DNA repair, cellular stress mechanisms, and anti-aging benefits. Niacinamide was also studied for its antimicrobial activity, particularly in the context of host-infection via host immune response, yet its direct antimicrobial activity and the mechanisms of action remain unclear. Its multifunctionality makes it an appealing bioactive molecule for skincare products as well as a potential preservative solution. This study explores niacinamide's antimicrobial mode of action against four common cosmetic pathogens. Our findings indicate that niacinamide is causing microbial cell cycle arrest; while cells were found to increase their volume and length under treatment to prepare for cell division, complete separation into two daughter cells was prevented. Fluorescence microscopy revealed expanded chromatin, alongside a decreased RNA expression of the DNA-binding protein gene, dps. Finally, niacinamide was found to directly interact with DNA, hindering successful amplification. These unprecedented findings allowed us to add a newly rationalized preservative facete to the wide range of niacinamide multi-functionality.

Comprehensive Examination of the Mouse Lung Metabolome Following Mycobacterium tuberculosis Infection Using a Multiplatform Mass Spectrometry Approach

The mechanisms whereby Mycobacterium tuberculosis (Mtb) rewires the host metabolism in vivo are surprisingly unexplored. Here, we used three high-resolution mass spectrometry platforms to track altered lung metabolic changes associated with Mtb infection of mice. The multiplatform data sets were merged using consensus orthogonal partial least squares-discriminant analysis (cOPLS-DA), an algorithm that allows for the joint interpretation of the results from a single multivariate analysis. We show that Mtb infection triggers a temporal and progressive catabolic state to satisfy the continuously changing energy demand to control infection. This causes dysregulation of metabolic and oxido-reductive pathways culminating in Mtb-associated wasting. Notably, high abundances of trimethylamine-N-oxide (TMAO), produced by the host from the bacterial metabolite trimethylamine upon infection, suggest that Mtb could exploit TMAO as an electron acceptor under anaerobic conditions. Overall, these new pathway alterations advance our understanding of the link between Mtb pathogenesis and metabolic dysregulation and could serve as a foundation for new therapeutic intervention strategies. Mass spectrometry data has been deposited in the Metabolomics Workbench repository (data-set identifier: ST001328).

NAD glycohydrolase: enzyme characterization using intact mammalian erythrocytes

1. NADase activity has been determined on intact erythrocytes of several species. 2. Although a wide range in maximum velocity exists across species, Michaelis constants observed are very similar. 3. The enzyme is found on the outer surface of the erythrocyte plasma membrane. 4. It is inhibited by substrate after an apparent permanent modification. 5. This modification may be due to self ADP-ribosylation. 6. We have also demonstrated the presence of an ADP-ribosyltransferase on the outer surface of the sheep erythrocyte membrane.

Purification and comparative properties of the glycoprotein nicotinamide adenine dinucleotide glycohydrolase from rat liver microsomal and plasma membranes

NAD glycohydrolase, or NADase (NAD+ glycohydrolase, EC 3.2.2.5) was solubilized with porcine pancreatic lipase from isolated fractions of microsomes and plasma membranes obtained from rat livers. The enzyme from each organelle was further purified by DEAE-cellulose chromatography, gel filtration and isoelectric focusing. The solubilized, partially purified enzymes had similar molecular weights, pH-activity profiles and Km values. Marked charge heterogeneity was observed for the microsomal enzyme on isoelectric focusing between pH 6 and 8 with maximum activity focusing at pH 8.0. Plasma membrane NADase displayed a single peak at pH 6.7. Treatment of the partially purified microsomal or plasma membrane enzyme with neuraminidase resulted in a single peak of activity on isoelectric focusing (pH 3.5--10) with a pI of 9.2. Polyacrylamide gel electrophoresis of either NADase revealed a periodate-Schiff positive band which was coincident with enzyme activity. Compositional analyses of the microsomal enzyme focusing at pH 8.0 confirmed the presence of hexoses, hexosamines and sialic acid. Differences in carbohydrate composition might be important in determining the subcellular distribution of this enzyme.