The mechanical properties of bacteria are important for protecting cells against physical stress. The cell wall is the best-characterized cellular element contributing to bacterial cell mechanics; however, the biochemistry underlying its regulation and assembly is still not completely understood. Using a unique high-throughput biophysical assay, we identified genes coding proteins that modulate cell stiffness in the opportunistic human pathogen Pseudomonas aeruginosa. This approach enabled us to discover proteins with roles in a diverse range of biochemical pathways that influence the stiffness of P. aeruginosa cells. We demonstrate that d-Ala—a component of the peptidoglycan—is tightly regulated in cells and that its accumulation reduces expression of machinery that cross-links this material and decreases cell stiffness. This research demonstrates that there is much to learn about mechanical regulation in bacteria, and these studies revealed new nonessential P. aeruginosa targets that may enhance antibacterial chemotherapies or lead to new approaches.
The ribosomally produced antimicrobial peptides of bacteria (bacteriocins) represent an unexplored source of membrane-active antibiotics. We designed a library of linear peptides from a circular bacteriocin and show that pore-formation dynamics in bacterial membranes are tunable via selective amino acid substitution. We observed antibacterial interpeptide synergy indicating that fundamentally altering interactions with the membrane enables synergy. Our findings suggest an approach for engineering pore-formation through rational peptide design and increasing the utility of novel antimicrobial peptides by exploiting synergy.
Bacteria sense environmental stressors and activate responses to improve their survival in harsh growth conditions. Neutrophils respond to the presence of bacteria by producing oxidative antibacterial species including hypochlorous acid (HOCl). However, the extent that bacteria detect activated neutrophils or HOCl has not been known. Here, we report that the opportunistic bacterial pathogen Pseudomonas aeruginosa responds to activated neutrophils by activating the fro system, which regulates the expression of antioxidative factors. We show that this response is specific to HOCl and that other oxidative factors including H2O2, do not trigger a fro response. The fro system has been previously shown to detect flow that is present in host vasculature, such as in animal circulatory systems. Our data thus suggest a model in which fro serves as an early host detection system in P. aeruginosa that improves its survival against neutrophil-mediated defenses, which could promote colonization in human tissue and increase pathogenicity.
Tuberculosis
(TB) is the most lethal bacterial infectious disease
worldwide. It is notoriously difficult to treat, requiring a cocktail
of antibiotics administered over many months. The dense, waxy outer
membrane of the TB-causing agent, Mycobacterium tuberculosis (Mtb), acts as a formidable barrier against uptake of antibiotics.
Subsequently, enzymes involved in maintaining the integrity of the
Mtb cell wall are promising drug targets. Recently, we demonstrated
that Mtb lacking malic enzyme (MEZ) has altered cell wall lipid composition
and attenuated uptake by macrophages. These results suggest that MEZ
contributes to lipid biosynthesis by providing reductants in the form
of NAD(P)H. Here, we present the X-ray crystal structure of MEZ to
3.6 Å. We use biochemical assays to demonstrate MEZ is dimeric
in solution and to evaluate the effects of pH and allosteric regulators
on its kinetics and thermal stability. To assess the interactions
between MEZ and its substrate malate and cofactors, Mn2+ and NAD(P)+, we ran a series of molecular dynamics (MD)
simulations. First, the MD analysis corroborates our empirical observations
that MEZ is unusually flexible, which persists even with the addition
of substrate and cofactors. Second, the MD simulations reveal that
dimeric MEZ subunits alternate between open and closed states, and
that MEZ can stably bind its NAD(P)+ cofactor in multiple
conformations, including an inactive, compact NAD+ form.
Together the structure of MEZ and insights from its dynamics can be
harnessed to inform the design of MEZ inhibitors that target Mtb and
not human malic enzyme homologues.
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