Cadaverine biosynthesis contributes to decreased Escherichia coli susceptibility to antibiotics.

Some bacterial stress responses are involved in survival under antibiotic treatment and contribute to less susceptible microbial forms selection. Here, we tested the role of cadaverine, one of the biogenic polyamines considered as universal adaptogens, in the processes. The expression of ldcC and cadA genes, encoding cadaverine-producing lysine decarboxylase, increased in Escherichia coli cells exposed to β-lactams and fluoroquinolones but not aminoglycosides.

A synthetic diterpene analogue inhibits mycobacterial persistence and biofilm formation by targeting (p)ppGpp synthetases.

Bacterial persistence coupled with biofilm formation is directly associated with failure of antibiotic treatment of tuberculosis. We have now identified 4-(4,7-DiMethyl-1,2,3,4-tetrahydroNaphthalene-1-yl)Pentanoic acid (DMNP), a synthetic diterpene analogue, as a lead compound that was capable of suppressing persistence and eradicating biofilms in Mycobacterium smegmatis. By using two reciprocal experimental approaches - Δrel and ΔrelZ gene knockout mutations versus rel and relZ overexpression technique - we showed that both Rel and RelZ (p)ppGpp synthetases are plausible candidates for serving as targets for DMNP.

possesses operational agmatinase but contains no detectable polyamines.

Background: Polyamines are widespread intracellular molecules able to influence antibiotic susceptibility, but almost nothing is known on their occurrence and physiological role in mycobacteria.

Methods: here, we analyzed transcriptomic, proteomic and biochemical data and obtained the first evidence for the post-transcriptional expression of some genes attributed to polyamine metabolism and polyamine transport in Mycolicibacterium smegmatis (basionym Mycobacterium smegmatis).

Results: in our experiments, exponentially growing cells demonstrated transcription of 21 polyamine-associated genes and possessed 7 enzymes of polyamine metabolism and 2 polyamine transport proteins.

ATP/ADP alteration as a sign of the oxidative stress development in Escherichia coli cells under antibiotic treatment.

The extensively discussed idea of oxidative stress development under antibiotic treatment was confirmed using an antioxidant gene expression (soxRS-, oxyR-regulon) approach, including microaerobic cultivation conditions. The killing action of antibiotics and their ability to cause peroxide oxidative stress in Escherichia coli cells was comparable to a similar hydrogen peroxide capacity; therefore, the involvement of intracellular hydrogen peroxide production in the killing action of antibiotics seems plausible under conditions studied. The temporary increase of ATP/ADP (which returned to untreated levels in 10 min) and the intensification of respiration preceded the development of oxidative stress.

Polyamines reduce oxidative stress in Escherichia coli cells exposed to bactericidal antibiotics.

Bactericidal antibiotics (fluoroquinolones, aminoglycosides and cephalosporins) at their sublethal concentrations were able to produce hydroxyl radicals, hydrogen peroxide and superoxide anions (ROS) in Escherichia coli cells, which resulted in damage to proteins and DNA. The cells responded to oxidative stress by a 2-3-fold increase in cell polyamines (putrescine, spermidine) produced as a consequence of upregulation of ornithine decarboxylase (ODC). Relief of oxidative stress by cessation of culture aeration or addition of antioxidants substantially diminished or even completely abolished polyamine accumulation observed in response to antibiotics.