A cis‐acting antitoxin domain within the chromosomal toxin–antitoxin module EzeT of Escherichia coli quenches toxin activity

Toxin–antitoxin (TA) systems are widespread genetic modules in the genomes of bacteria and archaea emerging as key players that modulate bacterial physiology. They consist of two parts, a toxic component that blocks an essential cellular process and an antitoxin that inhibits this toxic activity during normal growth. According to the nature of the antitoxin and the mode of inhibition, TA systems are subdivided into different types. Here, we describe the characterization of a type II‐like TA system in Escherichia coli called EzeT. While in conventional type II systems the antitoxin is expressed in trans to form an inactive protein–protein complex, EzeT consists of two domains combining toxin and cis‐acting antitoxin functionalities in a single polypeptide chain. We show that the C‐terminal domain of EzeT is homologous to zeta toxins and is toxic in vivo. The lytic phenotype could be attributed to UDP‐N‐acetylglucosamine phosphorylation, so far only described for type II epsilon/zeta systems from Gram‐positive streptococci. Presence of the N‐terminal domain inhibits toxicity in vivo and strongly attenuates kinase activity. Autoinhibition by a cis‐acting antitoxin as described here for EzeT‐type TA systems can explain the occurrence of single or unusually large toxins, further expanding our understanding of the TA system network.     

The chromosomal SezAT toxin–antitoxin system promotes the maintenance of the SsPI‐1 pathogenicity island in epidemic Streptococcus suis

Streptococcus suis has emerged as a causative agent of human meningitis and streptococcal toxic shock syndrome over the last years. The high pathogenicity of S. suis may be due in part to a laterally acquired pathogenicity island (renamed SsPI‐1), which can spontaneously excise and transfer to recipients. Cells harboring excised SsPI‐1 can potentially lose this island if cell division occurs prior to its reintegration; however, attempts to cure SsPI‐1 from the host cells have been unsuccessful. Here, we report that an SsPI‐1‐borne Epsilon/Zeta toxin–antitoxin system (designated SezAT) promotes SsPI‐1 stability in bacterial populations. The sezAT locus consists of two closely linked sezT and sezA genes encoding a toxin and its cognate antitoxin, respectively. Overproduction of SezT induces a bactericidal effect that can be neutralized by co‐expression of SezA, but not by its later action. When devoid of a functional SezAT system, large‐scale deletion of SsPI‐1 is straightforward. Thus, SezAT serves to ensure inheritance of SsPI‐1 during cell division, which may explain the persistence of epidemic S. suis. This report presents the first functional characterization of TA loci in S. suis, and the first biochemical evidence for the adaptive significance of the Epsilon/Zeta system in the evolution of pathogen virulence.     

The toxin from a ParDE toxin‐antitoxin system found in Pseudomonas aeruginosa offers protection to cells challenged with anti‐gyrase antibiotics

Toxin‐antitoxin systems are mediators of diverse activities in bacterial physiology. For the ParE‐type toxins, their reported role of gyrase inhibition utilized during plasmid‐segregation killing indicates they are toxic. However, their location throughout chromosomes leads to questions about function, including potential non‐toxic outcomes. The current study has characterized a ParDE system from the opportunistic human pathogen Pseudomonas aeruginosa (Pa). We identified a protective function for this ParE toxin, PaParE, against effects of quinolone and other antibiotics. However, higher concentrations of PaParE are themselves toxic to cells, indicating the phenotypic outcome can vary based on its concentration. Our assays confirmed PaParE inhibition of gyrase‐mediated supercoiling of DNA with an IC₅₀ value in the low micromolar range, a species‐specificity that resulted in more efficacious inhibition of Escherichia coli derived gyrase versus Pa gyrase, and overexpression in the absence of antitoxin yielded an expected filamentous morphology with multi‐foci nucleic acid material. Additional data revealed that the PaParE toxin is monomeric and interacts with dimeric PaParD antitoxin with a K_D in the lower picomolar range, yielding a heterotetramer. This work provides novel insights into chromosome‐encoded ParE function, whereby its expression can impart partial protection to cultures from selected antibiotics.     

The novel type II toxin–antitoxin PacTA modulates Pseudomonas aeruginosa iron homeostasis by obstructing the DNA-binding activity of Fur

Type II toxin–antitoxin (TA) systems are widely distributed in bacterial and archaeal genomes and are involved in diverse critical cellular functions such as defense against phages, biofilm formation, persistence, and virulence. GCN5-related N-acetyltransferase (GNAT) toxin, with an acetyltransferase activity-dependent mechanism of translation inhibition, represents a relatively new and expanding family of type II TA toxins. We here describe a group of GNAT-Xre TA modules widely distributed among Pseudomonas species. We investigated PacTA (one of its members encoded by PA3270/PA3269) from Pseudomonas aeruginosa and demonstrated that the PacT toxin positively regulates iron acquisition in P. aeruginosa. Notably, other than arresting translation through acetylating aminoacyl-tRNAs, PacT can directly bind to Fur, a key ferric uptake regulator, to attenuate its DNA-binding affinity and thus permit the expression of downstream iron-acquisition-related genes. We further showed that the expression of the pacTA locus is upregulated in response to iron starvation and the absence of PacT causes biofilm formation defect, thereby attenuating pathogenesis. Overall, these findings reveal a novel regulatory mechanism of GNAT toxin that controls iron-uptake-related genes and contributes to bacterial virulence.     

An ADP‐ribosyltransferase Alt of bacteriophage T4 negatively regulates the Escherichia coli MazF toxin of a toxin–antitoxin module

Prokaryotic toxin–antitoxin (TA) systems are linked to many roles in cell physiology, such as plasmid maintenance, stress response, persistence and protection from phage infection, and the activities of toxins are tightly regulated. Here, we describe a novel regulatory mechanism for a toxin of Escherichia coli TA systems. The MazF toxin of MazE‐MazF, which is one of the best characterized type II TA systems, was modified immediately after infection with bacteriophage T4. Mass spectrometry demonstrated that the molecular weight of this modification was 542 Da, corresponding to a mono‐ADP‐ribosylation. This modification disappeared in cells infected with T4 phage lacking Alt, which is one of three ADP‐ribosyltransferases encoded by T4 phage and is injected together with phage DNA upon infection. In vivo and in vitro analyses confirmed that T4 Alt ADP‐ribosylated MazF at an arginine residue at position 4. Finally, the ADP‐ribosylation of MazF by Alt resulted in the reduction of MazF RNA cleavage activity in vitro, suggesting that it may function to inactivate MazF during T4 infection. This is the first example of the chemical modification of an E. coli toxin in TA systems to regulate activity.     

The Streptococcus pyogenes NAD+ glycohydrolase modulates epithelial cell PARylation and HMGB1 release

Streptococcus pyogenes uses the cytolysin streptolysin O (SLO) to translocate an enzyme, the S. pyogenes NAD⁺ glycohydrolase (SPN), into the host cell cytosol. However, the function of SPN in this compartment is not known. As a complication, many S. pyogenes strains express a SPN variant lacking NAD⁺ glycohydrolase (NADase) activity. Here, we show that SPN modifies several SLO‐ and NAD⁺‐dependent host cell responses in patterns that correlate with NADase activity. SLO pore formation results in hyperactivation of the cellular enzyme poly‐ADP‐ribose polymerase‐1 (PARP‐1) and production of polymers of poly‐ADP‐ribose (PAR). However, while SPN NADase activity moderates PARP‐1 activation and blocks accumulation of PAR, these processes continued unabated in the presence of NADase‐inactive SPN. Temporal analyses revealed that while PAR production is initially independent of NADase activity, PAR rapidly disappears in the presence of NADase‐active SPN, host cell ATP is depleted and the pro‐inflammatory mediator high‐mobility group box‐1 (HMGB1) protein is released from the nucleus by a PARP‐1‐dependent mechanism. In contrast, HMGB1 is not released in response to NADase‐inactive SPN and instead the cells release elevated levels of interleukin‐8 and tumour necrosis factor‐α. Thus, SPN and SLO combine to induce cellular responses subsequently influenced by the presence or absence of NADase activity.     

Augmentation of cellular NAD+ by NQO1 enzymatic action improves age‐related hearing impairment

Age‐related hearing loss (ARHL) is a major neurodegenerative disorder and the leading cause of communication deficit in the elderly population, which remains largely untreated. The development of ARHL is a multifactorial event that includes both intrinsic and extrinsic factors. Recent studies suggest that NAD⁺/NADH ratio may play a critical role in cellular senescence by regulating sirtuins, PARP‐1, and PGC‐1α. Nonetheless, the beneficial effect of direct modulation of cellular NAD⁺ levels on aging and age‐related diseases has not been studied, and the underlying mechanisms remain obscure. Herein, we investigated the effect of β‐lapachone (β‐lap), a known plant‐derived metabolite that modulates cellular NAD⁺ by conversion of NADH to NAD⁺ via the enzymatic action of NADH: quinone oxidoreductase 1 (NQO1) on ARHL in C57BL/6 mice. We elucidated that the reduction of cellular NAD⁺ during the aging process was an important contributor for ARHL; it facilitated oxidative stress and pro‐inflammatory responses in the cochlear tissue through regulating sirtuins that alter various signaling pathways, such as NF‐κB, p53, and IDH2. However, augmentation of NAD⁺ by β‐lap effectively prevented ARHL and accompanying deleterious effects through reducing inflammation and oxidative stress, sustaining mitochondrial function, and promoting mitochondrial biogenesis in rodents. These results suggest that direct regulation of cellular NAD⁺ levels by pharmacological agents may be a tangible therapeutic option for treating various age‐related diseases, including ARHL.     

Role of PemI in the Staphylococcus aureus PemIK toxin–antitoxin complex: PemI controls PemK by acting as a PemK loop mimic

Staphylococcus aureus is a notorious and globally distributed pathogenic bacterium. New strategies to develop novel antibiotics based on intrinsic bacterial toxin–antitoxin (TA) systems have been recently reported. Because TA systems are present only in bacteria and not in humans, these distinctive systems are attractive targets for developing antibiotics with new modes of action. S. aureus PemIK is a type II TA system, comprising the toxin protein PemK and the labile antitoxin protein PemI. Here, we determined the crystal structures of both PemK and the PemIK complex, in which PemK is neutralized by PemI. Our biochemical approaches, including fluorescence quenching and polarization assays, identified Glu20, Arg25, Thr48, Thr49, and Arg84 of PemK as being important for RNase function. Our study indicates that the active site and RNA-binding residues of PemK are covered by PemI, leading to unique conformational changes in PemK accompanied by repositioning of the loop between β1 and β2. These changes can interfere with RNA binding by PemK. Overall, PemK adopts particular open and closed forms for precise neutralization by PemI. This structural and functional information on PemIK will contribute to the discovery and development of novel antibiotics in the form of peptides or small molecules inhibiting direct binding between PemI and PemK.     

Inhibition of cell proliferation in Saccharomyces cerevisiae by expression of human NAD+ ADP-ribosyltransferase requires the DNA binding domain ("zinc fingers").

Summary Constitutive expression of human nuclear NAD⁺: protein ADP-ribosyltransferase (polymerizing) [pADPRT; poly(ADP-ribose)polymerase; EC 2.4.2.30] as an active enzyme in Saccharomyces cerevisiae, under the control of the alcohol dehydrogenase promoter, was only possible with simultaneous inhibition of ADP-ribosylation by 3-methoxybenzamide. Induction of fully active pADPRT from the inducible galactose epimerase promoter resulted in inhibition of cell division and morphological changes reminiscent of cell cycle mutants. Expression of a pADPRT cDNA truncated at its 5end had no influence on cell proliferation at all. Obviously the amino-terminal part of the DNA binding domain containing the first zinc finger, which is essential for inducibility of pADPRT activity by DNA breaks, is also required for inhibition of cell growth on expression in yeast. Full-length as well as truncated pADPRT molecules were directed to the cell nucleus where the fully active enzyme produced large amounts of poly(ADP-ribose) by automodification. Since pADPRT turned out to be the only target for ADP-ribosylation in these cells, elevated levels of poly(ADP-ribose) were the most likely cause of inhibition of cell division, presumably resulting from interaction with chromosomal proteins.     

Personal model‐assisted identification of NAD+ and glutathione metabolism as intervention target in NAFLD

To elucidate the molecular mechanisms underlying non‐alcoholic fatty liver disease (NAFLD), we recruited 86 subjects with varying degrees of hepatic steatosis (HS). We obtained experimental data on lipoprotein fluxes and used these individual measurements as personalized constraints of a hepatocyte genome‐scale metabolic model to investigate metabolic differences in liver, taking into account its interactions with other tissues. Our systems level analysis predicted an altered demand for NAD⁺ and glutathione (GSH) in subjects with high HS. Our analysis and metabolomic measurements showed that plasma levels of glycine, serine, and associated metabolites are negatively correlated with HS, suggesting that these GSH metabolism precursors might be limiting. Quantification of the hepatic expression levels of the associated enzymes further pointed to altered de novo GSH synthesis. To assess the effect of GSH and NAD⁺ repletion on the development of NAFLD, we added precursors for GSH and NAD⁺ biosynthesis to the Western diet and demonstrated that supplementation prevents HS in mice. In a proof‐of‐concept human study, we found improved liver function and decreased HS after supplementation with serine (a precursor to glycine) and hereby propose a strategy for NAFLD treatment.