Project description:Nitrosomonas europaea carries numerous toxin-antitoxin systems. However, despite the abundant representation in its chromosome, studies have not surveyed the underlying molecular functions in detail, and their biological roles remain enigmatic. In the present study, we found that a chromosomally-encoded MazF family member, predicted at the locus NE1181, is a functional toxin endoribonuclease, and constitutes a toxin-antitoxin system, together with its cognate antitoxin, MazE. Massive parallel sequencing provided strong evidence that this toxin endoribonuclease exhibits RNA cleavage activity, primarily against the AAU triplet. This sequence-specificity was supported by the results of fluorometric assays. Our results indicate that N. europaea alters the translation profile and regulates its growth using the MazF family of endoribonuclease under certain stressful conditions.

Project description:The Mycobacterium tuberculosis genome contains an unusually high number of toxin-antitoxin modules, some of which have been suggested to play a role in the establishment and maintenance of latent tuberculosis. Nine of these toxin-antitoxin loci belong to the mazEF family, encoding the intracellular toxin MazF and its antitoxin inhibitor MazE. Nearly every MazF ortholog recognizes a unique three- or five-base RNA sequence and cleaves mRNA. As a result, these toxins selectively target a subset of the transcriptome for degradation and are known as "mRNA interferases." Here we demonstrate that a MazF family member from M. tuberculosis, MazF-mt6, has an additional role--inhibiting translation through targeted cleavage of 23S rRNA in the evolutionarily conserved helix/loop 70. We first determined that MazF-mt6 cleaves mRNA at (5')UU?CCU(3') sequences. We then discovered that MazF-mt6 also cleaves M. tuberculosis 23S rRNA at a single UUCCU in the ribosomal A site that contacts tRNA and ribosome recycling factor. To gain further mechanistic insight, we demonstrated that MazF-mt6-mediated cleavage of rRNA can inhibit protein synthesis in the absence of mRNA cleavage. Finally, consistent with the position of 23S rRNA cleavage, MazF-mt6 destabilized 50S-30S ribosomal subunit association. Collectively, these results show that MazF toxins do not universally act as mRNA interferases, because MazF-mt6 inhibits protein synthesis by cleaving 23S rRNA in the ribosome active center.

Project description:Bacterial toxin-antitoxin systems are thought to help bacteria to reduce their metabolism in various stressful conditions. Many toxins of the bacterial toxin-antitoxin systems are ribonucleases. Such toxins have been mostly viewed as degraders of mRNA, however recently it was demonstrated that they are also capable of cleaving non-coding RNA. MazF toxin is also hypothesized to reprogram E. colis translational machinery. Current cDNA libraries are part of a project which aims to identify the major RNA cleavage sites (in mRNA, rRNA and regulatory non-coding RNA) of MazF and MqsR toxins in E. coli. We wanted to elaborate on the roles of MazF and MqsR in E. coli: is MazF really involved in reprogramming the translational machinery or is MazF, along with MqsR, just a robust cleaver of RNA? We extracted total RNA from cultures where the expression of MazF or MqsR was induced for 2h and from cultures that had been recovering from toxin production for 30 minutes; RNA from log phase culture was used as the control. We used strand specific random primed paired end RNA sequencing data to locate the major cleavage sites. To map the cleavage sites, we counted 5’ end stacks of forward reads in each genomic position and compared them with total coverage. MazF and MqsR cleave at specific recognition sequences, ˇACA and GˇC respectively, which allowed us to eliminate the false positives. One of our initial aims was also to look for irregular RNA ligation events following toxin expression, thus we used long, 300 base reads in sequencing.

Project description:Clostridium difficile is an important, emerging nosocomial pathogen. The transition from harmless colonization to disease is typically preceded by antimicrobial therapy, which alters the balance of the intestinal flora, enabling C. difficile to proliferate in the colon. One of the most perplexing aspects of the C. difficile infectious cycle is its ability to survive antimicrobial therapy and transition from inert colonization to active infection. Toxin-antitoxin (TA) systems have been implicated in facilitating persistence after antibiotic treatment. We identified only one TA system in C. difficile strain 630 (epidemic type X), designated MazE-cd and MazF-cd, a counterpart of the well-characterized Escherichia coli MazEF TA system. This E. coli MazF toxin cleaves mRNA at ACA sequences, leading to global mRNA degradation, growth arrest, and death. Likewise, MazF-cd expression in E. coli or Clostridium perfringens resulted in growth arrest. Primer extension analysis revealed that MazF-cd cleaved RNA at the five-base consensus sequence UACAU, suggesting that the mRNAs susceptible to cleavage comprise a subset of total mRNAs. In agreement, we observed differential cleavage of several mRNAs by MazF-cd in vivo, revealing a direct correlation between the number of cleavage recognition sites within a given transcript and its susceptibility to degradation by MazF-cd. Interestingly, upon detailed statistical analyses of the C. difficile transcriptome, the major C. difficile virulence factor toxin B (TcdB) and CwpV, a cell wall protein involved in aggregation, were predicted to be significantly resistant to MazF-cd cleavage.

Project description:Bacterial toxin-antitoxin systems help bacteria to reduce their metabolism in various stressful conditions and also play a part in generating antibiotic tolerant bacterial subpopulation called persisters. Many toxins of the bacterial toxin-antitoxin systems are ribonucleases. Such toxins have been mostly viewed as degraders of mRNA, however recently it was demonstrated that they are also capable of cleaving non-coding RNA. Current libraries are a part of a project which aims to identify the major RNA cleavage sites (in mRNA, rRNA and regulatory non-coding RNA) of MazF and MqsR toxins in E. coli. We were also interested in the activity of promoters during toxin overexpression. We used a targeted RNA-sequencing approach that allowed us to map the distinct 5- and 3-ends of toxin-cleaved RNA and also the beginnings of transcripts. We extracted total RNA from cultures where the expression of MazF or MqsR was induced; RNA from log phase culture was used as the control. In addition, RNA extracted from stationary phase culture was used to test for the possible toxin cleavage in natural stress conditions. The cleaved RNA is rapidly recycled making it possible that we miss important cleavage sites due to RNA degradation during the prolonged stationary phase. Therefore, in addition to wt E. coli we also used stationary phase RNA from exoribonuclease deficient strain where RNA cleavage products accumulate. Identification of the 5 ends is based on ligation of RNA adapters to the cellular RNA molecules, which requires 5 -monophosphates. Mapping of the 3 -ends is based on poly(A) tailing of RNA, which requires 3 -OH groups. Transcription initiation, ordinary cellular RNases, and toxin endonucleases all produce different types of RNA ends. These can be enzymatically converted to 5 -phosphates and 3 -OHs, which allows one to separately quantify the RNA ends produced by each of these processes from a single biological sample. Briefly, (i) primary transcripts have 5 -triphosphate ends that can be converted to monophosphate by Tobacco Acid Pyrophosphatase (TAP), and 3 -hydroxyl ends that can be directly polyadenylated by poly(A) polymerase. (ii) Most cellular RNases (excluding RNase I and the toxins) produce 5 -monophosphates and 3 -hydroxyls, which are directly usable for ligation/polyadenylation. (iii) RNase I, MazF, and several other toxins produce 5 -hydroxyl ends that need to be phosphorylated by T4 Polynucleotide Kinase (PNK) prior to ligation, and 2,3 -cyclic phosphates that need to be dephosphorylated and converted to 3 -hydroxyls, also by T4 PNK. In short, for each of our RNA samples three 5 end and two 3 end libraries were made. The PNK treated libraries contain reads mapping specifically to 5- or 3-ends left by toxin (or RNaseI) cleavage and TAP treated libraries have extra reads mapping to beginnings of the transcripts.

Project description:Toxin-antitoxin (TA) systems play key roles in bacterial persistence, biofilm formation and stress responses. The MazF toxin from the Escherichia coli mazEF TA system is a sequence- and single-strand-specific endoribonuclease, and many studies have led to the proposal that MazF family members exclusively target mRNA. However, recent data indicate some MazF toxins can cleave specific sites within rRNA in concert with mRNA. In this report, we identified the repertoire of RNAs cleaved by Mycobacterium tuberculosis toxin MazF-mt9 using an RNA-seq-based approach. This analysis revealed that two tRNAs were the principal targets of MazF-mt9, and each was cleaved at a single site in either the tRNA(Pro14) D-loop or within the tRNA(Lys43) anticodon. This highly selective target discrimination occurs through recognition of not only sequence but also structural determinants. Thus, MazF-mt9 represents the only MazF family member known to target tRNA and to require RNA structure for recognition and cleavage. Interestingly, the tRNase activity of MazF-mt9 mirrors basic features of eukaryotic tRNases that also generate stable tRNA-derived fragments that can inhibit translation in response to stress. Our data also suggest a role for tRNA distinct from its canonical adapter function in translation, as cleavage of tRNAs by MazF-mt9 downregulates bacterial growth.

Project description:Toxin-antitoxin systems are widely distributed genetic modules that regulate growth and persistence in bacteria. Many systems, including E. coli MazEF, include toxins that are endoribonucleases, but the full set of targets for these toxins remains poorly defined. Previous studies on a limited set of transcripts suggested that MazF creates a pool of leaderless mRNAs that are preferentially translated by specialized ribosomes created through MazF cleavage of mature 16S rRNA. Here, using paired-end RNA sequencing (RNA-seq) and ribosome profiling, we provide a comprehensive, global analysis of MazF cleavage specificity and its targets. We find that MazF cleaves most transcripts at multiple sites within their coding regions, with very few full-length, leaderless mRNAs created. Additionally, our results demonstrate that MazF does not create a large pool of specialized ribosomes but instead rapidly disrupts ribosome biogenesis by targeting both ribosomal protein transcripts and rRNA precursors, helping to inhibit cell growth.

Project description:A crucial bacterial strategy to avoid killing by antibiotics is to enter a growth arrested state, yet the molecular mechanisms behind this process remain elusive. The conditional overexpression of mazF, the endoribonuclease toxin of the MazEF toxin-antitoxin system in Staphylococcus aureus, is one approach to induce bacterial growth arrest, but its targets remain largely unknown. We used overexpression of mazF and high-throughput sequence analysis following the exact mapping of non-phosphorylated transcriptome ends (nEMOTE) technique to reveal in vivo toxin cleavage sites on a global scale. We obtained a catalogue of MazF cleavage sites and unearthed an extended MazF cleavage specificity that goes beyond the previously reported one. We correlated transcript cleavage and abundance in a global transcriptomic profiling during mazF overexpression. We observed that MazF affects RNA molecules involved in ribosome biogenesis, cell wall synthesis, cell division and RNA turnover and thus deliver a plausible explanation for how mazF overexpression induces stasis. We hypothesize that autoregulation of MazF occurs by directly modulating the MazEF operon, such as the rsbUVW genes that regulate the sigma factor SigB, including an observed cleavage site on the MazF mRNA that would ultimately play a role in entry and exit from bacterial stasis.

Project description:mRNA interferases are sequence-specific endoribonucleases encoded by toxin-antitoxin (TA) systems in bacterial genomes. Previously, we demonstrated that Mycobacterium tuberculosis contains at least seven genes encoding MazF homologues (MazF-mt1 to -mt7) and determined cleavage specificities for MazF-mt1 and MazF-mt6. Here we have developed a new general method for the determination of recognition sequences longer than three bases for mRNA interferases with the use of phage MS2 RNA as a substrate and CspA, an RNA chaperone, which prevents the formation of secondary structures in the RNA substrate. Using this method, we determined that MazF-mt3 cleaves RNA at UU CCU or CU CCU and MazF-mt7 at U CGCU ( indicates the cleavage site). As pentad sequence recognition is more specific than those of previously characterized mRNA interferases, bioinformatics analysis was carried out to identify M. tuberculosis mRNAs that may be resistant to MazF-mt3 and MazF-mt7 cleavage. The pentad sequence was found to be significantly underrepresented in several genes, including members of the PE and PPE families, large families of proteins that play a role in tuberculosis immunity and pathogenesis. These data suggest that MazF-mt3 and MazF-mt7 or other mRNA interferases that target longer RNA sequences may alter protein expression through differential mRNA degradation, a regulatory mechanism that may allow adaptation to environmental conditions, including those encountered by pathogens such as M. tuberculosis during infection.

Project description:A crucial bacterial strategy to avoid killing by antibiotics is to enter a growth arrested state, yet the molecular mechanisms behind this process remain elusive. The conditional overexpression of MazF, the endoribonuclease toxin of the MazEF toxin-antitoxin system in Staphylococcus aureus, is one approach to induce bacterial growth arrest, but its targets remain largely unknown. We used overexpression of MazF and high-throughput sequence analysis following the exact mapping of non-phosphorylated transcriptome ends (nEMOTE) technique to reveal in vivo toxin cleavage sites on a global scale. We obtained a catalogue of MazF cleavage sites and unearthed an extended MazF cleavage specificity that goes beyond the previously reported one. We correlated transcript cleavage and abundance in a global transcriptomic profiling during mazF overexpression. We observed that MazF affects RNA molecules involved in ribosome biogenesis, cell wall synthesis, cell division and RNA turover and thus deliver a plausible explanation for how mazF overexpression induces stasis. We hypothesize that autoregulation of MazF occurs by directly modulating the MazEF operon, such as the rsbUVW genes that regulate the alternative SigB, including an observed cleavage site on the MazF mRNA that would ultimately play a role in entry and exit from bacterial stasis.