Project description:Riboswitches are cis-acting regulating RNA elements mostly found in the 5’-UTR of bacterial mRNAs. The Salmonella enterica mgtA riboswitch controls mgtA expression upon the sensing of intracellular Mg2+ ions. A leader peptide (MgtL) is contained within the mgtA riboswitch and its translation has been previously shown to be affected by Mg2+ concentrations. The current regulatory model suggests that the efficiency of MgtL translation is inversely related to mgtA transcription. Herein we show that the orthologue mgtA riboswitch of Escherichia coli also contains a leader peptide but, unlike S. enterica, that its translation is proportionally related to mgtA expression. Our results also suggest that ribosome stalling at mgtL is crucial for mgtA expression. Together, our results indicate that in E. coli, the expression of the MgtL leader peptide and mgtA are positively coordinated according to the intracellular Mg2+ concentration, a unique mechanism among known riboswitches.

Project description:SreA is one of seven candidate S-adenosyl methionine (SAM) class I riboswitches identified in Listeria monocytogenes, a saprophyte and opportunistic foodborne pathogen. SAM is essential to all domains of life, serving as a ubiquitous methyl donor and mediator of trans-sulfuration. SreA precedes genes encoding a methionine ATP- binding cassette (ABC) transporter, which imports methionine, a sulfur containing amino acid and substrate for sulfur metabolism. SreA is presumed to regulate transcription of its downstream genes in a SAM-dependent manner. The proposed role of SreA in controlling the transcription of genes encoding an ABC transporter complex may have important implications for how the bacteria senses and responds to the availability of the metabolite SAM in the diverse environments in which L. monocytogenes persists. Here we validate SreA as a functional SAM-I riboswitch through ligand binding studies, structure characterization, and transcription termination assays. We determined that SreA has both a similar structure and SAM binding properties to other well characterized SAM-I riboswitches. However, SreA regulates transcription at a distinctly lower (nM) ligand concentration but does not substantially terminate transcription, even in the presence of mM SAM.

Project description:A set of small RNAs was identified in Vancomycin-resistant Enterococcus faecium, a leading cause of MDR infections. We described here the function of srn_2050, acting as a T-box riboswitch to regulate expression of downstream genes encoding the HisRS and AspRS aminoacyl-tRNA synthetases. Comparative RNAseq between Aus0004 and isogenic srn_2050 mutant identified the genes whose expression is impacted by the RNA. srn_2050 structure in its ‘off state’ was deciphered by in-line probing, containing T-box consensus sequences, a pseudoknot, a specifier loop and a terminator. Transcription binding assays between the riboswitch and either tRNAAsp or tRNAHis indicate that each deacylated tRNA interacts with the T-box. Their anticodons bind to a GACAC sequence within the specifier loop (GAC and CAC are Asp and His codons, respectively), whereas tRNATyr (UA/C-U) does not. A pioneering evaluation of E. faecium amino acid auxotrophy, with emphasis on E. faecium strain Aus0004, revealed auxotrophy for Histidine but not for Aspartic acid. Based on comparative growths and RNAseq between Aus004 and Aus004-srn2050, the riboswitch is shown essential for growth under aspartate starvation. This is the first example of a functional riboswitch in E. faecium with two overlapping codons allowing a dual tRNA-dependent regulation at transcriptional level.

Project description:Redundancy in the number of tRNA genes which occur across species is poorly understood and, in many cases, remains essentially unexplored. In Staphylococcus aureus, several tRNAGly genes encode isoacceptors that either participate in protein synthesis or cell wall formation, upon aminoacylation by the sole glycyl-tRNA synthetase (GlyRS). Transcription of GlyRS, is regulated by a glyS T-box riboswitch in the 5’UTR, which responds to all tRNAGly isoacceptors and exhibits species-specific RNA conformations. To address whether disruption of the tRNAGly expression impacts the balance between ribosomal translation and cell wall formation, we used CRISPR/Cas9 editing to ablate one proteinogenic tRNAGly gene copy which is the stronger ligand of the glyS T-box riboswitch. Interestingly, no discernible impact on the growth and translational activity of S. aureus was observed, suggesting that the remaining tRNAs could make up for this deficiency. However, transcriptomics and proteomics analyses revealed that the edited strain had deficient cell wall integrity, and subsequent experimentation showed increased susceptibility to antibiotics targeting the cell wall. Interestingly, the observed alteration in the proteome level were independent of the glycine codon usage. Moreover, the edited strain exhibited reduced biofilm formation but retained its ability to invade human cell cultures. Overall, the present study highlights the important role of tRNA gene copy redundancy in the physiology of an important pathogen like S. aureus and consolidates the regulatory role of tRNAs in metabolic homeostasis.

Project description:Synthetic riboswitches mediating ligand-dependent RNA cleavage or splicing-modulation represent elegant tools to control gene expression in various applications, including next-generation gene therapy. However, due to the limited understanding of context-dependent structure-function relationships, the identification of functional riboswitches requires large-scale-screening of aptamer-effector-domain designs, which is hampered by the lack of suitable cellular high-throughput methods. Here we describe a fast and broadly applicable method to functionally screen complex riboswitch libraries (~1.8x104 constructs) by cDNA-amplicon-sequencing in transiently transfected and stimulated human cells. The self-barcoding nature of each construct enables quantification of differential mRNA levels without additional pre-selection or cDNA-manipulation steps. We apply this method to engineer tetracycline- and guanine-responsive ON- and OFF-switches based on hammerhead, hepatitis-delta-virus and Twister ribozymes as well as U1-snRNP polyadenylation-dependent RNA devices. In summary, our method enables fast and efficient high-throughput riboswitch identification, thereby overcoming a major hurdle in the development cascade for therapeutically applicable gene switches. DOI:10.1038/s41467-020-14491-x

Project description:Redundancy in the number of tRNA genes which occur across species is poorly understood and, in many cases, remains essentially unexplored. In Staphylococcus aureus, several tRNAGly genes encode isoacceptors that either participate in protein synthesis or cell wall formation, upon aminoacylation by the sole glycyl-tRNA synthetase (GlyRS). Transcription of GlyRS, is regulated by a glyS T-box riboswitch in the 5’UTR, which responds to all tRNAGly isoacceptors and exhibits species-specific RNA conformations. To address whether disruption of the tRNAGly expression impacts the balance between ribosomal translation and cell wall formation, we used CRISPR/Cas9 editing to ablate one proteinogenic tRNAGly gene copy which is the strongest ligand of the glyS T-box riboswitch. Interestingly, no discernible impact on the growth and general translational activity of S. aureus was observed, suggesting that the remaining tRNAs could make up for this deficiency. However, transcriptomics and proteomics analyses revealed that the edited strain had deficient cell wall integrity, and subsequent experimentation showed increased susceptibility to antibiotics targeting the cell wall and resistance to lysostaphin. Interestingly, the observed alteration in the proteome level were independent of the glycine codon usage. Moreover, the edited strain exhibited reduced biofilm formation but retained its ability to invade human cell cultures. Overall, the present study highlights the important role of tRNA gene copy redundancy in the physiology of an important pathogen like S. aureus and consolidates the regulatory role of tRNAs in metabolic homeostasis.

Project description:RNA is a multifaceted biomolecule with numerous biological functions and can interact with small molecule metabolites as exemplified by riboswitches. Here, we profile the Escherichia Coli transcriptome on interactions with the metabolite Thiamine Monophosphate (TMP). We designed and synthesized a photoaffinity probe based on the scaffold of TMP and applied it to chemotranscriptomic profiling. Using next-generation RNA sequencing, several potential interactions between bacterial transcripts and the probe were identified. A remarkable interaction between the TMP probe and the well-characterized ribB riboswitch was validated by RT-qPCR, and further verified with competition assays. Localization of the photocrosslinked nucleotides using reverse transcription and docking predictions of the probe suggested binding to the riboswitch aptamer. After examining binding of unmodified TMP to the riboswitch using SHAPE, we found selective yet moderate binding interactions, potentially mediated by the phosphate group of TMP. Lastly, TMP appeared to enhance gene expression of a reporter gene that is under riboswitch control, while the natural ligand Flavin Mononucleotide (FMN) displayed an inhibitory effect, hinting at a potential biological role of TMP. This work showcases the possibility of chemotranscriptomic profiling to identify new RNA-small molecule interactions.

Project description:Riboswitches are ligand-binding elements contained within the 5M-bM-^@M-^Y untranslated regions of bacterial transcripts, which generally regulate expression of downstream open reading frames. Here we show that in Listeria monocytogenes, a Vitamin B12-binding (B12) riboswitch controls expression of a non-coding regulatory RNA, Rli55. Rli55 in turn controls expression of the eut genes, which enable ethanolamine utilization and require B12 as a cofactor. Defects in ethanolamine utilization, or in its regulation by Rli55, significantly attenuate Listeria virulence in mice. Rli55 functions by sequestering the two-component response regulator, EutV via a EutV binding-site contained within the RNA. Thus Rli55 is a riboswitch-regulated member of the small group of regulatory RNAs that function by sequestering a protein and reveals a unique mechanism of signal integration in bacterial gene regulation. RNA-Seq and CLIP-Seq to investigate the sequestration of EutV by rli55

Project description:Riboswitches are ligand-binding elements contained within the 5’ untranslated regions of bacterial transcripts, which generally regulate expression of downstream open reading frames. Here we show that in Listeria monocytogenes, a Vitamin B12-binding (B12) riboswitch controls expression of a non-coding regulatory RNA, Rli55. Rli55 in turn controls expression of the eut genes, which enable ethanolamine utilization and require B12 as a cofactor. Defects in ethanolamine utilization, or in its regulation by Rli55, significantly attenuate Listeria virulence in mice. Rli55 functions by sequestering the two-component response regulator, EutV via a EutV binding-site contained within the RNA. Thus Rli55 is a riboswitch-regulated member of the small group of regulatory RNAs that function by sequestering a protein and reveals a unique mechanism of signal integration in bacterial gene regulation.

Project description:Drug-resistant bacteria pose an urgent global health threat, necessitating the development of antibacterial compounds with a novel mode of action. Protein biosynthesis accounts for up to half of the energy expenditure of bacterial cells and consequently inhibiting the efficiency or fidelity of the bacterial ribosome is a major target of existing antibiotics. Here we describe an alternative mode of action to affect the same process; allowing translation to proceed but causing co-translational aggregation of the nascent chain. We found a peptide that acts via this mechanism and is bactericidal against a wide range of pathogenic bacteria, including strains for which novel treatments are most urgently needed such as the ESKAPE pathogens, both in planktonic growth and in biofilms. Proteomics, transcriptomics and biochemical analyses of the inclusion bodies that form in bacteria upon peptide treatment reveal ribosomal proteins, mRNAs and their cognate nascent chains in amyloid-like structures assembled in polar inclusion bodies. The bacterial ssrA ribosome rescue pathway is activated but fails to prevent incorporation of hundreds of proteins into the inclusion bodies. Mechanistically, our results show that disrupting ribosomal quality control via co-translational aggregation constitutes a potent target mechanism for the development of broad-spectrum antibacterials.