Extensive 5'-surveillance guards against non-canonical NAD-caps of nuclear mRNAs in yeast.

The ubiquitous redox coenzyme nicotinamide adenine dinucleotide (NAD) acts as a non-canonical cap structure on prokaryotic and eukaryotic ribonucleic acids. Here we find that in budding yeast, NAD-RNAs are abundant (>1400 species), short (<170 nt), and mostly correspond to mRNA 5'-ends. The modification percentage of transcripts is low (<5%). NAD incorporation occurs mainly during transcription initiation by RNA polymerase II, which uses distinct promoters with a YAAG core motif for this purpose. Most NAD-RNAs are 3'-truncated. At least three decapping enzymes, Rai1, Dxo1, and Npy1, guard against NAD-RNA at different cellular locations, targeting overlapping transcript populations. NAD-mRNAs are not translatable in vitro. Our work indicates that in budding yeast, most of the NAD incorporation into RNA seems to be disadvantageous to the cell, which has evolved a diverse surveillance machinery to prematurely terminate, decap and reject NAD-RNAs.

The 5' NAD Cap of RNAIII Modulates Toxin Production in Staphylococcus aureus Isolates.

Nicotinamide adenosine dinucleotide (NAD) has been found to be covalently attached to the 5' ends of specific RNAs in many different organisms, but the physiological consequences of this modification are largely unknown. Here, we report the occurrence of several NAD-RNAs in the opportunistic pathogen Staphylococcus aureus Most prominently, RNAIII, a central quorum-sensing regulator of this bacterium's physiology, was found to be 5' NAD capped in a range from 10 to 35%. NAD incorporation efficiency into RNAIII was found to depend in vivo on the -1 position of the P3 promoter. An increase in RNAIII's NAD content led to a decreased expression of alpha- and delta-toxins, resulting in reduced cytotoxicity of the modified strains. These effects seem to be caused neither by changes in RNAIII's secondary structure nor by a different translatability upon NAD attachment, as indicated by unaltered patterns in in vitro chemical probing and toeprinting experiments. Even though we did not observe any effect of this modification on RNAIII's secondary structure or translatability in vitro, additional unidentified factors might account for the modulation of exotoxins in vivo Ultimately, the study constitutes a step forward in the discovery of new roles of the NAD molecule in bacteria.IMPORTANCE Numerous organisms, including bacteria, are endowed with a 5' NAD cap in specific RNAs. While the presence of the 5' NAD cap modulates the stability of the modified RNA species, a significant biological function and phenotype have not been assigned so far. Here, we show the presence of a 5' NAD cap in RNAIII from S. aureus, a dual-function regulatory RNA involved in quorum-sensing processes and regulation of virulence factor expression. We also demonstrate that altering the natural NAD modification ratio of RNAIII leads to a decrease in exotoxin production, thereby modulating the bacterium's virulence. Our work unveils a new layer of regulation of RNAIII and the agr system that might be linked to the redox state of the NAD molecule in the cell.

Identification, Biosynthesis, and Decapping of NAD-Capped RNAs in B. subtilis.

The ubiquitous coenzyme nicotinamide adenine dinucleotide (NAD) decorates various RNAs in different organisms. In the proteobacterium Escherichia coli, the NAD-cap confers stability against RNA degradation. To date, NAD-RNAs have not been identified in any other bacterial microorganism. Here, we report the identification of NAD-RNA in the firmicute Bacillus subtilis. In the late exponential growth phase, predominantly mRNAs are NAD modified. NAD is incorporated de novo into RNA by the cellular RNA polymerase using non-canonical transcription initiation. The incorporation efficiency depends on the -1 position of the promoter but is independent of sigma factors or mutations in the rifampicin binding pocket. RNA pyrophosphohydrolase BsRppH is found to decap NAD-RNA. In vitro, the decapping activity is facilitated by manganese ions and single-stranded RNA 5' ends. Depletion of BsRppH influences the gene expression of ∼13% of transcripts in B. subtilis. The NAD-cap stabilizes RNA against 5'-to-3'-exonucleolytic decay by RNase J1.

Capture and sequencing of NAD-capped RNA sequences with NAD captureSeq.

Here we describe a protocol for NAD captureSeq that allows for the identification of nicotinamide-adenine dinucleotide (NAD)-capped RNA sequences in total RNA samples from different organisms. NAD-capped RNA is first chemo-enzymatically biotinylated with high efficiency, permitting selective capture on streptavidin beads. Then, a highly efficient library preparation protocol tailored to immobilized, 5'-modified RNA is applied, with adaptor ligation to the RNA's 3' terminus and reverse transcription (RT) performed on-bead. Then, cDNA is released into solution, tailed, ligated to a second adaptor and PCR-amplified. After next-generation sequencing (NGS) of the DNA library, enriched sequences are identified by comparison with a control sample in which the first step of chemo-enzymatic biotinylation is omitted. Because the downstream protocol does not necessarily rely on NAD-modified but on 'clickable' or biotin-modified RNA, it can be applied to other RNA modifications or RNA-biomolecule interactions. The central part of this protocol can be completed in ∼7 d, excluding preparatory steps, sequencing and bioinformatic analysis.

Boronate affinity electrophoresis for the purification and analysis of cofactor-modified RNAs.

RNA modifications are widely distributed in Nature, and their thorough analysis helps answering fundamental biological questions. Nowadays, mass spectrometry or deep-sequencing methods are often used for the analysis. With the raising number of newly discovered RNA modifications, such as the 5'-NAD cap in Escherichia coli, there is an important need for new, less complex and fast analytical tools to analyze the occurrence, amount, and distribution of modified RNAs in cells. To accomplish this task, we have revisited the previously developed affinity gel electrophoresis principles and copolymerized acryloylaminophenyl boronic acid (APB) in standard denaturing polyacrylamide gels to retard the NAD- or FAD-modified RNAs compared to the unmodified RNAs in the gels. The boronyl groups inside the gel form relatively stable complexes with 1,2-cis diols, occurring naturally at the 3'-end of RNA, and also in the nicotinamide riboside of NAD-modified RNA at the 5'-end. The transient formation of diesters between the immobilized boronic acid and the diols causes lower mobility of the modified RNAs, compared to unmodified RNAs, resulting in two distinct bands for one RNA sequence. We used APB affinity gel electrophoresis to preparatively purify in vitro transcribed NAD-RNA from triphosphorylated RNA, to study the enzyme kinetics of the NAD-RNA decapping enzyme NudC, and to determine the NAD modification ratios of various cellular sRNAs. In summary, APB affinity gels can be used to study cofactor-modified RNAs with low amounts of material, and to rapidly screen for their occurrence in total RNA while avoiding complex sample treatments.

Cap-like structures in bacterial RNA and epitranscriptomic modification.

The absence of capped RNA is considered as a hallmark of prokaryotic gene expression. Recent developments combine next-generation sequencing with a chemo-enzymatic capture step that allows the enrichment of rare 5'-modified RNA from bacteria. This approach identified covalent cap-like linkage of a specific set of small RNAs to the ubiquitous redox cofactor NAD, and a profound influence of this modification on RNA turnover. The modification revealed an unexpected connection between redox biology and RNA processing. We discuss possible roles of the NAD modification as well as broader implications for structurally related cofactors and metabolites which may also be linked to RNAs, leading to a new epitranscriptomic layer of information encoded in the chemical structure of the attached cofactors.

NAD captureSeq indicates NAD as a bacterial cap for a subset of regulatory RNAs.

A distinctive feature of prokaryotic gene expression is the absence of 5'-capped RNA. In eukaryotes, 5',5'-triphosphate-linked 7-methylguanosine protects messenger RNA from degradation and modulates maturation, localization and translation. Recently, the cofactor nicotinamide adenine dinucleotide (NAD) was reported as a covalent modification of bacterial RNA. Given the central role of NAD in redox biochemistry, posttranslational protein modification and signalling, its attachment to RNA indicates that there are unknown functions of RNA in these processes and undiscovered pathways in RNA metabolism and regulation. The unknown identity of NAD-modified RNAs has so far precluded functional analyses. Here we identify NAD-linked RNAs from bacteria by chemo-enzymatic capture and next-generation sequencing (NAD captureSeq). Among those identified, specific regulatory small RNAs (sRNAs) and sRNA-like 5'-terminal fragments of certain mRNAs are particularly abundant. Analogous to a eukaryotic cap, 5'-NAD modification is shown in vitro to stabilize RNA against 5'-processing by the RNA-pyrophosphohydrolase RppH and against endonucleolytic cleavage by ribonuclease (RNase) E. The nudix phosphohydrolase NudC decaps NAD-RNA and thereby triggers RNase-E-mediated RNA decay, while being inactive against triphosphate-RNA. In vivo, ∼13% of the abundant sRNA RNAI is NAD-capped in the presence, and ∼26% in the absence, of functional NudC. To our knowledge, this is the first description of a cap-like structure and a decapping machinery in bacteria.