Time course of large ribosomal subunit assembly in E. coli cells overexpressing a helicase inactive DbpA protein

Post-transcriptional Modifications of the Large Ribosome Subunit Assembly Intermediates in E. coli Expressing Helicase-Inactive DbpA Variant

RNA post-transcriptional modifications are ubiquitous across all organisms and serve as fundamental regulators of cellular homeostasis, growth, and stress adaptation. Techniques for the simultaneous detection of multiple RNA modifications in a high-throughput, single-nucleotide-resolution manner are largely absent in the field, and developing such techniques is of paramount importance. We used the Escherichia coli ribosome as a model system to develop novel techniques for RNA post-transcriptional modification detection, leveraging its extensive and diverse array of modifications. For modification detection, we performed reverse transcriptase reactions in the presence of Mn2⁺ and quantified the reverse transcriptase deletions and misincorporations at modification positions using Illumina next-generation sequencing. We simultaneously detected the following modifications in ribosomal RNA (rRNA): 1-methylguanosine (m1G), 2-methylguanosine (m2G), 3-methylpseudouridine, N6,N6-dimethyladenosine, and 3-methyluridine, without chemical treatment. Furthermore, subjecting the rRNA samples to 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluenesulfonate followed by alkaline conditions allowed us to simultaneously detect pseudouridine, 7-methylguanosine (m7G), 5-hydroxycytidine (OH5C), 2-methyladenosine, and dihydrouridine (D). Finally, subjecting the rRNA samples to KMnO4 followed by alkaline conditions allowed us to simultaneously detect m7G, OH5C, and D. Our results reveal that m1G, m2G, m7G, and D are incorporated prior to the accumulation of the 27S, 35S, and 45S large subunit intermediates in cells expressing the helicase-inactive R331A DbpA construct. These intermediates belong to three distinct stages and pathways of large subunit ribosome assembly. Therefore, our results identify the time points in three pathways at which m1G, m2G, m7G, and D are incorporated into the large ribosome subunit and provide a framework for broader studies on RNA modification dynamics.

Substrate Specificities of DDX1: A Human DEAD-Box Protein

DDX1 is a human DEAD-box RNA helicase involved in various stages of RNA metabolism, from transcription to decay, and is consequently implicated in many human diseases. The nucleotides hydrolyzed by DDX1 and the structures of the nucleic acids upon which it acts in cells remain largely unknown. In this study, we identify the nucleic acid sequences and structures that support DDX1's nucleotide hydrolysis activity and determine its nucleotide hydrolysis specificity. Our data demonstrate that DDX1 hydrolyzes only ATP and deoxy-ATP in the presence of RNA. The ATP hydrolysis activity of DDX1 is stimulated by single-stranded RNA molecules as short as ten nucleotides, a blunt-ended double-stranded RNA, double-stranded RNA/DNA hybrid, and single-stranded DNA. Under our experimental conditions, single-stranded DNA stimulates DDX1's ATPase activity to a smaller extent compared to the other RNA constructs or the RNA/DNA hybrid. Given DDX1's involvement in numerous critical cellular processes and its implication in various human diseases, determining its substrate specificity not only enhances our understanding of its in vivo function, but also facilitates the development of novel therapeutic approaches.

Role of DEAD-box RNA helicases in low-temperature adapted growth of Antarctic Pseudomonas syringae Lz4W

IMPORTANCE

RNA metabolism is important as RNA acts as a link between genomic information and functional biomolecules, thereby playing a critical role in cellular response to environment. We investigated the role of DEAD-box RNA helicases in low-temperature adapted growth of P. syringae, as this group of enzymes play an essential role in modulation of RNA secondary structures. This is the first report on the assessment of all major DEAD-box RNA helicases in any Antarctic bacterium. Of the five RNA helicases, three (srmB, csdA, and dbpA) are important for the growth of the Antarctic P. syringae at low temperature. However, the requisite role of dbpA and the indispensable requirement of csdA for low-temperature adapted growth are a novel finding of this study. Growth analysis of combinatorial deletion strains was performed to understand the functional interaction among helicase genes. Similarly, genetic complementation of RNA helicase mutants was conducted for identification of gene redundancy in P. syringae.

Substrate Specificities of DDX1: A Human DEAD-box protein

DDX1 is a human protein which belongs to the DEAD-box protein family of enzymes and is involved in various stages of RNA metabolism from transcription to decay. Many members of the DEAD-box family of enzymes use the energy of ATP binding and hydrolysis to perform their cellular functions. On the other hand, a few members of the DEAD-box family of enzymes bind and/or hydrolyze other nucleotides in addition to ATP. Furthermore, the ATPase activity of DEAD-box family members is stimulated differently by nucleic acids of various structures. The identity of the nucleotides that the DDX1 hydrolyzes and the structure of the nucleic acids upon which it acts in the cell remain largely unknown. Identifying the DDX1 protein's in vitro substrates is important for deciphering the molecular roles of DDX1 in cells. Here we identify the nucleic acid sequences and structures supporting the nucleotide hydrolysis activity of DDX1 and its nucleotide specificity. Our data demonstrate that the DDX1 protein hydrolyzes only ATP and deoxy-ATP in the presence of RNA. The ATP hydrolysis activity of DDX1 is stimulated by multiple molecules: single-stranded RNA molecules as short as ten nucleotides, a blunt-ended double-stranded RNA molecule, a hybrid of a double-stranded DNA-RNA molecule, and a single-stranded DNA molecule. Under our experimental conditions, the single-stranded DNA molecule stimulates the ATPase activity of DDX1 at a significantly reduced extent when compared to the other investigated RNA constructs or the hybrid double-stranded DNA/RNA molecule.

RNA Post-transcriptional Modifications of an Early-Stage Large-Subunit Ribosomal Intermediate

Protein production by ribosomes is fundamental to life, and proper assembly of the ribosome is required for protein production. The RNA, which is post-transcriptionally modified, provides the platform for ribosome assembly. Thus, a complete understanding of ribosome assembly requires the determination of the RNA post-transcriptional modifications in all of the ribosome assembly intermediates and on each pathway. There are 26 RNA post-transcriptional modifications in 23S RNA of the mature Escherichia coli (E. coli) large ribosomal subunit. The levels of these modifications have been investigated extensively only for a small number of large subunit intermediates and under a limited number of cellular and environmental conditions. In this study, we determined the level of incorporations of 2-methyl adenosine, 3-methyl pseudouridine, 5-hydroxycytosine, and seven pseudouridines in an early-stage E. coli large-subunit assembly intermediate with a sedimentation coefficient of 27S. The 27S intermediate is one of three large subunit intermediates accumulated in E. coli cells lacking the DEAD-box RNA helicase DbpA and expressing the helicase inactive R331A DbpA construct. The majority of the investigated modifications are incorporated into the 27S large subunit intermediate to similar levels to those in the mature 50S large subunit, indicating that these early modifications or the enzymes that incorporate them play important roles in the initial events of large subunit ribosome assembly.

RNA Post-Transcriptional Modifications in Two Large Subunit Intermediates Populated in E. coli Cells Expressing Helicase Inactive R331A DbpA

23S ribosomal RNA (rRNA) of Escherichia coli 50S large ribosome subunit contains 26 post-transcriptionally modified nucleosides. Here, we determine the extent of modifications in the 35S and 45S large subunit intermediates, accumulating in cells expressing the helicase inactive DbpA protein, R331A, and the native 50S large subunit. The modifications we characterized are 3-methylpseudouridine, 2-methyladenine, 5-hydroxycytidine, and nine pseudouridines. These modifications were detected using 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate (CMCT) treatment followed by alkaline treatment. In addition, KMnO₄ treatment of 23S rRNA was employed to detect 5-hydroxycytidine modification. CMCT and KMnO₄ treatments produce chemical changes in modified nucleotides that cause reverse transcriptase misincorporations and deletions, which were detected employing next-generation sequencing. Our results show that the 2-methyladenine modification and seven uridines to pseudouridine isomerizations are present in both the 35S and 45S to similar extents as in the 50S. Hence, the enzymes that perform these modifications, namely, RluA, RluB, RluC, RluE, RluF, and RlmN, have already acted in the intermediates. Two uridines to pseudouridine isomerizations, the 3-methylpseudouridine and 5-hydroxycytidine modifications, are significantly less present in the 35S and 45S, as compared to the 50S. Therefore, the enzymes that incorporate these modifications, RluD, RlmH, and RlhA, are in the process of modifying the 35S and 45S or will incorporate these modifications during the later stages of ribosome assembly. Our study employs a novel high throughput and single nucleotide resolution technique for the detection of 2-methyladenine and two novel high throughput and single nucleotide resolution techniques for the detection of 5-hydroxycytidine.

Structural basis for the activation of the DEAD-box RNA helicase DbpA by the nascent ribosome

DEAD-box RNA helicases are essential cellular enzymes that remodel misfolded RNA structures in an adenosine triphosphate (ATP)-dependent process. The DEAD-box helicase DbpA is involved in the complex and highly regulated process of ribosome maturation. To prevent wasteful hydrolysis of ATP by DbpA, the enzyme is only active when bound to maturing ribosomes. Here, we elucidate the structural basis behind this important regulatory mechanism and find that the recruited ribosome substrate is able to stabilize the catalytically important closed state of the helicase. In addition, our data identify the natural site of action for DbpA in the maturing ribosome and provide a molecular explanation for the observed ribosome maturation defects that result from the overexpression of a DbpA mutant form.

The adenosine triphosphate (ATP)-dependent DEAD-box RNA helicase DbpA from Escherichia coli functions in ribosome biogenesis. DbpA is targeted to the nascent 50S subunit by an ancillary, carboxyl-terminal RNA recognition motif (RRM) that specifically binds to hairpin 92 (HP92) of the 23S ribosomal RNA (rRNA). The interaction between HP92 and the RRM is required for the helicase activity of the RecA-like core domains of DbpA. Here, we elucidate the structural basis by which DbpA activity is endorsed when the enzyme interacts with the maturing ribosome. We used nuclear magnetic resonance (NMR) spectroscopy to show that the RRM and the carboxyl-terminal RecA-like domain tightly interact. This orients HP92 such that this RNA hairpin can form electrostatic interactions with a positively charged patch in the N-terminal RecA-like domain. Consequently, the enzyme can stably adopt the catalytically important, closed conformation. The substrate binding mode in this complex reveals that a region 5′ to helix 90 in the maturing ribosome is specifically targeted by DbpA. Finally, our results indicate that the ribosome maturation defects induced by a dominant negative DbpA mutation are caused by a delayed dissociation of DbpA from the nascent ribosome. Taken together, our findings provide unique insights into the important regulatory mechanism that modulates the activity of DbpA.

Interactions of the C-Terminal Truncated DEAD-Box Protein DDX3X With RNA and Nucleotide Substrates

DDX3X is a human DEAD-box RNA helicase implicated in many important cellular processes. In addition to the RecA-like catalytic core, DDX3X contains N- and C-terminal domains. The ancillary domains of DEAD-box RNA helicases have been shown to modulate their interactions with RNA and nucleotide substrates. Here, with the goal of understanding the role of N- and C-terminal domains of DDX3X on the DDX3X catalytic activity, we examined the interactions of RNA substrates and nucleotides with a DDX3X construct possessing the entire N-terminal domain and the catalytic core but lacking 80 residues from its C-terminal domain. Next, we compared our results with previously investigated DDX3X constructs. Our data show that the C-terminal truncated DDX3X does not bind to a blunt-ended double-helix RNA. This conclusion agrees with the data obtained on the wild-type LAF-1 protein, the DDX3X ortholog in Caenorhabditis elegans, and disagrees with the data obtained on the minimally active DDX3X construct, which misses 131 residues from its N-terminal domain and 80 residues from its C-terminal domain. The minimally active DDX3X construct was able to bind to the blunt-ended RNA construct. Combined, the previous studies and our results indicate that the N-terminal of DDX3X modulates the choice of DDX3X-RNA substrates. Furthermore, a previous study showed that the wild-type DDX3X construct hydrolyzes all four nucleotides and deoxynucleotides, both in the presence and absence of RNA. The C-terminal truncated DDX3X investigated here hydrolyzes only cytidine triphosphate (CTP) in the absence of RNA and CTP, adenosine triphosphate (ATP), and deoxyribose adenosine triphosphate (dATP) in the presence of RNA. Hence, the C-terminal truncated DDX3X has a more stringent nucleotide specificity than wild-type DDX3X.

Interrogation of highly structured RNA with multicomponent deoxyribozyme probes at ambient temperatures

Molecular analysis of RNA through hybridization with sequence-specific probes is challenging due to the intrinsic ability of RNA molecules to form stable secondary and tertiary structures. To overcome the energy barrier toward the probe-RNA complex formation, the probes are made of artificial nucleotides, which are more expensive than their natural counterparts and may still be inefficient. Here, we propose the use of a multicomponent probe based on an RNA-cleaving deoxyribozyme for the analysis of highly structured RNA targets. Efficient interrogation of two native RNA from Saccharomyces cerevisiae-a transfer RNA (tRNA) and 18S ribosomal RNA (rRNA)-was achieved at ambient temperature. We achieved detection limits of tRNA down to ∼0.3 nM, which is two orders of magnitude lower than that previously reported for molecular beacon probes. Importantly, no probe annealing to the target was required, with the hybridization assay performed at 37°C. Excess of nonspecific targets did not compromise the performance of the probe, and high interrogation efficiency was maintained by the probes even in complex matrices, such as cell lysate. A linear dynamic range of 0.3-150 nM tRNA was demonstrated. The probe can be adapted for differentiation of a single mismatch in the tRNA-probe complex. Therefore, this study opens a venue toward highly selective, sensitive, robust, and inexpensive assays for the interrogation of biological RNA.

Study of key RNA metabolism proteins in Enterococcus faecalis

The control of mRNA turnover is essential in bacteria to allow rapid adaptation, especially in opportunistic pathogen like Enterococcus faecalis. This mechanism involves RNase and DEAD-box helicases that are key elements in RNA processing and their associations form the degradosome with accessory proteins. In this study, we investigated the function of four RNases (J1, J2, Y and III) and three DEAD-box helicases (CshA, CshB, CshC) present in most Enterococci. The interactions of all these RNA metabolism actors were investigated in vitro, and the results are in accordance with a degradosome structure close to the one of Bacillus subtilis. At the physiological level, we showed that RNase J1 is essential, whereas RNases J2 and III have a role in cold, oxidative and bile salts stress response, and RNase Y in general fitness. Furthermore, RNases J2, Y and III mutants are affected in virulence in the Galleria mellonella infection model. Concerning DEAD-box helicases, all of them are involved in cold shock response. Since the ΔcshA mutant was the most stress impacted strain, we studied this DEAD-box helicase CshA in more detail. This showed that CshA autoregulates its own expression by binding to its mRNA 5'Unstranslated Region. Interestingly, CshC is also involved in the expression control of CshA by a hitherto unprecedented mechanism.

Pseudomonas aeruginosa Can Inhibit Growth of Streptococcal Species via Siderophore Production

Cystic fibrosis (CF) is a genetic disease that causes patients to accumulate thick, dehydrated mucus in the lung and develop chronic, polymicrobial infections due to reduced mucociliary clearance. These chronic polymicrobial infections and subsequent decline in lung function are significant factors in the morbidity and mortality of CF. Pseudomonas aeruginosa and Streptococcus spp. are among the most prevalent organisms in the CF lung; the presence of P. aeruginosa correlates with lung function decline, and the Streptococcus milleri group (SMG), a subgroup of the viridans streptococci, is associated with exacerbations in patients with CF. Here we characterized the interspecies interactions that occur between these two genera. We demonstrated that multiple P. aeruginosa laboratory strains and clinical CF isolates promote the growth of multiple SMG strains and oral streptococci in an in vitro coculture system. We investigated the mechanism by which P. aeruginosa enhances growth of streptococci by screening for mutants of P. aeruginosa PA14 that are unable to enhance Streptococcus growth, and we identified the P. aeruginosapqsL::TnM mutant, which failed to promote growth of Streptococcus constellatus and S. sanguinis Characterization of the P. aeruginosa ΔpqsL mutant revealed that this strain cannot promote Streptococcus growth. Our genetic data and growth studies support a model whereby the P. aeruginosa ΔpqsL mutant overproduces siderophores and thus likely outcompetes Streptococcus sanguinis for limited iron. We propose a model whereby competition for iron represents one important means of interaction between P. aeruginosa and Streptococcus spp.IMPORTANCE Cystic fibrosis (CF) lung infections are increasingly recognized for their polymicrobial nature. These polymicrobial infections may alter the biology of the organisms involved in CF-related infections, leading to changes in growth, virulence, and/or antibiotic tolerance, and could thereby affect patient health and response to treatment. In this study, we demonstrate interactions between P. aeruginosa and streptococci using a coculture model and show that one interaction between these microbes is likely competition for iron. Thus, these data indicate that one CF pathogen may influence the growth of another, and they add to our limited knowledge of polymicrobial interactions in the CF airway.

Kinetics and Thermodynamics of DbpA Protein's C-Terminal Domain Interaction with RNA

DbpA is an Escherichia coli DEAD-box RNA helicase implicated in RNA structural isomerization in the peptide bond formation site. In addition to the RecA-like catalytic core conserved in all of the members of DEAD-box family, DbpA contains a structured C-terminal domain, which is responsible for anchoring DbpA to hairpin 92 of 23S ribosomal RNA during the ribosome assembly process. Here, surface plasmon resonance was used to determine the equilibrium dissociation constant and the microscopic rate constants of the DbpA C-terminal domain association and dissociation to a fragment of 23S ribosomal RNA containing hairpin 92. Our results show that the DbpA protein's residence time on the RNA is 10 times longer than the time DbpA requires to hydrolyze one ATP. Thus, our data suggest that once bound to the intermediate ribosomal particles via its RNA-binding domain, DbpA could unwind a number of double-helix substrates before its dissociation from the ribosomal particles.