Transcription termination control in bacteria

Alternative RNA Conformations: Companion or Combatant

RNA molecules, in one form or another, are involved in almost all aspects of cell physiology, as well as in disease development. The diversity of the functional roles of RNA comes from its intrinsic ability to adopt complex secondary and tertiary structures, rivaling the diversity of proteins. The RNA molecules form dynamic ensembles of many interconverting conformations at a timescale of seconds, which is a key for understanding how they execute their cellular functions. Given the crucial role of RNAs in various cellular processes, we need to understand the RNA molecules from a structural perspective. Central to this review are studies aimed at revealing the regulatory role of conformational equilibria in RNA in humans to understand genetic diseases such as cancer and neurodegenerative diseases, as well as in pathogens such as bacteria and viruses so as to understand the progression of infectious diseases. Furthermore, we also summarize the prior studies on the use of RNA structures as platforms for the rational design of small molecules for therapeutic applications.

Novel High-Throughput DNA Part Characterization Technique for Synthetic Biology

This study presents a novel DNA part characterization technique that increases throughput by combinatorial DNA part assembly, solid plate-based quantitative fluorescence assay for phenotyping, and barcode tagging-based long-read sequencing for genotyping. We confirmed that the fluorescence intensities of colonies on plates were comparable to fluorescence at the single-cell level from a high-end, flow-cytometry device and developed a high-throughput image analysis pipeline. The barcode tagging-based long-read sequencing technique enabled rapid identification of all DNA parts and their combinations with a single sequencing experiment. Using our techniques, forty-four DNA parts (21 promoters and 23 RBSs) were successfully characterized in 72 h without any automated equipment. We anticipate that this high-throughput and easy-to-use part characterization technique will contribute to increasing part diversity and be useful for building genetic circuits and metabolic pathways in synthetic biology.

The Role of RNA Secondary Structure in Regulation of Gene Expression in Bacteria

Due to the high exposition to changing environmental conditions, bacteria have developed many mechanisms enabling immediate adjustments of gene expression. In many cases, the required speed and plasticity of the response are provided by RNA-dependent regulatory mechanisms. This is possible due to the very high dynamics and flexibility of an RNA structure, which provide the necessary sensitivity and specificity for efficient sensing and transduction of environmental signals. In this review, we will discuss the current knowledge about known bacterial regulatory mechanisms which rely on RNA structure. To better understand the structure-driven modulation of gene expression, we describe the basic theory on RNA structure folding and dynamics. Next, we present examples of multiple mechanisms employed by RNA regulators in the control of bacterial transcription and translation.

The Rho-Independent Transcription Terminator for the porA Gene Enhances Expression of the Major Outer Membrane Protein and Campylobacter jejuni Virulence in Abortion Induction

Campylobacter jejuni is a leading cause of foodborne illnesses worldwide. Its porA gene encodes the major outer membrane protein (MOMP) that is abundantly expressed and has important physiological functions, including a key role in systemic infection and abortion induction in pregnant animals. Despite the importance of porA in C. jejuni pathogenesis, mechanisms modulating its expression levels remain elusive. At the 3' end of the porA transcript, there is a Rho-independent transcription terminator (named T _porA in this study). Whether T _porA affects the expression and function of MOMP remains unknown and is investigated in this study. Green fluorescent protein (GFP) fusion constructs with the porA promoter at the 5' end and an intact T _porA or no T _porA at the 3' end of the gfp coding sequence revealed that both the transcript level of gfp and its fluorescence signals were more than 2-fold higher in the construct with T _porA than in the one without T _porA Real-time quantitative PCR (qRT-PCR) analysis of the porA mRNA and immunoblot detection of MOMP in C. jejuni showed that disruption of T _porA significantly reduced the porA transcript level and the expression of MOMP. An mRNA decay assay demonstrated that disruption of T _porA resulted in a shortened transcript half-life of the upstream gfp or porA gene, indicating that T _porA enhances mRNA stability. In the guinea pig model, the C. jejuni construct with an interrupted T _porA was significantly attenuated in abortion induction. Together, these results indicate that T _porA enhances the expression level of MOMP by stabilizing its mRNA and influences the virulence of C. jejuni.

Consensus architecture of promoters and transcription units in Escherichia coli: design principles for synthetic biology

Genetic information in genomes is ordered, arranged in such a way that it constitutes a code, the so-called cis regulatory code. The regulatory machinery of the cell, termed trans-factors, decodes and expresses this information. In this way, genomes maintain a potential repertoire of genetic programs, parts of which are executed depending on the presence of active regulators in each condition. These genetic programs, executed by the regulatory machinery, have functional units in the genome delimited by punctuation-like marks. In genetic terms, these informational phrases correspond to transcription units, which are the minimal genetic information expressed consistently from initiation to termination marks. Between the start and final punctuation marks, additional marks are present that are read by the transcriptional and translational machineries. In this work, we look at all the experimentally described and predicted genetic elements in the bacterium Escherichia coli K-12 MG1655 and define a comprehensive architectural organization of transcription units to reveal the natural genome-design and to guide the construction of synthetic genetic programs.

Capture and Release of tRNA by the T-Loop Receptor in the Function of the T-Box Riboswitch

In Gram-positive bacteria, the tRNA-dependent T-box riboswitch system regulates expression of amino acid biosynthetic and aminoacyl-tRNA synthetase genes through a transcription attenuation mechanism. Binding of uncharged tRNA "closes" the switch, allowing transcription read-through. Structural studies of the 100-nucleotide stem I domain reveal tRNA utilizes base pairing and stacking interactions to bind the stem, but little is known structurally about the 180-nucleotide riboswitch core (stem I, stem III, and antiterminator stem) in complex with tRNA or the mechanism of coupling of the intermolecular binding domains crucial to T-box function. Here we utilize solution structural and biophysical methods to characterize the interplay of the different riboswitch-tRNA contact points using Bacillus subtilis and Oceanobacillus iheyensis glycyl T-box and T-box:tRNA constructs. The data reveal that tRNA:riboswitch core binding at equilibrium involves only Specifier-anticodon and antiterminator-acceptor stem pairing. The elbow:platform stacking interaction observed in studies of the T-box stem I domain is released after pairing between the acceptor stem and the bulge in the antiterminator helix. The results are consistent with the model of T-box riboswitch:tRNA function in which tRNA is captured by stem I of the nascent mRNA followed by stabilization of the antiterminator helix and the paused transcription complex.

Riboswitches: From living biosensors to novel targets of antibiotics

Riboswitches are generally located in 5'-UTR region of mRNAs and specifically bind small ligands. Following ligand binding, gene expression is controlled mostly by transcription termination, translation inhibition or mRNA degradation processes. More than 30 classes of known riboswitches have been identified by now. Most riboswitches consist of an aptamer domain and an expression platform. The aptamer domain of each class of riboswitch is a conserved structure and stabilizes specific structures of the expression platforms through binding to specific compounds. In this review, we are highlighting most aspects of riboswitch research including the novel riboswitch discoveries, routine methods for discovering and investigating riboswitches along with newly discovered classes and mechanistic principles of riboswitch-mediated gene expression control. Moreover, we will give an overview about the potential of riboswitches as therapeutic targets for antibiotic design and also their utilization as biosensors for molecular detection.

Modular construction of a functional artificial epothilone polyketide pathway

Natural products of microbial origin continue to be an important source of pharmaceuticals and agrochemicals exhibiting potent activities and often novel modes of action. Due to their inherent structural complexity chemical synthesis is often hardly possible, leaving fermentation as the only viable production route. In addition, the pharmaceutical properties of natural products often need to be optimized for application by sophisticated medicinal chemistry and/or biosynthetic engineering. The latter requires a detailed understanding of the biosynthetic process and genetic tools to modify the producing organism that are often unavailable. Consequently, heterologous expression of complex natural product pathways has been in the focus of development over recent years. However, piecing together existing DNA cloned from natural sources and achieving efficient expression in heterologous circuits represent several limitations that can be addressed by synthetic biology. In this work we have redesigned and reassembled the 56 kb epothilone biosynthetic gene cluster from Sorangium cellulosum for expression in the high GC host Myxococcus xanthus. The codon composition was adapted to a modified codon table for M. xanthus, and unique restriction sites were simultaneously introduced and others eliminated from the sequence in order to permit pathway assembly and future interchangeability of modular building blocks from the epothilone megasynthetase. The functionality of the artificial pathway was demonstrated by successful heterologous epothilone production in M. xanthus at significant yields that have to be improved in upcoming work. Our study sets the stage for future engineering of epothilone biosynthesis and production optimization using a highly flexible assembly strategy.

Overlapping genes: a window on gene evolvability

Background

The forces underlying genome architecture and organization are still only poorly understood in detail. Overlapping genes (genes partially or entirely overlapping) represent a genomic feature that is shared widely across biological organisms ranging from viruses to multi-cellular organisms. In bacteria, a third of the annotated genes are involved in an overlap. Despite the widespread nature of this arrangement, its evolutionary origins and biological ramifications have so far eluded explanation.

Results

Here we present a comparative approach using information from 699 bacterial genomes that sheds light on the evolutionary dynamics of overlapping genes. We show that these structures exhibit high levels of plasticity.

Conclusions

We propose a simple model allowing us to explain the observed properties of overlapping genes based on the importance of initiation and termination of transcriptional and translational processes. We believe that taking into account the processes leading to the expression of protein-coding genes hold the key to the understanding of overlapping genes structures.

Nutrient salvaging and metabolism by the intracellular pathogen Legionella pneumophila

The Gram-negative bacterium Legionella pneumophila is ubiquitous in freshwater environments as a free-swimming organism, resident of biofilms, or parasite of protozoa. If the bacterium is aerosolized and inhaled by a susceptible human host, it can infect alveolar macrophages and cause a severe pneumonia known as Legionnaires' disease. A sophisticated cell differentiation program equips L. pneumophila to persist in both extracellular and intracellular niches. During its life cycle, L. pneumophila alternates between at least two distinct forms: a transmissive form equipped to infect host cells and evade lysosomal degradation, and a replicative form that multiplies within a phagosomal compartment that it has retooled to its advantage. The efficient changeover between transmissive and replicative states is fundamental to L. pneumophila's fitness as an intracellular pathogen. The transmission and replication programs of L. pneumophila are governed by a number of metabolic cues that signal whether conditions are favorable for replication or instead trigger escape from a spent host. Several lines of experimental evidence gathered over the past decade establish strong links between metabolism, cellular differentiation, and virulence of L. pneumophila. Herein, we focus on current knowledge of the metabolic components employed by intracellular L. pneumophila for cell differentiation, nutrient salvaging and utilization of host factors. Specifically, we highlight the metabolic cues that are coupled to bacterial differentiation, nutrient acquisition systems, and the strategies utilized by L. pneumophila to exploit host metabolites for intracellular replication.

Solution NMR determination of hydrogen bonding and base pairing between the glyQS T box riboswitch Specifier domain and the anticodon loop of tRNA(Gly)

In Gram-positive bacteria the tRNA-dependent T box riboswitch regulates the expression of many amino acid biosynthetic and aminoacyl-tRNA synthetase genes through a transcription attenuation mechanism. The Specifier domain of the T box riboswitch contains the Specifier sequence that is complementary to the tRNA anticodon and is flanked by a highly conserved purine nucleotide that could result in a fourth base pair involving the invariant U33 of tRNA. We show that the interaction between the T box Specifier domain and tRNA consists of three Watson-Crick base pairs and that U33 confers stability to the complex through intramolecular hydrogen bonding. Enhanced packing within the Specifier domain loop E motif may stabilize the complex and contribute to cognate tRNA selection.

The transfer-messenger RNA-small protein B system plays a role in avian pathogenic Escherichia coli pathogenicity

Extraintestinal pathogenic Escherichia coli (ExPEC) is capable of colonizing outside of the intestinal tract and evolving into a systemic infection. Avian pathogenic E. coli (APEC) is a member of the ExPEC group and causes avian colibacillosis. Transfer-mRNA-small protein B (tmRNA-SmpB)-mediated trans-translation is a bacterial translational control system that directs the modification and degradation of proteins, the biosynthesis of which has stalled or has been interrupted, facilitating the rescue of ribosomes stalled at the 3' ends of defective mRNAs that lack a stop codon. We found that disruption of one, or both, of the smpB or ssrA genes significantly decreased the virulence of the APEC strain E058, as assessed by chicken infection assays. Furthermore, the mutants were obviously attenuated in colonization and persistence assays. The results of quantitative real-time reverse transcription-PCR analysis indicated that the transcription levels of the transcriptional regulation gene rfaH and the virulence genes kpsM, chuA, and iss were significantly decreased compared to those of the wild-type strain. Macrophage infection assays showed that the mutant strains reduced the replication and/or survival ability in the macrophage HD11 cell line compared to that of the parent strain, E058. However, no significant differences were observed in ingestion by macrophages and in chicken serum resistance between the mutant and the wild-type strains. These data indicate that the tmRNA-SmpB system is important in the pathogenesis of APEC O2 strain E058.

Leader Sequence

The region of a messenger RNA (mRNA) molecule that precedes the coding sequence of a gene is called the ‘leader sequence’. This region is also known as the ‘five prime untranslated region’ (Figure 1) of the mRNA. Leader sequences have the propensity for forming secondary structures (stem-loops) by base pairing of complementary sequences. They are involved in the regulation of gene expression in eukaryotes and prokaryotes. In eukaryotes, the leader sequence may vary from few nucleotides to more than 1000 nucleotides. In prokaryotes, the leader sequences are usually short and at times contain an attenuator segment that is translated to a short-leader peptide. The leader peptide functions to terminate transcripts before the RNA polymerase reaches the first structural gene of the operon. The leader sequences in viruses have been shown to play an important role in the regulation of gene expression, replication, and pathogenicity. Mutations in the leader sequences of cellular mRNAs can have implications for disease and tumorigenesis.

Role of forward translocation in nucleoside triphosphate phosphohydrolase I (NPH I)-mediated transcription termination of vaccinia virus early genes

Termination of transcription of vaccinia virus early genes requires the virion form of the viral RNA polymerase (RNAP), a termination signal (UUUUUNU) in the nascent RNA, vaccinia termination factor, nucleoside triphosphate phosphohydrolase I (NPH I), and ATP. NPH I uses ATP hydrolysis to mediate transcript release, and in vitro, ATPase activity requires single-stranded DNA. NPH I shows sequence similarity with the DEXH-box family of proteins, which includes an Escherichia coli ATP-dependent motor protein, Mfd. Mfd releases transcripts and rescues arrested transcription complexes by moving the transcription elongation complex downstream on the DNA template in the absence of transcription elongation. This mechanism is known as forward translocation. In this study, we demonstrate that NPH I also uses forward translocation to catalyze transcript release from viral RNAP. Moreover, we show that NPH I-mediated release can occur at a stalled RNAP in the absence of vaccinia termination factor and U(5)NU when transcription elongation is prevented.

Conformation effects of base modification on the anticodon stem-loop of Bacillus subtilis tRNA(Tyr)

tRNA molecules contain 93 chemically unique nucleotide base modifications that expand the chemical and biophysical diversity of RNA and contribute to the overall fitness of the cell. Nucleotide modifications of tRNA confer fidelity and efficiency to translation and are important in tRNA-dependent RNA-mediated regulatory processes. The three-dimensional structure of the anticodon is crucial to tRNA-mRNA specificity, and the diverse modifications of nucleotide bases in the anticodon region modulate this specificity. We have determined the solution structures and thermodynamic properties of Bacillus subtilis tRNA(Tyr) anticodon arms containing the natural base modifications N(6)-dimethylallyl adenine (i(6)A(37)) and pseudouridine (ψ(39)). UV melting and differential scanning calorimetry indicate that the modifications stabilize the stem and may enhance base stacking in the loop. The i(6)A(37) modification disrupts the hydrogen bond network of the unmodified anticodon loop including a C(32)-A(38)(+) base pair and an A(37)-U(33) base-base interaction. Although the i(6)A(37) modification increases the dynamic nature of the loop nucleotides, metal ion coordination reestablishes conformational homogeneity. Interestingly, the i(6)A(37) modification and Mg(2+) are sufficient to promote the U-turn fold of the anticodon loop of Escherichia coli tRNA(Phe), but these elements do not result in this signature feature of the anticodon loop in tRNA(Tyr).

Solution structure of the K-turn and Specifier Loop domains from the Bacillus subtilis tyrS T-box leader RNA

In Gram-positive bacteria, the RNA transcripts of many amino acid biosynthetic and aminoacyl tRNA synthetase genes contain 5' untranslated regions, or leader RNAs, that function as riboswitches. These T-box riboswitches bind cognate tRNA molecules and regulate gene expression by a transcription attenuation mechanism. The Specifier Loop domain of the leader RNA contains nucleotides that pair with nucleotides in the tRNA anticodon loop and is flanked on one side by a kink-turn (K-turn), or GA, sequence motif. We have determined the solution NMR structure of the K-turn sequence element within the context of the Specifier Loop domain. The K-turn sequence motif has several noncanonical base pairs typical of K-turn structures but adopts an extended conformation. The Specifier Loop domain contains a loop E structural motif, and the single-strand Specifier nucleotides stack with their Watson-Crick edges displaced toward the minor groove. Mg(2+) leads to a significant bending of the helix axis at the base of the Specifier Loop domain, but does not alter the K-turn. Isothermal titration calorimetry indicates that the K-turn sequence causes a small enhancement of the interaction between the tRNA anticodon arm and the Specifier Loop domain. One possibility is that the K-turn structure is formed and stabilized when tRNA binds the T-box riboswitch and interacts with Stem I and the antiterminator helix. This motif in turn anchors the orientation of Stem I relative to the 3' half of the leader RNA, further stabilizing the tRNA-T box complex.

WebGeSTer DB--a transcription terminator database

We present WebGeSTer DB, the largest database of intrinsic transcription terminators (http://pallab.serc.iisc.ernet.in/gester). The database comprises of a million terminators identified in 1060 bacterial genome sequences and 798 plasmids. Users can obtain both graphic and tabular results on putative terminators based on default or user-defined parameters. The results are arranged in different tiers to facilitate retrieval, as per the specific requirements. An interactive map has been incorporated to visualize the distribution of terminators across the whole genome. Analysis of the results, both at the whole-genome level and with respect to terminators downstream of specific genes, offers insight into the prevalence of canonical and non-canonical terminators across different phyla. The data in the database reinforce the paradigm that intrinsic termination is a conserved and efficient regulatory mechanism in bacteria. Our database is freely accessible.

Transcriptional and translational regulatory responses to iron limitation in the globally distributed marine bacterium Candidatus pelagibacter ubique

Iron is recognized as an important micronutrient that limits microbial plankton productivity over vast regions of the oceans. We investigated the gene expression responses of Candidatus Pelagibacter ubique cultures to iron limitation in natural seawater media supplemented with a siderophore to chelate iron. Microarray data indicated transcription of the periplasmic iron binding protein sfuC increased by 16-fold, and iron transporter subunits, iron-sulfur center assembly genes, and the putative ferroxidase rubrerythrin transcripts increased to a lesser extent. Quantitative peptide mass spectrometry revealed that sfuC protein abundance increased 27-fold, despite an average decrease of 59% across the global proteome. Thus, we propose sfuC as a marker gene for indicating iron limitation in marine metatranscriptomic and metaproteomic ecological surveys. The marked proteome reduction was not directly correlated to changes in the transcriptome, implicating post-transcriptional regulatory mechanisms as modulators of protein expression. Two RNA-binding proteins, CspE and CspL, correlated well with iron availability, suggesting that they may contribute to the observed differences between the transcriptome and proteome. We propose a model in which the RNA-binding activity of CspE and CspL selectively enables protein synthesis of the iron acquisition protein SfuC during transient growth-limiting episodes of iron scarcity.

Novel insertion and deletion mutants of RpoB that render Mycobacterium smegmatis RNA polymerase resistant to rifampicin-mediated inhibition of transcription

The startling increase in the occurrence of rifampicin (Rif) resistance in the clinical isolates of Mycobacterium tuberculosis worldwide is posing a serious concern to tuberculosis management. The majority of Rif resistance in bacteria arises from mutations in the RpoB subunit of the RNA polymerase. We isolated M. smegmatis strains harbouring either an insertion (6 aa) or a deletion (10 aa) in their RpoB proteins. Although these strains showed a compromised fitness for growth in 7H9 Middlebrook medium, their resistance to Rif was remarkably high. The attenuated growth of the strains correlated with decreased specific activities of the RNA polymerases from the mutants. While the RNA polymerases from the parent or a mutant strain (harbouring a frequently occurring mutation, H442Y, in RpoB) were susceptible to Rif-mediated inhibition of transcription from calf thymus DNA, those from the insertion and deletion mutants were essentially refractory to such inhibition. Three-dimensional structure modelling revealed that the RpoB amino acids that interact with Rif are either deleted or unable to interact with Rif due to their unsuitable spatial positioning in these mutants. We discuss possible uses of the RpoB mutants in studying transcriptional regulation in mycobacteria and as potential targets for drug design.

Positions of Trp codons in the leader peptide-coding region of the at operon influence anti-trap synthesis and trp operon expression in Bacillus licheniformis

Tryptophan, phenylalanine, tyrosine, and several other metabolites are all synthesized from a common precursor, chorismic acid. Since tryptophan is a product of an energetically expensive biosynthetic pathway, bacteria have developed sensing mechanisms to downregulate synthesis of the enzymes of tryptophan formation when synthesis of the amino acid is not needed. In Bacillus subtilis and some other Gram-positive bacteria, trp operon expression is regulated by two proteins, TRAP (the tryptophan-activated RNA binding protein) and AT (the anti-TRAP protein). TRAP is activated by bound tryptophan, and AT synthesis is increased upon accumulation of uncharged tRNA(Trp). Tryptophan-activated TRAP binds to trp operon leader RNA, generating a terminator structure that promotes transcription termination. AT binds to tryptophan-activated TRAP, inhibiting its RNA binding ability. In B. subtilis, AT synthesis is upregulated both transcriptionally and translationally in response to the accumulation of uncharged tRNA(Trp). In this paper, we focus on explaining the differences in organization and regulatory functions of the at operon's leader peptide-coding region, rtpLP, of B. subtilis and Bacillus licheniformis. Our objective was to correlate the greater growth sensitivity of B. licheniformis to tryptophan starvation with the spacing of the three Trp codons in its at operon leader peptide-coding region. Our findings suggest that the Trp codon location in rtpLP of B. licheniformis is designed to allow a mild charged-tRNA(Trp) deficiency to expose the Shine-Dalgarno sequence and start codon for the AT protein, leading to increased AT synthesis.

Mechanisms and evolution of control logic in prokaryotic transcriptional regulation

A major part of organismal complexity and versatility of prokaryotes resides in their ability to fine-tune gene expression to adequately respond to internal and external stimuli. Evolution has been very innovative in creating intricate mechanisms by which different regulatory signals operate and interact at promoters to drive gene expression. The regulation of target gene expression by transcription factors (TFs) is governed by control logic brought about by the interaction of regulators with TF binding sites (TFBSs) in cis-regulatory regions. A factor that in large part determines the strength of the response of a target to a given TF is motif stringency, the extent to which the TFBS fits the optimal TFBS sequence for a given TF. Advances in high-throughput technologies and computational genomics allow reconstruction of transcriptional regulatory networks in silico. To optimize the prediction of transcriptional regulatory networks, i.e., to separate direct regulation from indirect regulation, a thorough understanding of the control logic underlying the regulation of gene expression is required. This review summarizes the state of the art of the elements that determine the functionality of TFBSs by focusing on the molecular biological mechanisms and evolutionary origins of cis-regulatory regions.

Frameworks for programming biological function through RNA parts and devices

One of the long-term goals of synthetic biology is to reliably engineer biological systems that perform human-defined functions. Currently, researchers face several scientific and technical challenges in designing and building biological systems, one of which is associated with our limited ability to access, transmit, and control molecular information through the design of functional biomolecules exhibiting novel properties. The fields of RNA biology and nucleic acid engineering, along with the tremendous interdisciplinary growth of synthetic biology, are fueling advances in the emerging field of RNA programming in living systems. Researchers are designing functional RNA molecules that exhibit increasingly complex functions and integrating these molecules into cellular circuits to program higher-level biological functions. The continued integration and growth of RNA design and synthetic biology presents exciting potential to transform how we interact with and program biology.

Molecular dissection of mammalian RNA polymerase II transcriptional termination

Transcriptional termination of mammalian RNA polymerase II (Pol II) is an essential but little-understood step in protein-coding gene expression. Mechanistically, termination by all DNA-dependent RNA polymerases can be reduced to two steps, namely release of the RNA transcript and release of the DNA template. Using a simple nuclear fractionation procedure, we have monitored transcript and template release in the context of both natural and artificial Pol II terminator sequences. We describe the timing and relationship between these events and in so doing establish the roles of the poly(A) signal, cotranscriptional RNA cleavage events, and 5′-3′ exonucleolytic RNA degradation in the mammalian Pol II termination process.

Identification of an operon and inducing peptide involved in the production of lactacin B by Lactobacillus acidophilus

AIM

To determine if a 9.5-kb region on the Lactobacillus acidophilus NCFM genome, encoded the genetic determinants for regulation and production of lactacin B, a class II bacteriocin.

METHODS

Transcriptional analysis was used to identify a 9.5-kb polycistronic region suspected of encoding the lab operon. The 12 putative open reading frames (LBA1803-LBA1791) were organized into three clusters: a production and regulation cluster encoding a putative two-component signal transduction system; an export cluster encoding a putative ABC transporter and a final cluster composed of three unknown proteins. Seven genes were typical of bacteriocins, encoding small, cationic peptides, each with an N-terminal double-glycine leader motif. Inactivation of a predicted ABC transporter completely abolished bacteriocin activity. When cloned and expressed together, LBA1803-LBA1800 resulted in markedly higher levels of lactacin B activity. The four peptides were chemically synthesized but exhibited no bacteriocin activity, alone or in combination. Only LBA1800 induced lactacin B production in broth cultures.

CONCLUSIONS

Lactacin B production is encoded within the 9.5-kb lab operon of 12 genes that are transcribed in a single transcript. LBA1800 is an inducing peptide of bacteriocin production.

SIGNIFICANCE AND IMPACT OF THE STUDY

A three-component regulatory system common to class II bacteriocins regulates the production of this bacteriocin by Lact. acidophilus.

Physiological effects of anti-TRAP protein activity and tRNA(Trp) charging on trp operon expression in Bacillus subtilis

The Bacillus subtilis anti-TRAP protein regulates the ability of the tryptophan-activated TRAP protein to bind to trp operon leader RNA and promote transcription termination. AT synthesis is regulated both transcriptionally and translationally by uncharged tRNA(Trp). In this study, we examined the roles of AT synthesis and tRNA(Trp) charging in mediating physiological responses to tryptophan starvation. Adding excess phenylalanine to wild-type cultures reduced the charged tRNA(Trp) level from 80% to 40%; the charged level decreased further, to 25%, in an AT-deficient mutant. Adding tryptophan with phenylalanine increased the charged tRNA(Trp) level, implying that phenylalanine, when added alone, reduces the availability of tryptophan for tRNA(Trp) charging. Changes in the charged tRNA(Trp) level observed during growth with added phenylalanine were associated with increased transcription of the genes of tryptophan metabolism. Nutritional shift experiments, from a medium containing tryptophan to a medium with phenylalanine and tyrosine, showed that wild-type cultures gradually reduced their charged tRNA(Trp) level. When this shift was performed with an AT-deficient mutant, the charged tRNA(Trp) level decreased even further. Growth rates for wild-type and mutant strains deficient in AT or TRAP or that overproduce AT were compared in various media. A lack of TRAP or overproduction of AT resulted in phenylalanine being required for growth. These findings reveal the importance of AT in maintaining a balance between the synthesis of tryptophan versus the synthesis of phenylalanine, with the level of charged tRNA(Trp) acting as the crucial signal regulating AT production.

Ribosome biogenesis and the translation process in Escherichia coli

Translation, the decoding of mRNA into protein, is the third and final element of the central dogma. The ribosome, a nucleoprotein particle, is responsible and essential for this process. The bacterial ribosome consists of three rRNA molecules and approximately 55 proteins, components that are put together in an intricate and tightly regulated way. When finally matured, the quality of the particle, as well as the amount of active ribosomes, must be checked. The focus of this review is ribosome biogenesis in Escherichia coli and its cross-talk with the ongoing protein synthesis. We discuss how the ribosomal components are produced and how their synthesis is regulated according to growth rate and the nutritional contents of the medium. We also present the many accessory factors important for the correct assembly process, the list of which has grown substantially during the last few years, even though the precise mechanisms and roles of most of the proteins are not understood.

RNA-based regulation of genes of tryptophan synthesis and degradation, in bacteria

We are now aware that RNA-based regulatory mechanisms are commonly used to control gene expression in many organisms. These mechanisms offer the opportunity to exploit relatively short, unique RNA sequences, in altering transcription, translation, and/or mRNA stability, in response to the presence of a small or large signal molecule. The ability of an RNA segment to fold and form alternative hairpin secondary structures -- each dedicated to a different regulatory function -- permits selection of specific sequences that can affect transcription and/or translation. In the present paper I will focus on our current understanding of the RNA-based regulatory mechanisms used by Escherichia coli and Bacillus subtilis in controlling expression of the tryptophan biosynthetic operon. The regulatory mechanisms they use for this purpose differ, suggesting that these organisms, or their ancestors, adopted different strategies during their evolution. I will also describe the RNA-based mechanism used by E. coli in regulating expression of its operon responsible for tryptophan degradation, the tryptophanase operon.

Comparison of tryptophan biosynthetic operon regulation in different Gram-positive bacterial species

The tryptophan biosynthetic operon has been widely used as a model system for studying transcription regulation. In Bacillus subtilis, the trp operon is primarily regulated by a tryptophan-activated RNA-binding protein, TRAP. Here we show that in many other Gram-positive species the trp operon is regulated differently, by tRNA(Trp) sensing by the RNA-based T-box mechanism, with T-boxes arranged in tandem. Our analyses reveal an apparent relationship between trp operon organization and the specific regulatory mechanism(s) used.

The nucleus-encoded factor MCD4 participates in degradation of nonfunctional 3' UTR sequences generated by cleavage of pre-mRNA in Chlamydomonas chloroplasts

The 3' maturation of chloroplast pre-mRNAs in Chlamydomonas proceeds via endonucleolytic cleavage, exonucleolytic trimming of the upstream cleavage product, and rapid degradation of the downstream moiety. However, the cis elements and trans factors remain to be characterized in detail. In the case of atpB, a 300 nucleotide processing determinant (PD), consisting of an inverted repeat (IR) and endonuclease cleavage site (ECS), directs 3' maturation. To further characterize the PD, 15 variants were examined in vivo in ectopic contexts. This revealed that the IR, and nucleotides 15-37 downstream of the ECS stimulate processing. A candidate trans factor for 3' maturation was subsequently functionally analyzed. This factor is encoded by the nuclear locus MCD4, and the mcd4 mutant was known to accumulate abnormally 3'-processed chloroplast mRNAs. When the mcd4 mutation was crossed into strains containing reporter genes with insertions of several PD versions, processing was reduced in some cases. This caused accumulation of RNA sequences downstream of the PD, which are normally degraded. From these data, it can be suggested that MCD4 facilitates the endonucleolytic cleavage step in 3' end maturation of atpB and perhaps other mRNAs, by interacting with the IR, RNA downstream of the IR, or with proteins bound there.

Identification of genes associated with mutacin I production in Streptococcus mutans using random insertional mutagenesis

Streptococcus mutans is a major pathogen implicated in dental caries. Its virulence is enhanced by its ability to produce bacteriocins, called mutacins, which inhibit the growth of other Gram-positive bacteria. The goal of this study is to use a random insertional mutagenesis approach to search for genes that are associated with mutacin I production in the virulent strain UA140. A random insertional mutagenesis library consisting of 11,000 clones was constructed and screened for a mutacin-defective phenotype. Mutacin-defective clones were isolated, and their insertion sites were determined by PCR amplification or plasmid rescue followed by sequencing. A total of twenty-five unique genes were identified. These genes can be categorized into the following functional classes: two-component sensory systems, stress responses, energy metabolism and central cellular processes. Several conserved hypothetical proteins with unknown functions were also identified. These results suggest that mutacin I production is stringently controlled by diverse and complex regulatory pathways.

A Role for the SmpB-SsrA system in Yersinia pseudotuberculosis pathogenesis

Yersinia utilizes a sophisticated type III secretion system to enhance its chances of survival and to overcome the host immune system. SmpB (small protein B) and SsrA (small stable RNA A) are components of a unique bacterial translational control system that help maintain the bacterial translational machinery in a fully operational state. We have found that loss of the SmpB-SsrA function causes acute defects in the ability of Yersinia pseudotuberculosis to survive in hostile environments. Most significantly, we show that mutations in smpB-ssrA genes render the bacterium avirulent and unable to cause mortality in mice. Consistent with these observations, we show that the mutant strain is unable to proliferate in macrophages and exhibits delayed Yop-mediated host cell cytotoxicity. Correspondingly, we demonstrate that the smpB-ssrA mutant suffers severe deficiencies in expression and secretion of Yersinia virulence effector proteins, and that this defect is at the level of transcription. Of further interest is the finding that the SmpB-SsrA system might play a similar role in the related type III secretion system that governs flagella assembly and bacterial motility. These findings highlight the significance of the SmpB-SsrA system in bacterial pathogenesis, survival under adverse environmental conditions, and motility.

Bacteria have evolved sophisticated mechanisms to monitor, adapt, and respond to environmental and host-mediated assaults. Many Gram-negative pathogenic bacteria utilize a needle-like type III secretion system (TTSS) to inject a cocktail of effector proteins into host cells, disabling the host defenses against the pathogen. There is evolutionary, structural, and sequence similarity between this TTSS and the bacterial motility apparatus, the flagellum. Experiments described in this study examine the role played by the SmpB-SsrA system in Yersinia virulence, motility, and adaptation to adverse environments. The authors present evidence to demonstrate that an smpB-ssrA mutant of Yersinia pseudotuberculosis is more sensitive to adverse environmental conditions, lacks motility, exhibits severe defects in Yop secretion, and is avirulent in a mouse infection model. On the basis of these findings, they postulate that the SmpB-SsrA system, through its ribosome rescue, and protein tagging for directed degradation functions, affects the expression of the Ysc-Yop TTSS, and likely the flagellar TTSS, at the level of transcription. Their findings are consistent with a proposed regulatory role for the SmpB-SsrA system in regulation of bacterial gene expression.

Evidence for a second class of S-adenosylmethionine riboswitches and other regulatory RNA motifs in alpha-proteobacteria

Comparative sequence analysis and structural probing identified five RNA elements in the intergenic region of Agrobacterium tumefaciens and other α-proteobacteria. One of these RNA elements is probably a SAM-II, the only riboswitch class identified so far that is not found in Gram-positive bacteria.

Background

Riboswitches are RNA elements in the 5' untranslated leaders of bacterial mRNAs that directly sense the levels of specific metabolites with a structurally conserved aptamer domain to regulate expression of downstream genes. Riboswitches are most common in the genomes of low GC Gram-positive bacteria (for example, Bacillus subtilis contains examples of all known riboswitches), and some riboswitch classes seem to be restricted to this group.

Results

We used comparative sequence analysis and structural probing to identify five RNA elements (serC, speF, suhB, ybhL, and metA) that reside in the intergenic regions of Agrobacterium tumefaciens and many other α-proteobacteria. One of these, the metA motif, is found upstream of methionine biosynthesis genes and binds S-adenosylmethionine (SAM). This natural aptamer most likely functions as a SAM riboswitch (SAM-II) with a consensus sequence and structure that is distinct from the class of SAM riboswitches (SAM-I) predominantly found in Gram-positive bacteria. The minimal functional SAM-II aptamer consists of fewer than 70 nucleotides, which form a single stem and a pseudoknot. Despite its simple architecture and lower affinity for SAM, the SAM-II aptamer strongly discriminates against related compounds.

Conclusion

SAM-II is the only metabolite-binding riboswitch class identified so far that is not found in Gram-positive bacteria, and its existence demonstrates that biological systems can use multiple RNA structures to sense a single chemical compound. The two SAM riboswitches might be 'RNA World' relics that were selectively retained in certain bacterial lineages or new motifs that have emerged since the divergence of the major bacterial groups.

New elements of the termination of transcription in prokaryotes

We report here that phased runs of adenines and thymines are very frequent in the neighborhood of 3' of the coding regions of Escherichia coli and Bacillus subtilis. These findings suggest that the DNA curvature could affect transcription termination either directly, through contacts with RNA polymerase, or indirectly, via contacts with some regulatory proteins.

Conserved regulatory motifs in bacteria: riboswitches and beyond

We present a computational approach that identifies regulatory elements conserved across phylogenetically distant organisms. Intergenic regulatory regions were clustered by orthology of the adjacent genes, and an iterative process was applied to search for significant motifs, enabling new elements of the putative regulon to be added in each cycle. With this approach, we identified highly conserved riboswitches and the Gram positive T-box. Interestingly, we identified many other regulatory systems that appear to depend on conserved RNA structures.

A protein-dependent riboswitch controlling ptsGHI operon expression in Bacillus subtilis: RNA structure rather than sequence provides interaction specificity

The Gram-positive soil bacterium Bacillus subtilis transports glucose by the phosphotransferase system. The genes for this system are encoded in the ptsGHI operon. The expression of this operon is controlled at the level of transcript elongation by a protein-dependent riboswitch. In the absence of glucose a transcriptional terminator prevents elongation into the structural genes. In the presence of glucose, the GlcT protein is activated and binds and stabilizes an alternative RNA structure that overlaps the terminator and prevents termination. In this work, we have studied the structural and sequence requirements for the two mutually exclusive RNA structures, the terminator and the RNA antiterminator (the RAT sequence). In both cases, the structure seems to be more important than the actual sequence. The number of paired and unpaired bases in the RAT sequence is essential for recognition by the antiterminator protein GlcT. In contrast, mutations of individual bases are well tolerated as long as the general structure of the RAT is not impaired. The introduction of one additional base in the RAT changed its structure and resulted in complete loss of interaction with GlcT. In contrast, this mutant RAT was efficiently recognized by a different B.subtilis antitermination protein, LicT.

Features of a leader peptide coding region that regulate translation initiation for the anti-TRAP protein of B. subtilis

The rtpA gene of Bacillus subtilis encodes the Anti-TRAP protein, AT. AT can bind and inhibit the TRAP regulatory protein, preventing TRAP from promoting transcription termination in the trpEDCFBA operon leader region. AT synthesis is upregulated transcriptionally and translationally in response to the accumulation of uncharged tRNA(Trp). Here we analyze AT's translational regulation by rtpLP, a 10 residue leader peptide coding region located immediately preceding the rtpA Shine-Dalgarno sequence. Our findings suggest that, whenever the charged tRNA(Trp) level is sufficient to allow the ribosome translating rtpLP to reach its stop codon, it blocks the adjacent rtpA Shine-Dalgarno sequence, inhibiting AT synthesis. However, when there is a charged tRNA(Trp) deficiency, the translating ribosome presumably stalls at one of three adjacent rtpLP Trp codons. This stalling exposes the rtpA Shine-Dalgarno sequence, permitting AT synthesis. RNA-RNA pairing may also influence AT synthesis. Production of AT would inactivate TRAP, thereby increasing trp operon expression.

Can tRNAs act as antisense RNA? The case of mutA and dnaQ

Many mutator genes have been characterized in E. coli, but the realization that mutA, the most recent mutator pathway described, encodes for a missense suppressor glycine tRNA caused a real surprise. The connection between expression of mutA and a 10 times increase in the spontaneous mutation rate is not readily explainable. The first attempt to describe the mechanism of action suggested a direct mistranslation of one subunit of polymerase III (PolIII) and the ideal candidate was the epsilon subunit carrying the 3'-->5' exonuclease activity. This subunit increases PolIII accuracy about 100 times. However, such direct mistranslation of epsilon was later ruled out when it became clear that all mutA cells express an error-prone form of PolIII. This result could not be reconciled with the very low level of mistranslation (1%) caused by mutA. But there is no need to invoke amino acid misincorporation in epsilon to destroy its activity. On the contrary, I suggest a new way to regulate epsilon amount, based on the reinterpretation of the mutA pathway through the new and puzzling observation that several tRNAs (including mutA which encodes for a glycine missense suppressor tRNA) are complementary to the 5' end of dnaQ mRNA. Accordingly, I propose that uncharged tRNAs can act as antisense RNAs, decreasing translation of dnaQ and possibly other genes. This could represent a new regulatory function for tRNAs and of course gives a direct and unrecognized link between starvation and mutation rate.

An mRNA structure that controls gene expression by binding S-adenosylmethionine

Riboswitches are metabolite-binding RNA structures that serve as genetic control elements for certain messenger RNAs. These RNA switches have been identified in all three kingdoms of life and are typically responsible for the control of genes whose protein products are involved in the biosynthesis, transport or utilization of the target metabolite. Herein, we report that a highly conserved RNA domain found in bacteria serves as a riboswitch that responds to the coenzyme S-adenosylmethionine (SAM) with remarkably high affinity and specificity. SAM riboswitches undergo structural reorganization upon introduction of SAM, and these allosteric changes regulate the expression of 26 genes in Bacillus subtilis. This and related findings indicate that direct interaction between small metabolites and allosteric mRNAs is an important and widespread form of genetic regulation in bacteria.

tRNA requirements for glyQS antitermination: a new twist on tRNA

Transcription antitermination of the Bacillus subtilis glyQS gene, a member of the T box gene regulation family, can be induced during in vitro transcription in a minimal system using purified B. subtilis RNA polymerase by the addition of unmodified T7 RNA polymerase-transcribed tRNA(Gly). Antitermination was previously shown to depend on base-pairing between the glyQS leader and the tRNA at the anticodon and acceptor ends. In this study, variants of tRNA(Gly) were generated to identify additional tRNA elements required for antitermination activity, and to determine the effect of structural changes in the tRNA. We find that additions to the 3' end of the tRNA blocked antitermination, in agreement with the prediction that uncharged tRNA is the effector in vivo, whereas insertion of 1 nucleotide between the acceptor stem and the 3' UCCA residues had no effect. Disruption of the D-loop/T-loop tertiary interaction inhibited antitermination function, as was previously demonstrated for tRNA(Tyr)-directed antitermination of the B. subtilis tyrS gene in vivo. Insertion of a single base pair in the anticodon stem was tolerated, whereas further insertions abolished antitermination. However, we find that major alterations in the length of the acceptor stem are tolerated, and the insertions exhibited a pattern of periodicity suggesting that there is face-of-the-helix dependence in the positioning of the unpaired UCCA residues at the 3' end of the tRNA for interaction with the antiterminator bulge and antitermination.

RNA-structural mimicry in Escherichia coli ribosomal protein L4-dependent regulation of the S10 operon

Ribosomal protein L4 regulates the 11-gene S10 operon in Escherichia coli by acting, in concert with transcription factor NusA, to cause premature transcription termination at a Rho-independent termination site in the leader sequence. This process presumably involves L4 interaction with the leader mRNA. Here, we report direct, specific, and independent binding of ribosomal protein L4 to the S10 mRNA leader in vitro. Most of the binding energy is contributed by a small hairpin structure within the leader region, but a 64-nucleotide sequence is required for the bona fide interaction. Binding to the S10 leader mRNA is competed by the 23 S rRNA L4 binding site. Although the secondary structures of the mRNA and rRNA binding sites appear different, phosphorothioate footprinting of the L4-RNA complexes reveals close structural similarity in three dimensions. Mutational analysis of the mRNA binding site is compatible with the structural model. In vitro binding of L4 induces structural changes of the S10 leader RNA, providing a first clue for how protein L4 may provoke transcription termination.

Tandem transcription and translation regulatory sensing of uncharged tryptophan tRNA

The Bacillus subtilis AT (anti-TRAP) protein inhibits the regulatory protein TRAP (trp RNA-binding attenuation protein), thereby eliminating transcription termination in the leader region of the trp operon. Transcription of the AT operon is activated by uncharged tryptophan transfer RNA (tRNATrp). Here we show that translation of AT also is regulated by uncharged tRNATrp. A 10-residue coding region containing three consecutive tryptophan codons is located immediately preceding the AT structural gene. Completion of translation of this coding region inhibits AT synthesis, whereas incomplete translation increases AT production. Tandem sensing of uncharged tRNATrp therefore regulates synthesis of AT, which in turn regulates TRAP's ability to inhibit trp operon expression.

Genomewide transcriptional changes associated with genetic alterations and nutritional supplementation affecting tryptophan metabolism in Bacillus subtilis

DNA microarrays comprising approximately 95% of the Bacillus subtilis annotated protein coding ORFs were deployed to generate a series of snapshots of genomewide transcriptional changes that occur when cells are grown under various conditions that are expected to increase or decrease transcription of the trp operon segment of the aromatic supraoperon. Comparisons of global expression patterns were made between cells grown in the presence of indole acrylic acid, a specific inhibitor of tRNA(Trp) charging; cells deficient in expression of the mtrB gene, which encodes the tryptophan-activated negative regulatory protein, TRAP; WT cells grown in the presence or absence of two or three of the aromatic amino acids; and cells harboring a tryptophanyl tRNA synthetase mutation conferring temperature-sensitive tryptophan-dependent growth. Our findings validate expected responses of the tryptophan biosynthetic genes and presumed regulatory interrelationships between genes in the different aromatic amino acid pathways and the histidine biosynthetic pathway. Using a combination of supervised and unsupervised statistical methods we identified approximately 100 genes whose expression profiles were closely correlated with those of the genes in the trp operon. This finding suggests that expression of these genes is influenced directly or indirectly by regulatory events that affect or are a consequence of altered tryptophan metabolism.

Transcription termination control of the S box system: direct measurement of S-adenosylmethionine by the leader RNA

Modulation of the structure of a leader RNA to control formation of an intrinsic termination signal is a common mechanism for regulation of gene expression in bacteria. Expression of the S box genes in Gram-positive organisms is induced in response to limitation for methionine. We previously postulated that methionine availability is monitored by binding of a regulatory factor to the leader RNA and suggested that methionine or S-adenosylmethionine (SAM) could serve as the metabolic signal. In this study, we show that efficient termination of the S box leader region by bacterial RNA polymerase depends on SAM but not on methionine or other related compounds. We also show that SAM directly binds to and induces a conformational change in the leader RNA. Both binding of SAM and SAM-directed transcription termination were blocked by leader mutations that cause constitutive expression in vivo. Overproduction of SAM synthetase in Bacillus subtilis resulted in delay in induction of S box gene expression in response to methionine starvation, consistent with the hypothesis that SAM is the molecular effector in vivo. These results indicate that SAM concentration is sensed directly by the nascent transcript in the absence of a trans-acting factor.

Expression of the glycolytic gapA operon in Bacillus subtilis: differential syntheses of proteins encoded by the operon

Glycolysis is one of the central routes of carbon catabolism in Bacillus subtilis. Several glycolytic enzymes, including the key enzyme glyceraldehyde-3-phosphate dehydrogenase, are encoded in the hexacistronic gapA operon. Expression of this operon is induced by a variety of sugars and amino acids. Under non-inducing conditions, expression is repressed by the CggR repressor protein, the product of the promoter-proximal gene of the operon. Here, it is shown that the amount of glyceraldehyde-3-phosphate dehydrogenase encoded by the second gene of the operon exceeds that of the CggR repressor by about 100-fold. This differential synthesis was attributed to an mRNA processing event that takes place at the 3' end of the cggR open reading frame and to differential segmental stabilities of the resulting cleavage products. The mRNA specifying the truncated cggR gene is quickly degraded, whereas the downstream processing products encompassing gapA are quite stable. This increased stability is conferred by the presence of a stem-loop structure at the 5' end of the processed mRNAs. Mutations were introduced in the region of the cleavage site. A mutation affecting the stability of the stem-loop structure immediately downstream of the processing site had two effects. First, the steady-state transcript pattern was drastically shifted towards the primary transcripts; second, the stability of the processed mRNA containing the destabilized stem-loop structure was strongly decreased. This results in a reduction of the amount of glyceraldehyde-3-phosphate dehydrogenase in the cell. It is concluded that mRNA processing is involved in differential syntheses of the proteins encoded by the gapA operon.