Interaction of the sigma factor and the nusA gene protein of E. coli with RNA polymerase in the initiation-termination cycle of transcription

Dynamic competition between a ligand and transcription factor NusA governs riboswitch-mediated transcription regulation

Cotranscriptional RNA folding is widely assumed to influence the timely control of gene expression, but our understanding remains limited. In bacteria, the fluoride (F^-)-sensing riboswitch is a transcriptional control element essential to defend against toxic F^- levels. Using this model riboswitch, we find that its ligand F^- and essential bacterial transcription factor NusA compete to bind the cotranscriptionally folding RNA, opposing each other's modulation of downstream pausing and termination by RNA polymerase. Single-molecule fluorescence assays probing active transcription elongation complexes discover that NusA unexpectedly binds highly reversibly, frequently interrogating the complex for emerging, cotranscriptionally folding RNA duplexes. NusA thus fine-tunes the transcription rate in dependence of the ligand-responsive higher-order structure of the riboswitch. At the high NusA concentrations found intracellularly, this dynamic modulation is expected to lead to adaptive bacterial transcription regulation with fast response times.

The transcriptional response of Arcobacter butzleri to cold shock

Arcobacter (A.) butzleri is an emerging zoonotic pathogen associated with gastrointestinal diseases, such as abdominal cramps and diarrhea, and is widely detected in animals, showing a high prevalence in poultry and seafood. The survival and adaptation of A. butzleri to cold temperatures remains poorly studied, although it might be of interest for food safety considerations. To address this, growth patterns of eight A. butzleri isolates were determined at 8 °C for 28 days. A. butzleri isolates showed strain‐dependent behavior: six isolates were unculturable after day 18, one exhibited declining but detectable cell counts until day 28 and one grew to the stationary phase level. Out of 13 A. butzleri cold shock‐related genes homologous to Escherichia coli, 10 were up‐regulated in response to a temperature downshift to 8 °C, as demonstrated by reverse transcription‐quantitative PCR. Additionally, we compared these data with the cold‐shock response in E. coli. Overall, we provide a deeper insight into the environmental adaptation capacities of A. butzleri, which we find shares similarities with the E. coli cold‐shock response.

The Mechanisms of Substrate Selection, Catalysis, and Translocation by the Elongating RNA Polymerase

Multi-subunit DNA-dependent RNA polymerases synthesize all classes of cellular RNAs, ranging from short regulatory transcripts to gigantic messenger RNAs. RNA polymerase has to make each RNA product in just one try, even if it takes millions of successive nucleotide addition steps. During each step, RNA polymerase selects a correct substrate, adds it to a growing chain, and moves one nucleotide forward before repeating the cycle. However, RNA synthesis is anything but monotonous: RNA polymerase frequently pauses upon encountering mechanical, chemical and torsional barriers, sometimes stepping back and cleaving off nucleotides from the growing RNA chain. A picture in which these intermittent dynamics enable processive, accurate, and controllable RNA synthesis is emerging from complementary structural, biochemical, computational, and single-molecule studies. Here, we summarize our current understanding of the mechanism and regulation of the on-pathway transcription elongation. We review the details of substrate selection, catalysis, proofreading, and translocation, focusing on rate-limiting steps, structural elements that modulate them, and accessory proteins that appear to control RNA polymerase translocation.

Extrachromosomal Nucleolus-Like Compartmentalization by a Plasmid-Borne Ribosomal RNA Operon and Its Role in Nucleoid Compaction

In the fast-growing Escherichia coli cells, RNA polymerase (RNAP) molecules are concentrated and form foci at clusters of ribosomal RNA (rRNA) operons resembling eukaryotic nucleolus. The bacterial nucleolus-like organization, spatially compartmentalized at the surface of the compact bacterial chromosome (nucleoid), serves as transcription factories for rRNA synthesis and ribosome biogenesis, which influences the organization of the nucleoid. Unlike wild type that has seven rRNA operons in the genome in a mutant that has six (Δ6rrn) rRNA operons deleted in the genome, there are no apparent transcription foci and the nucleoid becomes uncompacted, indicating that formation of RNAP foci requires multiple copies of rRNA operons clustered in space and is critical for nucleoid compaction. It has not been determined, however, whether a multicopy plasmid-borne rRNA operon (prrnB) could substitute the multiple chromosomal rRNA operons for the organization of the bacterial nucleolus-like structure in the mutants of Δ6rrn and Δ7rrn that has all seven rRNA operons deleted in the genome. We hypothesized that extrachromosomal nucleolus-like structures are similarly organized and functional in trans from prrnB in these mutants. In this report, using multicolor images of three-dimensional superresolution Structured Illumination Microscopy (3D-SIM), we determined the distributions of both RNAP and NusB that are a transcription factor involved in rRNA synthesis and ribosome biogenesis, prrnB clustering, and nucleoid structure in these two mutants in response to environmental cues. Our results found that the extrachromosomal nucleolus-like organization tends to be spatially located at the poles of the mutant cells. In addition, formation of RNAP foci at the extrachromosomal nucleolus-like structure condenses the nucleoid, supporting the idea that active transcription at the nucleolus-like organization is a driving force in nucleoid compaction.

Nucleolus-like compartmentalization of the transcription machinery in fast-growing bacterial cells

We have learned a great deal about RNA polymerase (RNA Pol), transcription factors, and the transcriptional regulation mechanisms in prokaryotes for specific genes, operons, or transcriptomes. However, we have only begun to understand how the transcription machinery is three-dimensionally (3D) organized into bacterial chromosome territories to orchestrate the transcription process and to maintain harmony with the replication machinery in the cell. Much progress has been made recently in our understanding of the spatial organization of the transcription machinery in fast-growing Escherichia coli cells using state-of-the-art superresolution imaging techniques. Co-imaging of RNA polymerase (RNA Pol) with DNA and transcription elongation factors involved in ribosomal RNA (rRNA) synthesis, and ribosome biogenesis has revealed similarities between bacteria and eukaryotes in the spatial organization of the transcription machinery for growth genes, most of which are rRNA genes. Evidence supports the notion that RNA Pol molecules are concentrated, forming foci at the clustering of rRNA operons resembling the eukaryotic nucleolus. RNA Pol foci are proposed to be active transcription factories for both rRNA genes expression and ribosome biogenesis to support maximal growth in optimal growing conditions. Thus, in fast-growing bacterial cells, RNA Pol foci mimic eukaryotic Pol I activity, and transcription factories resemble nucleolus-like compartmentation. In addition, the transcription and replication machineries are mostly segregated in space to avoid the conflict between the two major cellular functions in fast-growing cells.

Nus Factors of Escherichia coli

The highly conserved Nus factors of bacteria were discovered as essential host proteins for the growth of temperate phage λ in Escherichia coli. Later, their essentiality and functions in transcription, translation, and, more recently, in DNA repair have been elucidated. Close involvement of these factors in various gene networks and circuits is also emerging from recent genomic studies. We have described a detailed overview of their biochemistry, structures, and various cellular functions, as well as their interactions with other macromolecules. Towards the end, we have envisaged different uncharted areas of studies with these factors, including their participation in pathogenicity.

Nus Factors of Escherichia coli

The Nus factors-NusA, NusB, NusE, and NusG-area set of well-conserved proteins in bacteria and are involved in transcription elongation, termination, antitermination, and translation processes. Originally, Escherichia coli host mutations defective for supporting bacteriophage λ N-mediated antitermination were mapped to the nusA (nusA1), nusB (nusB5, nusB101), and nusE (nusE71) genes, and hence, these genes were named nus for Nutilization substances (Nus). Subsequently,the Nus factors were purified and their roles in different host functions were elucidated. Except for NusB, deletion of which is conditionally lethal, all the other Nus factors are essential for E. coli. Among the Nus factors, NusA has the most varied functions. It specifically binds to RNA polymerase (RNAP), nascent RNA, and antiterminator proteins like N and Q and hence takes part in modulating transcription elongation, termination, and antitermination. It is also involved in DNA repair pathways. NusG interacts with RNAP and the transcription termination factor Rho and therefore is involved in both factor-dependent termination and transcription elongation processes. NusB and NusE are mostly important in antitermination at the ribosomal operon-transcription. NusE is a component of ribosome and may take part in facilitating the coupling between transcription and translation. This chapter emphasizes the structure-function relationship of these factors and their involvement in different fundamental cellular processes from a mechanistic angle.

The dynamic nature and territory of transcriptional machinery in the bacterial chromosome

Our knowledge of the regulation of genes involved in bacterial growth and stress responses is extensive; however, we have only recently begun to understand how environmental cues influence the dynamic, three-dimensional distribution of RNA polymerase (RNAP) in Escherichia coli on the level of single cell, using wide-field fluorescence microscopy and state-of-the-art imaging techniques. Live-cell imaging using either an agarose-embedding procedure or a microfluidic system further underscores the dynamic nature of the distribution of RNAP in response to changes in the environment and highlights the challenges in the study. A general agreement between live-cell and fixed-cell images has validated the formaldehyde-fixing procedure, which is a technical breakthrough in the study of the cell biology of RNAP. In this review we use a systems biology perspective to summarize the advances in the cell biology of RNAP in E. coli, including the discoveries of the bacterial nucleolus, the spatial compartmentalization of the transcription machinery at the periphery of the nucleoid, and the segregation of the chromosome territories for the two major cellular functions of transcription and replication in fast-growing cells. Our understanding of the coupling of transcription and bacterial chromosome (or nucleoid) structure is also summarized. Using E. coli as a simple model system, co-imaging of RNAP with DNA and other factors during growth and stress responses will continue to be a useful tool for studying bacterial growth and adaptation in changing environment.

Spatial organization of transcription machinery and its segregation from the replisome in fast-growing bacterial cells

In a fast-growing Escherichia coli cell, most RNA polymerase (RNAP) is allocated to rRNA synthesis forming transcription foci at clusters of rrn operons or bacterial nucleolus, and each of the several nascent nucleoids contains multiple pairs of replication forks. The composition of transcription foci has not been determined. In addition, how the transcription machinery is three-dimensionally organized to promote cell growth in concord with replication machinery in the nucleoid remains essentially unknown. Here, we determine the spatial and functional landscapes of transcription and replication machineries in fast-growing E. coli cells using super-resolution-structured illumination microscopy. Co-images of RNAP and DNA reveal spatial compartmentation and duplication of the transcription foci at the surface of the bacterial chromosome, encompassing multiple nascent nucleoids. Transcription foci cluster with NusA and NusB, which are the rrn anti-termination system and are associated with nascent rRNAs. However, transcription foci tend to separate from SeqA and SSB foci, which track DNA replication forks and/or the replisomes, demonstrating that transcription machinery and replisome are mostly located in different chromosomal territories to maintain harmony between the two major cellular functions in fast-growing cells. Our study suggests that bacterial chromosomes are spatially and functionally organized, analogous to eukaryotes.

Multiple strategies for translesion synthesis in bacteria

Damage to DNA is common and can arise from numerous environmental and endogenous sources. In response to ubiquitous DNA damage, Y-family DNA polymerases are induced by the SOS response and are capable of bypassing DNA lesions. In Escherichia coli, these Y-family polymerases are DinB and UmuC, whose activities are modulated by their interaction with the polymerase manager protein UmuD. Many, but not all, bacteria utilize DinB and UmuC homologs. Recently, a C-family polymerase named ImuC, which is similar in primary structure to the replicative DNA polymerase DnaE, was found to be able to copy damaged DNA and either carry out or suppress mutagenesis. ImuC is often found with proteins ImuA and ImuB, the latter of which is similar to Y‑family polymerases, but seems to lack the catalytic residues necessary for polymerase activity. This imuAimuBimuC mutagenesis cassette represents a widespread alternative strategy for translesion synthesis and mutagenesis in bacteria. Bacterial Y‑family and ImuC DNA polymerases contribute to replication past DNA damage and the acquisition of antibiotic resistance.

New discoveries linking transcription to DNA repair and damage tolerance pathways

In Escherichia coli, the transcription elongation factor NusA is associated with all elongating RNA polymerases where it functions in transcription termination and antitermination. Here, we review our recent results implicating NusA in the recruitment of DNA repair and damage tolerance mechanisms to sites of stalled transcription complexes.

NusA interaction with the α subunit of E. coli RNA polymerase is via the UP element site and releases autoinhibition

Elongating Escherichia coli RNAP is modulated by NusA protein. The C-terminal domain (CTD) of the RNAP α subunit (αCTD) interacts with the acidic CTD 2 (AR2) of NusA, releasing the autoinhibitory blockade of the NusA S1-KH1-KH2 motif and allowing NusA to bind nascent nut spacer RNA. We determined the solution conformation of the AR2:αCTD complex. The αCTD residues that interface with AR2 are identical to those that recognize UP promoter elements A nusA-ΔAR2 mutation does not affect UP-dependent rrnH transcription initiation in vivo. Instead, the mutation inhibits Rho-dependent transcription termination at phage λtR1, which lies adjacent to the λnutR sequence. The Rho-dependent λtimm terminator, which is not preceded by a λnut sequence, is fully functional. We propose that constitutive binding of NusA-ΔAR2 to λnutR occludes Rho. In addition, the mutation confers a dominant defect in exiting stationary phase.

Growth rate regulation in Escherichia coli

Growth rate regulation in bacteria has been an important issue in bacterial physiology for the past 50 years. This review, using Escherichia coli as a paradigm, summarizes the mechanisms for the regulation of rRNA synthesis in the context of systems biology, particularly, in the context of genome-wide competition for limited RNA polymerase (RNAP) in the cell under different growth conditions including nutrient starvation. The specific location of the seven rrn operons in the chromosome and the unique properties of the rrn promoters contribute to growth rate regulation. The length of the rrn transcripts, coupled with gene dosage effects, influence the distribution of RNAP on the chromosome in response to growth rate. Regulation of rRNA synthesis depends on multiple factors that affect the structure of the nucleoid and the allocation of RNAP for global gene expression. The magic spot ppGpp, which acts with DksA synergistically, is a key effector in both the growth rate regulation and the stringent response induced by nutrient starvation, mainly because the ppGpp level changes in response to environmental cues. It regulates rRNA synthesis via a cascade of events including both transcription initiation and elongation, and can be explained by an RNAP redistribution (allocation) model.

Σ(70)-dependent transcription pausing in Escherichia coli

After promoter escape in Escherichia coli, the initiating σ(70) factor is retained by core RNA polymerase (RNAP) for at least tens of nucleotides. While it is bound, σ(70) can engage a repeat of a promoter DNA element located downstream of the promoter and thereby induce a transcription pause. The σ(70)-dependent promoter-proximal pause that occurs at all lambdoid phage late gene promoters is essential to regulation of the late gene operons. Several, and possibly many, E. coli promoters have associated σ(70)-dependent pauses. Clearly characterized σ(70)-dependent pauses occur within 25 nucleotides of the start site, but σ(70)-dependent pausing might occur farther downstream as well. In this review, we summarize evidence for σ(70)-dependent promoter-proximal and promoter-distal pausing, and we discuss its potential regulatory function and mechanistic basis.

Molecular association of the Arabidopsis ETR1 ethylene receptor and a regulator of ethylene signaling, RTE1

The plant hormone ethylene plays important roles in growth and development. Ethylene is perceived by a family of membrane-bound receptors that actively repress ethylene responses. When the receptors bind ethylene, their signaling is shut off, activating responses. REVERSION-TO-ETHYLENE SENSITIVITY (RTE1) encodes a novel membrane protein conserved in plants and metazoans. Genetic analyses in Arabidopsis thaliana suggest that RTE1 promotes the signaling state of the ethylene receptor ETR1 through the ETR1 N-terminal domain. RTE1 and ETR1 have been shown to co-localize to the endoplasmic reticulum (ER) and Golgi apparatus in Arabidopsis. Here, we demonstrate a physical association of RTE1 and ETR1 using in vivo and in vitro methods. Interaction of RTE1 and ETR1 was revealed in vivo by bimolecular fluorescence complementation (BiFC) in a tobacco cell transient assay and in stably transformed Arabidopsis. The association was also observed using a truncated version of ETR1 comprising the N terminus (amino acids 1-349). Interaction of RTE1 and ETR1 was confirmed by co-immunoprecipitation from Arabidopsis. The interaction occurs with high affinity (K(d), 117 nM) based on tryptophan fluorescence spectroscopy using purified recombinant RTE1 and a tryptophan-less version of purified recombinant ETR1. An amino acid substitution (C161Y) in RTE1 that is known to confer an ETR1 loss-of-function phenotype correspondingly gives a nearly 12-fold increase in the dissociation constant (K(d), 1.38 μM). These findings indicate that a high affinity association of RTE1 and ETR1 is important in the regulation of ETR1.

RNA polymerase trafficking in Bacillus subtilis cells

To obtain insight into the in vivo dynamics of RNA polymerase (RNAP) on the Bacillus subtilis genome, we analyzed the distribution of the σ(A) and β' subunits of RNAP and the NusA elongation factor on the genome in exponentially growing cells using chromatin affinity precipitation coupled with gene chip mapping (ChAP-chip). In contrast to Escherichia coli RNAP, which often accumulates at the promoter-proximal region, B. subtilis RΝΑP is evenly distributed from the promoter to the coding sequences. This finding suggests that, in general, B. subtilis RNAP recruited to the promoter promptly translocates away from the promoter to form the elongation complex and proceeds without intragenic transcription attenuation. We detected RNAP accumulation in the promoter-proximal regions of some genes, most of which can be identified as transcription attenuation systems in the leader region. Our findings suggest that the differences in RNAP behavior between E. coli and B. subtilis during initiation and elongation steps might result in distinct strategies for postinitiation control of transcription. The E. coli mechanism involves trapping at the promoter and promoter-proximal pausing of RNAP in addition to transcription attenuation, whereas transcription attenuation in leader sequences is mainly employed in B. subtilis.

Roles for the transcription elongation factor NusA in both DNA repair and damage tolerance pathways in Escherichia coli

We report observations suggesting that the transcription elongation factor NusA promotes a previously unrecognized class of transcription-coupled repair (TCR) in addition to its previously proposed role in recruiting translesion synthesis (TLS) DNA polymerases to gaps encountered during transcription. Earlier, we reported that NusA physically and genetically interacts with the TLS DNA polymerase DinB (DNA pol IV). We find that Escherichia coli nusA11(ts) mutant strains, at the permissive temperature, are highly sensitive to nitrofurazone (NFZ) and 4-nitroquinolone-1-oxide but not to UV radiation. Gene expression profiling suggests that this sensitivity is unlikely to be due to an indirect effect on gene expression affecting a known DNA repair or damage tolerance pathway. We demonstrate that an N(2)-furfuryl-dG (N(2)-f-dG) lesion, a structural analog of the principal lesion generated by NFZ, blocks transcription by E. coli RNA polymerase (RNAP) when present in the transcribed strand, but not when present in the nontranscribed strand. Our genetic analysis suggests that NusA participates in a nucleotide excision repair (NER)-dependent process to promote NFZ resistance. We provide evidence that transcription plays a role in the repair of NFZ-induced lesions through the isolation of RNAP mutants that display altered ability to survive NFZ exposure. We propose that NusA participates in an alternative class of TCR involved in the identification and removal of a class of lesion, such as the N(2)-f-dG lesion, which are accurately and efficiently bypassed by DinB in addition to recruiting DinB for TLS at gaps encountered by RNAP.

RapA, the SWI/SNF subunit of Escherichia coli RNA polymerase, promotes the release of nascent RNA from transcription complexes

RapA, a prokaryotic member of the SWI/SNF protein superfamily, is an integral part of the RNA polymerase transcription complex. RapA's function and catalytic mechanism have been linked to nucleic acid remodeling. In this work, we show that mutations in the interface between RapA's SWI/SNF and double-stranded nucleic acid-binding domains significantly alter ATP hydrolysis in purified RapA. The effects of individual mutations on ATP hydrolysis loosely correlated with RapA's nucleic acid remodeling activity, indicating that the interaction between these domains may be important for the RapA-mediated remodeling of nonproductive transcription complexes. In this study, we introduced a model system for in vitro transcription of a full-length Escherichia coli gene (slyD). To study the function of RapA, we fractionated and identified in vitro transcription reaction intermediates in the presence or absence of RapA. These experiments demonstrated that RapA contributes to the formation of free RNA species during in vitro transcription. This work further refines our models for RapA function in vivo and establishes a new role in RNA management for a representative of the SWI/SNF protein superfamily.

Regulator trafficking on bacterial transcription units in vivo

The trafficking patterns of the bacterial regulators of transcript elongation sigma(70), rho, NusA, and NusG on genes in vivo and the explanation for promoter-proximal peaks of RNA polymerase (RNAP) are unknown. Genome-wide, E. coli ChIP-chip revealed distinct association patterns of regulators as RNAP transcribes away from promoters (rho first, then NusA, then NusG). However, the interactions of elongating complexes with these regulators did not differ significantly among most transcription units. A modest variation of NusG signal among genes reflected increased NusG interaction as transcription progresses, rather than functional specialization of elongating complexes. Promoter-proximal RNAP peaks were offset from sigma(70) peaks in the direction of transcription and co-occurred with NusA and rho peaks, suggesting that the RNAP peaks reflected elongating, rather than initiating, complexes. However, inhibition of rho did not increase RNAP levels within genes downstream from the RNAP peaks, suggesting the peaks are caused by a mechanism other than rho-dependent attenuation.

Transcriptional modulator NusA interacts with translesion DNA polymerases in Escherichia coli

NusA, a modulator of RNA polymerase, interacts with the DNA polymerase DinB. An increased level of expression of dinB or umuDC suppresses the temperature sensitivity of the nusA11 strain, requiring the catalytic activities of these proteins. We propose that NusA recruits translesion DNA synthesis (TLS) polymerases to RNA polymerases stalled at gaps, coupling TLS to transcription.

Identification of the genetic determinants of Salmonella enterica serotype Typhimurium that may regulate the expression of the type 1 fimbriae in response to solid agar and static broth culture conditions

Background

Type 1 fimbriae are the most commonly found fimbrial appendages on the outer membrane of Salmonella enterica serotype Typhimurium. Previous investigations indicate that static broth culture favours S. Typhimurium to produce type 1 fimbriae, while non-fimbriate bacteria are obtained by growth on solid agar media. The phenotypic expression of type 1 fimbriae in S. Typhimurium is the result of the interaction and cooperation of several genes in the fim gene cluster. Other gene products that may also participate in the regulation of type 1 fimbrial expression remain uncharacterized.

Results

In the present study, transposon insertion mutagenesis was performed on S. Typhimurium to generate a library to screen for those mutants that would exhibit different type 1 fimbrial phenotypes than the parental strain. Eight-two mutants were obtained from 7,239 clones screened using the yeast agglutination test. Forty-four mutants produced type 1 fimbriae on both solid agar and static broth media, while none of the other 38 mutants formed type 1 fimbriae in either culture condition. The flanking sequences of the transposons from 54 mutants were cloned and sequenced. These mutants can be classified according to the functions or putative functions of the open reading frames disrupted by the transposon. Our current results indicate that the genetic determinants such as those involved in the fimbrial biogenesis and regulation, global regulators, transporter proteins, prophage-derived proteins, and enzymes of different functions, to name a few, may play a role in the regulation of type 1 fimbrial expression in response to solid agar and static broth culture conditions. A complementation test revealed that transforming a recombinant plasmid possessing the coding sequence of a NAD(P)H-flavin reductase gene ubiB restored an ubiB mutant to exhibit the type 1 fimbrial phenotype as its parental strain.

Conclusion

Genetic determinants other than the fim genes may involve in the regulation of type 1 fimbrial expression in S. Typhimurium. How each gene product may influence type 1 fimbrial expression is an interesting research topic which warrants further investigation.

Overexpression of phage HK022 Nun protein is toxic for Escherichia coli

The Nun protein of coliphage HK022 excludes superinfecting lambda phage. Nun recognizes and binds to the N utilization (nut) sites on phage lambda nascent RNA and induces transcription termination. Overexpression of Nun from a high-copy plasmid is toxic for Escherichia coli, despite the fact that nut sites are not encoded in the E. coli genome. Cells expressing Nun cannot exit stationary phase. Toxicity is related to transcription termination, since host and nun mutations that block termination also suppress cell killing. Nun inhibits expression of wild-type lacZ, but not lacZ expressed from the Crp/cAMP-independent lacUV5 promoter. Microarray and proteomic analyses show that Nun down-regulates crp and tnaA. Crp overexpression and high indole concentrations partially reverse Nun-mediated toxicity and restore lacZ expression.

The elongation factor RfaH and the initiation factor sigma bind to the same site on the transcription elongation complex

RNA polymerase is a target for numerous regulatory events in all living cells. Recent studies identified a few "hot spots" on the surface of bacterial RNA polymerase that mediate its interactions with diverse accessory proteins. Prominent among these hot spots, the beta' subunit clamp helices serve as a major binding site for the initiation factor sigma and for the elongation factor RfaH. Furthermore, the two proteins interact with the nontemplate DNA strand in transcription complexes and thus may interfere with each other's activity. We show that RfaH does not inhibit transcription initiation but, once recruited to RNA polymerase, abolishes sigma-dependent pausing. We argue that this apparent competition is due to a steric exclusion of sigma by RfaH that is stably bound to the nontemplate DNA and clamp helices, both of which are necessary for the sigma recruitment to the transcription complex. Our findings highlight the key regulatory role played by the clamp helices during both initiation and elongation stages of transcription.

Transcription termination factor rho can displace streptavidin from biotinylated RNA

In Escherichia coli, binding of the hexameric Rho protein to naked C-rich Rut (Rho utilization) regions of nascent RNA transcripts initiates Rho-dependent termination of transcription. Although the ring-shaped Rho factor exhibits in vitro RNA-dependent ATPase and directional RNA-DNA helicase activities, the actual molecular mechanisms used by Rho to disrupt the intricate network of interactions that cement the ternary transcription complex remain elusive. Here, we show that Rho is a molecular motor that can apply significant disruptive forces on heterologous nucleoprotein assemblies such as streptavidin bound to biotinylated RNA molecules. ATP-dependent disruption of the biotin-streptavidin interaction demonstrates that Rho is not mechanistically limited to the melting of nucleic acid base pairs within molecular complexes and confirms that specific interactions with the roadblock target are not required for Rho to operate properly. We also show that Rho-induced streptavidin displacement depends significantly on the identity of the biotinylated transcript as well as on the position, nature, and length of the biotin link to the RNA chain. Altogether, our data are consistent with a "snow plough" type of mechanism of action whereby an early rearrangement of the Rho-substrate complex (activation) is rate-limiting, physical force (pulling) is exerted on the RNA chain by residues of the central Rho channel, and removal of structural obstacles from the RNA track stems from their nonspecific steric exclusion from the hexamer central hole. In this context, a simple model for the regulation of Rho-dependent termination based on the modulation of disruptive dynamic loading by secondary factors is proposed.

Role of E.coli NusA in phage HK022 Nun-mediated transcription termination

The 109 amino acid residue Nun protein expressed from prophage HK022 excludes superinfecting phage lambda by arresting transcription on the lambda chromosome near the lambdanut sites. In vitro, the Nun N terminus binds to nascent lambdanutRNA, whereas the C terminus interacts with RNA polymerase and DNA template. Escherichia coli host factors, NusA, NusB, NusE (S10), and NusG, stimulate Nun-arrest. NusA binds the Nun C terminus and enhances formation of the Nun-nutRNA complex. Because of these in vitro activities of NusA, and since a nusA mutation (nusAE136K) blocked Nun in vivo, we assumed that NusA was required for Nun activity. However, using a nusAts strain, we find that NusA is required for termination at nutR but not at nutL. Furthermore, nusAE136K is dominant to nusA(+) for Nun-arrest, both in vitro and in vivo. NusAE136K shows increased affinity for Nun and, unlike NusA(+), can readily be recovered in a ternary complex with Nun and nutRNA. We propose NusAE136K suppresses Nun-arrest when it is a component of the transcription elongation complex, perhaps, in part, by blocking interactions between the Nun C terminus and RNA polymerase and DNA. We also find that in contrast to Nun-arrest, antitermination by lambda N requires NusA.

Bacterial transcription elongation factors: new insights into molecular mechanism of action

Like transcription initiation, the elongation and termination stages of transcription cycle serve as important targets for regulatory factors in prokaryotic cells. In this review, we discuss the recent progress in structural and biochemical studies of three evolutionarily conserved elongation factors, GreA, NusA and Mfd. These factors affect RNA polymerase (RNAP) processivity by modulating transcription pausing, arrest, termination or anti-termination. With structural information now available for RNAP and models of ternary elongation complexes, the interaction between these factors and RNAP can be modelled, and possible molecular mechanisms of their action can be inferred. The models suggest that these factors interact with RNAP at or near its three major, nucleic acid-binding channels: Mfd near the upstream opening of the primary (DNA-binding) channel, NusA in the vicinity of both the primary channel and the RNA exit channel, and GreA within the secondary (backtracked RNA-binding) channel, and support the view that these channels are involved in the maintenance of RNAP processivity.

Association of RNA polymerase with transcribed regions in Escherichia coli

We examine the association of the beta-, alpha-, and sigma(70)-subunits of Escherichia coli RNA polymerase (RNAP) and the NusA elongation factor with transcribed regions in vivo by using chromatin immunoprecipitation. RNAP preferentially associates with the promoter-proximal region of several operons, and this preference is particularly pronounced at the lexA-dinF promoter. When cells are grown in exponential phase, little or no sigma(70) is associated with RNAP during early elongation. However, during stationary phase, sigma(70) is retained in a fraction of elongating RNAP complexes throughout the melAB operon. In contrast, sigma(70) is not observed in elongating RNAP complexes at the lacZYA operon during stationary phase. At both operons, NusA associates with RNAP during early elongation, and this association is greatly reduced during stationary phase. These observations suggest that in vivo association of sigma(70) and NusA with elongating RNAP is regulated by growth conditions.

Translation repression by an RNA polymerase elongation complex

Bacteriophage lambda N and bacterial Nus proteins together with a unique site NUT in the leader of the early viral N gene transcript bind RNA polymerase (RNAP) and form a highly processive antitermination complex; N bound at NUT also represses N translation. In this study, we investigate whether N and NUT cause N translation repression as part of the antitermination complex by testing conditions that inhibit the formation of the N-modified transcription complex for their effect on N-mediated translation repression. We show that nus and nut mutations that in combination destabilize multiple interactions in the antitermination complex prevent N-mediated translation repression. Likewise, transcription of the nut-N region by T7 RNAP, which does not lead to the assembly of an effective antitermination complex when N is supplied, eliminates translation repression. We also demonstrate that a unique mutant beta subunit of RNAP reduces N-mediated translation repression, and that overexpression of transcription factor NusA suppresses this defect. We conclude that the N-modified RNAP transcription complex is necessary to repress N translation.

Structural basis for the interaction of Escherichia coli NusA with protein N of phage lambda

The C terminus of transcription factor NusA from Escherichia coli comprises two repeat units, which bind during antitermination to protein N from phage lambda. To delineate the structural basis of the NusA-lambdaN interaction, we attempted to crystallize the NusA C-terminal repeats in complex with a lambdaN peptide (residues 34-47). The two NusA domains became proteolytically separated during crystallization, and crystals contained two copies of the first repeat unit in contact with a single lambdaN fragment. The NusA modules employ identical regions to contact the peptide but approach the ligand from opposite sides. In contrast to the alpha-helical conformation of the lambdaN N terminus in complex with boxB RNA, residues 34-40 of lambdaN remain extended upon interaction with NusA. Mutational analyses indicated that only one of the observed NusA-lambdaN interaction modes is biologically significant, supporting an equimolar ratio of NusA and lambdaN in antitermination complexes. Solution studies indicated that additional interactions are fostered by the second NusA repeat unit, consistent with known compensatory mutations in NusA and lambdaN. Contrary to the RNA polymerase alpha subunit, lambdaN binding does not stimulate RNA interaction of NusA. The results demonstrate that lambdaN serves as a scaffold to closely oppose NusA and the mRNA in antitermination complexes.

RapA, a bacterial homolog of SWI2/SNF2, stimulates RNA polymerase recycling in transcription

We report that RapA, an Escherichia coli RNA polymerase (RNAP)-associated homolog of SWI2/SNF2, is capable of dramatic activation of RNA synthesis. The RapA-mediated transcriptional activation in vitro depends on supercoiled DNA and high salt concentrations, a condition that is likely to render the DNA superhelix tightly compacted. Moreover, RapA activates transcription by stimulating RNAP recycling. Mutational analyses indicate that the ATPase activity of RapA is essential for its function as a transcriptional activator, and a rapA null mutant exhibits a growth defect on nutrient plates containing high salt concentrations in vivo. Thus, RapA acts as a general transcription factor and an integral component of the transcription machinery. The mode of action of RapA in remodeling posttranscription or posttermination complexes is discussed.

Growth phase and growth rate regulation of the rapA gene, encoding the RNA polymerase-associated protein RapA in Escherichia coli

The Escherichia coli rapA gene encodes the RNA polymerase (RNAP)-associated protein RapA, which is a bacterial member of the SWI/SNF helicase-like protein family. We have studied the rapA promoter and its regulation in vivo and determined the interaction between RNAP and the promoter in vitro. We have found that the expression of rapA is growth phase dependent, peaking at the early log phase. The growth phase control of rapA is determined at least by one particular feature of the promoter: it uses CTP as the transcription-initiating nucleotide instead of a purine, which is used for most E. coli promoters. We also found that the rapA promoter is subject to growth rate regulation in vivo and that it forms intrinsic unstable initiation complexes with RNAP in vitro. Furthermore, we have shown that a GC-rich or discriminator sequence between the -10 and +1 positions of the rapA promoter is responsible for its growth rate control and the instability of its initiation complexes with RNAP.

Translocation of sigma(70) with RNA polymerase during transcription: fluorescence resonance energy transfer assay for movement relative to DNA

Using fluorescence resonance energy transfer, we show that, in the majority of transcription complexes, sigma(70) is not released from RNA polymerase upon transition from initiation to elongation, but, instead, remains associated with RNA polymerase and translocates with RNA polymerase. The results argue against the presumption that there are necessary subunit-composition differences, and corresponding necessary mechanistic differences, in initiation and elongation. The methods of this report should be generalizable to monitor movement of any molecule relative to any nucleic acid.

Isolation and characterization of sigma(70)-retaining transcription elongation complexes from Escherichia coli

sigma(70) subunit is thought to be released from the core RNA polymerase (RNAP) upon the transition from initiation to elongation or shortly afterward. Here, we identify a population of RNAP from E. coli that retains sigma(70) throughout elongation. The relative amount of this population appears to depend on cellular growth and reaches its maximum during the stationary phase. The proportion of sigma(70)-retaining elongation complexes (EC-sigma(70)) is invariant with various promoters or distances from the transcription start site. EC-sigma(70) responds to pauses, intrinsic terminators, and the elongation factor NusA similarly to EC without sigma(70). However, EC-sigma(70) has a substantially higher ability to support multiple rounds of transcription at certain promoters, suggesting its profound role in gene expression and regulation in bacteria.

Ribosomal protein S4 is a transcription factor with properties remarkably similar to NusA, a protein involved in both non-ribosomal and ribosomal RNA antitermination

Escherichia coli ribosomal RNA (rRNA) operons contain antitermination motifs necessary for forming terminator-resistant transcription complexes. In preliminary work, we isolated 'antiterminating' transcription complexes and identified four new proteins potentially involved in rRNA transcription antitermination: ribosomal (r-) proteins S4, L3, L4 and L13. We show here that these r-proteins and Nus factors lead to an 11-fold increase in terminator read-through in in vitro transcription reactions. A significant portion of the effect was a result of r-protein S4. We show that S4 acted as a general antitermination factor, with properties very similar to NusA. It retarded termination and increased read-through at Rho-dependent terminators, even in the absence of the rRNA antiterminator motif. High concentrations of NusG showed reduced antitermination by S4. Like rrn antitermination, S4 selectively antiterminated at Rho-dependent terminators. Lastly, S4 tightly bound RNA polymerase in vivo. Our results suggest that, like NusA, S4 is a general transcription antitermination factor that associates with RNA polymerase during normal transcription and is also involved in rRNA operon antitermination. A model for key r-proteins playing a regulatory role in rRNA synthesis is presented.

Interactions of an Arg-rich region of transcription elongation protein NusA with NUT RNA: implications for the order of assembly of the lambda N antitermination complex in vivo

The E. coli NusA transcription elongation protein (NusA(Ec)), identified because of its requirement for transcription antitermination by the N protein, has an Arg-rich S1 RNA-binding domain. A complex of N and NusA with other host factors binding at NUT sites in the RNA renders RNA polymerase termination-resistant. An E. coli haploid for nusA944, having nine different codons replacing four normally found in the Arg-rich region, is defective in support of N action. Another variant, haploid for the nusAR199A allele, with a change in a highly conserved Arg codon in the S1 domain, effectively supports N-mediated antitermination. However, nusAR199A is recessive to nusA944, while nusA(Ec) is dominant to nusA944 for support of N-mediated antitermination, suggesting a competition between NusA944 and NusAR199A during complex formation. Complex formation with the variant NusA proteins was assessed by mobility gel shifts. NusAR199A, unlike NusA(Ec) and NusA944, fails to form a complex with N and NUT RNA. However, while NusAR199A, like wild-type NusA, forms an enlarged complex with NUT RNA, N, RNA polymerase, and other host proteins required for efficient N-mediated antitermination, NusA944 does not form this enlarged complex. Consistent with the in vivo results, NusA944 prevents NusAR199A but not NusA(Ec) from forming the enlarged complex. The simplest conclusion from these dominance studies is that in the formation of the complete active antitermination complex in vivo, NusA and N binding to the newly synthesized NUT RNA precedes addition of the other factors. Alternative less effective routes to the active complex that allows bypass of this preferred pathway may also exist.

An extended RNA binding surface through arrayed S1 and KH domains in transcription factor NusA

The crystal structure of Thermotoga maritima NusA, a transcription factor involved in pausing, termination, and antitermination processes, reveals a four-domain, rod-shaped molecule. An N-terminal alpha/beta portion, a five-stranded beta-barrel (S1 domain), and two K-homology (KH) modules create a continuous spine of positive electrostatic potential, suitable for nonspecific mRNA attraction. Homology models suggest how, in addition, specific mRNA regulatory sequences can be recognized by the S1 and KH motifs. An arrangement of multiple S1 and KH domains mediated by highly conserved residues is seen, creating an extended RNA binding surface, a paradigm for other proteins with similar domain arrays. Structural and mutational analyses indicate that the motifs cooperate, modulating strength and specificity of RNA binding.

Proteins shared by the transcription and translation machines

It is becoming increasingly clear that the complex machines involved in transcription and translation, the two major activities leading to gene expression, communicate directly with one another by sharing proteins. For some proteins, such as ribosomal proteins S10 and L4, there is strong evidence of their participation in both processes, and much is known about their role in both activities. The exact roles and interactions of other proteins, such as Nus factors B and G, in both transcription and translation remain a mystery. Although there are not, at present, many examples of such shared proteins, the importance of understanding their behavior and intimate involvement with two major cellular machines is beginning to be appreciated. Studies related to the dual activities of these proteins and searches for more examples of proteins shared between the transcription and translation machines should lead to a better understanding of the communication between these two activities and the purposes it serves.

The alpha subunit of E. coli RNA polymerase activates RNA binding by NusA

The Escherichia coli NusA protein modulates pausing, termination, and antitermination by associating with the transcribing RNA polymerase core enzyme. NusA can be covalently cross-linked to nascent RNA within a transcription complex, but does not bind RNA on its own. We have found that deletion of the 79 carboxy-terminal amino acids of the 495-amino-acid NusA protein allows NusA to bind RNA in gel mobility shift assays. The carboxy-terminal domain (CTD) of the alpha subunit of RNA polymerase, as well as the bacteriophage lambda N gene antiterminator protein, bind to carboxy-terminal regions of NusA and enable full-length NusA to bind RNA. Binding of NusA to RNA in the presence of alpha or N involves an amino-terminal S1 homology region that is otherwise inactive in full-length NusA. The interaction of the alpha-CTD with full-length NusA stimulates termination. N may prevent termination by inducing NusA to interact with N utilization (nut) site RNA rather than RNA near the 3' end of the nascent transcript. Sequence analysis showed that the alpha-CTD contains a modified helix-hairpin-helix motif (HhH), which is also conserved in the carboxy-terminal regions of some eubacterial NusA proteins. These HhH motifs may mediate protein-protein interactions in NusA and the alpha-CTD.

Interaction between RNA polymerase and RapA, a bacterial homolog of the SWI/SNF protein family

Recently, we identified a novel Escherichia coli RNA polymerase (RNAP)-associated protein, an ATPase, called RapA (Sukhodolets, M. V. , and Jin, D. J. (1998) J. Biol. Chem. 273, 7018-7023). RapA is a bacterial homolog of SWI2/SNF2. We showed that RapA forms a stable complex with RNAP holoenzyme and that binding to RNAP holoenzyme stimulates the ATPase activity of RapA. We have further analyzed the interactions between purified RapA and the two forms of RNAP: core RNAP and RNAP holoenzyme. We found that RapA interacts with either form of RNAP. However, RapA exhibits higher affinity for core RNAP than for RNAP holoenzyme. Chemical cross-linking of the RNAP-RapA complex indicated that the RapA-binding sites are located at the interface between the alpha and beta' subunits of RNAP. Contrary to previously reported results (Muzzin, O., Campbell, E., A., Xia, L., Severinova, E., Darst, S. A., and Severinov, K. (1998) J. Biol. Chem. 273, 15157-15161), our in vivo analysis of a rapA null mutant suggested that RapA is not likely to be directly involved in DNA repair.

Functional importance of regions in Escherichia coli elongation factor NusA that interact with RNA polymerase, the bacteriophage lambda N protein and RNA

The association of the essential Escherichia coli protein NusA with RNA polymerase increases pausing and the efficiency of termination at intrinsic terminators. NusA is also part of the phage lambda N protein-modified antitermination complex that functions to prevent transcriptional termination. We have investigated the structure of NusA using various deletion fragments of NusA in a variety of in vitro assays. Sequence and structural alignments have suggested that NusA has both S1 and KH homology regions that are thought to bind RNA. We show here that the portion of NusA containing the S1 and KH homology regions is important for NusA to enhance both termination and antitermination. There are two RNA polymerase-binding regions in NusA, one in the amino-terminal 137 amino acids and the other in the carboxy-terminal 264 amino acids; only the amino-terminal RNA polymerase-binding region provides a functional contact that enhances termination at an intrinsic terminator or antitermination by N. The carboxy-terminal region of NusA is also required for interaction with N and is important for the formation of an N-NusA-nut site or N-NusA-RNA polymerase-nut site complex; the instability of complexes lacking this carboxy-terminal region of NusA that binds N and RNA polymerase can be compensated for by the presence of the additional E. coli elongation factors, NusB, NusG and ribosomal protein S10.

Interactions of Escherichia coli sigma(70) within the transcription elongation complex

A functional transcription elongation complex can be formed without passing through a promoter by adding a complementary RNA primer and core Escherichia coli RNA polymerase in trans to an RNA-primed synthetic bubble-duplex DNA framework. This framework consists of a double-stranded DNA sequence with an internal noncomplementary DNA "bubble" containing a hybridized RNA primer. On addition of core polymerase and the requisite NTPs, the RNA primer is extended in a process that manifests most of the properties of in vitro transcription elongation. This synthetic elongation complex can also be assembled by using holo rather than core RNA polymerase, and in this study we examine the interactions and fate of the sigma(70) specificity subunit of the holopolymerase in the assembly process. We show that the addition of holopolymerase to the bubble-duplex construct triggers the dissociation of the sigma factor from some complexes, whereas in others the RNA oligomer is released into solution instead. These results are consistent with an allosteric competition between sigma(70) and the nascent RNA strand within the elongation complex and suggest that both cannot be bound to the core polymerase simultaneously. However, the dissociation of sigma(70) from the complex can also be stimulated by binding of the holopolymerase to the DNA bubble duplex in the absence of a hybridized RNA primer, suggesting that the binding of the core polymerase to the bubble-duplex construct also triggers a conformational change that additionally weakens the sigma-core interaction.

Mechanism of action of RNA polymerase II elongation factor Elongin. Maximal stimulation of elongation requires conversion of the early elongation complex to an Elongin-activable form

We previously identified and purified Elongin by its ability to stimulate the rate of elongation by RNA polymerase II in vitro (Bradsher, J. N., Jackson, K. W., Conaway, R. C., and Conaway, J. W. (1993) J. Biol. Chem. 268, 25587-25593). In this report, we present evidence that stimulation of elongation by Elongin requires that the early RNA polymerase II elongation complex undergoes conversion to an Elongin-activable form. We observe (i) that Elongin does not detectably stimulate the rate of promoter-specific transcription initiation by the fully assembled preinitiation complex and (ii) that early RNA polymerase II elongation intermediates first become susceptible to stimulation by Elongin after synthesizing 8-9-nucleotide-long transcripts. Furthermore, we show that the relative inability of Elongin to stimulate elongation by early elongation intermediates correlates not with the lengths of their associated transcripts but, instead, with the presence of transcription factor IIF (TFIIF) in transcription reactions. By exploiting adenovirus 2 major late promoter derivatives that contain premelted transcriptional start sites and do not require TFIIF, TFIIE, or TFIIH for transcription initiation, we observe (i) that Elongin is capable of strongly stimulating the rate of synthesis of trinucleotide transcripts by a subcomplex of RNA polymerase II, TBP, and TFIIB and (ii) that the ability of Elongin to stimulate synthesis of these short transcripts is substantially reduced by addition of TFIIF to transcription reactions. Here we present these findings, which are consistent with the model that maximal stimulation of elongation by Elongin requires that early elongation intermediates undergo a structural transition that includes loss of TFIIF.

Nascent RNA in transcription complexes interacts with CspE, a small protein in E. coli implicated in chromatin condensation

Proteins in a partially fractionated Escherichia coli extract that interact with the nascent RNA in active transcription complexes from several promoters were detected using the photocrosslinking ribonucleotide analogs 5-(azidophenacyl)thio-UTP or 5-(azidophenacyl)thio-CTP as transcription substrates. Upon irradiation of ternary transcription complexes, several extract proteins were crosslinked to the RNA. Most notably, a small protein was crosslinked to the RNA in complexes on seven of nine templates tested. This protein was purified and sequenced and found to match a hypothetical protein, MsmC/CspE, recently shown to be involved in chromatin partitioning. CspE has 69% amino acid sequence identity with the major cold shock protein in E. coli, CspA, which has been shown to bind to a DNA sequence designated the Y box, with the sequence 5'-ATTGG. Of the nine templates tested, CspE was found to be most heavily crosslinked to RNA from the lambda PR' promoter, which is modified by the Q antiterminator protein. CspE was very heavily crosslinked to RNA only ten nucleotides long in initial ternary complexes on this promoter, but not to this same RNA after it had been released from the transcription complex. However, even when present from the start of transcription, CspE did not crosslink to the RNA 82 nucleotides long in elongation complexes from this same promoter. Despite the loss of interaction with the RNA after polymerase had left the promoter, CspE inhibited Q-mediated transcriptional antitermination from PR' in vitro almost 200 nucleotides downstream from the promoter, presumably by interaction with the Y box DNA upstream from PR', which overlaps with the binding site for the Q. A potential role for CspE and transcription in chromosome condensation and nucleoid structure is discussed.

An integrated model of the transcription complex in elongation, termination, and editing

Recent findings now allow the development of an integrated model of the thermodynamic, kinetic, and structural properties of the transcription complex in the elongation, termination, and editing phases of transcript formation. This model provides an operational framework for placing known facts and can be extended and modified to incorporate new advances. The most complete information about transcriptional mechanisms and their control continues to come from the Escherichia coli system, upon which most of the explicit descriptions provided here are based. The transcriptional machinery of higher organisms, despite its greater inherent complexity, appears to use many of the same general principles. Thus, the lessons of E. coli continue to be relevant.

Combinatorial effects of NusA and NusG on transcription elongation and Rho-dependent termination in Escherichia coli

The transcription factors NusA and NusG from Escherichia coli are modulators of the RNA polymerase elongation reaction and Rho-dependent transcription termination. NusA decreases the elongation rate and termination efficiency while NusG increases both activities. Both Nus factors are able to physically interact with Rho and with RNA polymerase. Experiments with purified components designed to determine whether these factors act independently or competitively showed that the change in elongation rate was a composite of their individual effects, that the combined effect on termination was dependent on the reaction conditions and that the two factors do not compete for their sites of action for either effect. The two factors were also found not to enhance significantly the slight (20%) inhibition of elongation caused by 200 microM guanosine 3',5'-bisdiphosphate (ppGpp) during transcription in vitro. The results also show that the effects of NusA and NusG on RNA polymerase elongation and Rho function are contrary to the inverse relationship between elongation and termination that is expected for a kinetic coupling of Rho action to RNA polymerase elongation. This property suggests that in addition to their known actions on RNA polymerase that influence the length of pausing, these factors act on some other rate-limiting step of the Rho-dependent termination process.

NMR structure of the bacteriophage lambda N peptide/boxB RNA complex: recognition of a GNRA fold by an arginine-rich motif

The structure of the complex formed by the arginine-rich motif of the transcriptional antitermination protein N of phage lambda and boxB RNA was determined by heteronuclear magnetic resonance spectroscopy. A bent alpha helix in N recognizes primarily the shape and negatively charged surface of the boxB hairpin through multiple hydrophobic and ionic interactions. The GAAGA boxB loop forms a GNRA fold, previously described for tetraloops, which is essential for N binding. The fourth nucleotide of the loop extrudes from the GNRA fold to enable the E. coli elongation factor NusA to recognize the N protein/RNA complex. This structure reveals a new mode of RNA-protein recognition and shows how a small RNA element can facilitate a protein-protein interaction and thereby nucleate formation of a large ribonucleoprotein complex.

RapA, a novel RNA polymerase-associated protein, is a bacterial homolog of SWI2/SNF2

We have identified a novel Escherichia coli RNA polymerase (RNAP)-associated protein, an ATPase named RapA. Almost all of this 110-kDa protein in the cell copurifies with RNAP holoenzyme as a 1:1 complex. Purified to homogeneity, RapA also forms a stable complex with RNAP, as if it were a subunit of RNAP. The ATPase activity of RapA is stimulated by binding to RNAP, and thus, RapA and RNAP interact physically as well as functionally. Interestingly, RapA is a homolog of the SWI/SNF family of eukaryotic proteins whose members are involved in transcription activation, nucleosome remodeling, and DNA repair.

Involvement of boxA nucleotides in the formation of a stable ribonucleoprotein complex containing the bacteriophage lambda N protein

The association of the transcriptional antitermination protein N of bacteriophage lambda with Escherichia coli RNA polymerase depends on nut site RNA (boxA + boxB) in the nascent transcript and the host protein, NusA. This ribonucleoprotein complex can transcribe through Rho-dependent and intrinsic termination sites located up to several hundred base pairs downstream of nut. For antitermination to occur farther downstream, this core antitermination complex must be stabilized by the host proteins NusB, NusG, and ribosomal protein S10. Here, we show that the assembly of NusB, NusG, and S10 onto the core complex involves nucleotides 2-7 of lambda boxA (CGCUCUUACACA) and is a fully cooperative process that depends on the presence of all three proteins. This assembly of NusB, NusG, and S10 also requires the carboxyl-terminal region (amino acids 73-107) of N, which interacts directly with RNA polymerase. NusB and S10 assemble in the absence of NusG when lambda boxA is altered at nucleotides 8 and 9 to create a consensus version of boxA (CGCUCUUUAACA). These experiments suggest that multiple protein-protein and protein-RNA interactions are required to convert a core antitermination complex into a complete complex.