Overexpression of N antitermination proteins of bacteriophages lambda, 21, and P22: loss of N protein specificity

Artificial RNA Editing with ADAR for Gene Therapy

Editing mutated genes is a potential way for the treatment of genetic diseases. G-to-A mutations are common in mammals and can be treated by adenosine-to-inosine (A-to-I) editing, a type of substitutional RNA editing. The molecular mechanism of A-to-I editing involves the hydrolytic deamination of adenosine to an inosine base; this reaction is mediated by RNA-specific deaminases, adenosine deaminases acting on RNA (ADARs), family protein. Here, we review recent findings regarding the application of ADARs to restoring the genetic code along with different approaches involved in the process of artificial RNA editing by ADAR. We have also addressed comparative studies of various isoforms of ADARs. Therefore, we will try to provide a detailed overview of the artificial RNA editing and the role of ADAR with a focus on the enzymatic site directed A-to-I editing.

Non-programmed transcriptional frameshifting is common and highly RNA polymerase type-dependent

Background

The viral or host systems for a gene expression assume repeatability of the process and high quality of the protein product. Since level and fidelity of transcription primarily determines the overall efficiency, all factors contributing to their decrease should be identified and optimized. Among many observed processes, non-programmed insertion/deletion (indel) of nucleotide during transcription (slippage) occurring at homopolymeric A/T sequences within a gene can considerably impact its expression. To date, no comparative study of the most utilized Escherichia coli and T7 bacteriophage RNA polymerases (RNAP) propensity for this type of erroneous mRNA synthesis has been reported. To address this issue we evaluated the influence of shift-prone A/T sequences by assessing indel-dependent phenotypic changes. RNAP-specific expression profile was examined using two of the most potent promoters, P_araBAD of E. coli and φ10 of phage T7.

Results

Here we report on the first systematic study on requirements for efficient transcriptional slippage by T7 phage and cellular RNAPs considering three parameters: homopolymer length, template type, and frameshift directionality preferences. Using a series of out-of-frame gfp reporter genes fused to a variety of A/T homopolymeric sequences we show that T7 RNAP has an exceptional potential for generating frameshifts and is capable of slipping on as few as three adenine or four thymidine residues in a row, in a flanking sequence-dependent manner. In contrast, bacterial RNAP exhibits a relatively low ability to baypass indel mutations and requires a run of at least 7 tymidine and even more adenine residues. This difference comes from involvement of various intrinsic proofreading properties. Our studies demonstrate distinct preference towards a specific homopolymer in slippage induction. Whereas insertion slippage performed by T7 RNAP (but not deletion) occurs tendentiously on poly(A) rather than on poly(T) runs, strong bias towards poly(T) for the host RNAP is observed.

Conclusions

Intrinsic RNAP slippage properties involve trade-offs between accuracy, speed and processivity of transcription. Viral T7 RNAP manifests far greater inclinations to the transcriptional slippage than E. coli RNAP. This possibly plays an important role in driving bacteriophage adaptation and therefore could be considered as beneficial. However, from biotechnological and experimental viewpoint, this might create some problems, and strongly argues for employing bacterial expression systems, stocked with proofreading mechanisms.

Electronic supplementary material

The online version of this article (10.1186/s12934-018-1034-4) contains supplementary material, which is available to authorized users.

Diverse mutants of HIV RRE IIB recognize wild-type Rev ARM or Rev ARM R35G-N40V

The binding of human immunodeficiency virus Rev protein via its arginine-rich motif (ARM) to an internal loop in the Rev-response element region IIB (RRE IIB) is necessary for viral replication. Many variant RNAs and ARMs that bind Rev and RRE IIB have been found. Despite the essential role of Rev asparagine 40 in recognition, the Rev ARM double-mutant R35G-N40V functions well in a Rev-RRE IIB reporter assay, indicating R35G-N40V uses a distinct recognition strategy. To examine how RRE IIB may evolve specificity to wild-type Rev ARM and R35G-N40V, 10 RRE IIB libraries, each completely randomized in overlapping regions, were screened with wild-type Rev ARM and R35G-N40V using a reporter system based on bacteriophage λ N antitermination. Consistent with previous studies, a core element of RRE IIB did not vary, and substitutions occurred at conserved residues only in the presence of other substitutions. Notably, the groove-widening, non-canonical base-pair G48:G71 was mutable to U48:G71 without strong loss of binding to wild-type Rev ARM, suggesting U48:G71 performs the same role by adopting the nearly isosteric, reverse wobble base pair. Originating from RRE IIB, as few as one or two substitutions are sufficient to confer specificity to wild-type Rev or Rev R35G-N40. The diversity of RRE IIB mutants that maintain binding to wild-type Rev ARM and R35G-N40V supports neutral theories of evolution and illustrates paths by which viral RNA-protein interactions can evolve new specificities. Rev-RRE offers an excellent model with which to study the fine structure of how specificity evolves.

Bacterial 'immunity' against bacteriophages

Vertebrate animals possess multiple anti-pathogen defenses. Individual mechanisms usually are differentiated into those that are immunologically adaptive vs. more “primitive” anti-pathogen phenomena described as innate responses. Here I frame defenses used by bacteria against bacteriophages as analogous to these animal immune functions. Included are numerous anti-phage defenses in addition to the adaptive immunity associated with CRISPR/cas systems. As these other anti-pathogen mechanisms are non-adaptive they can be described as making up an innate bacterial immunity. This exercise was undertaken in light of the recent excitement over the discovery that CRISPR/cas systems can serve, as noted, as a form of bacterial adaptive immunity. The broader goal, however, is to gain novel insight into bacterial defenses against phages by fitting these mechanisms into considerations of how multicellular organisms also defend themselves against pathogens. This commentary can be viewed in addition as a bid toward integrating these numerous bacterial anti-phage defenses into a more unified immunology.

Randomized codon mutagenesis reveals that the HIV Rev arginine-rich motif is robust to substitutions and that double substitution of two critical residues alters specificity

The binding of the arginine-rich motif (ARM) of HIV Rev protein to its high-affinity site in stem IIB in the Rev response element (RRE) initiates assembly of a ribonucleoprotein complex that mediates the export of essential, incompletely spliced viral transcripts. Many biochemical, genetic, and structural studies of Rev-RRE IIB have been published, yet the roles of many peptide residues in Rev ARM are unconfirmed by mutagenesis. Rev aptamer I (RAI) is an optimized RRE IIB that binds Rev with higher affinity and for which mutational data are sparse. Randomized-codon libraries of Rev ARM were assayed for their ability to bind RRE IIB and RAI using a bacterial reporter system based on bacteriophage λ N-nut antitermination. Most Rev ARM residues tolerated substitutions without strong loss of binding to RRE IIB, and all except arginine 39 tolerated substitution without strong loss of binding to RAI. The pattern of critical Rev residues is not the same for RRE IIB and RAI, suggesting important differences between the interactions. The results support and aid the interpretation of existing structural models. Observed clinical variation is consistent with additional constraints on Rev mutation. By chance, we found double mutants of two highly critical residues, arginine 35 (to glycine) and asparagine 40 (to valine or lysine), that bind RRE IIB well, but not RAI. That an apparently distinct binding mode occurs with only two mutations highlights the ability of ARMs to evolve new recognition strategies and supports the application of neutral theories of evolution to protein-RNA recognition.

The RNA-binding domain of bacteriophage P22 N protein is highly mutable, and a single mutation relaxes specificity toward lambda

Antitermination in bacteriophage P22, a lambdoid phage, uses the arginine-rich domain of the N protein to recognize boxB RNAs in the nut site of two regulated transcripts. Using an antitermination reporter system, we screened libraries in which each nonconserved residue in the RNA-binding domain of P22 N was randomized. Mutants were assayed for the ability to complement N-deficient virus and for antitermination with P22 boxB(left) and boxB(right) reporters. Single amino acid substitutions complementing P22 N(-) virus were found at 12 of the 13 positions examined. We found evidence for defined structural roles for seven nonconserved residues, which was generally compatible with the nuclear magnetic resonance model. Interestingly, a histidine can be replaced by any other aromatic residue, although no planar partner is obvious. Few single substitutions showed bias between boxB(left) and boxB(right), suggesting that the two RNAs impose similar constraints on genetic drift. A separate library comprising only hybrids of the RNA-binding domains of P22, lambda, and phi21 N proteins produced mutants that displayed bias. P22 N(-) plaque size plotted against boxB(left) and boxB(right) reporter activities suggests that lytic viral fitness depends on balanced antitermination. A few N proteins were able to complement both lambda N- and P22 N-deficient viruses, but no proteins were found to complement both P22 N- and phi21 N-deficient viruses. A single tryptophan substitution allowed P22 N to complement both P22 and lambda N(-). The existence of relaxed-specificity mutants suggests that conformational plasticity provides evolutionary transitions between distinct modes of RNA-protein recognition.

Bacteriophage P22 antitermination boxB sequence requirements are complex and overlap with those of lambda

Transcription antitermination in phages lambda and P22 uses N proteins that bind to similar boxB RNA hairpins in regulated transcripts. In contrast to the lambda N-boxB interaction, the P22 N-boxB interaction has not been extensively studied. A nuclear magnetic resonance structure of the P22 N peptide boxB(left) complex and limited mutagenesis have been reported but do not reveal a consensus sequence for boxB. We have used a plasmid-based antitermination system to screen boxBs with random loops and to test boxB mutants. We find that P22 N requires boxB to have a GNRA-like loop with no simple requirements on the remaining sequences in the loop or stem. U:A or A:U base pairs are strongly preferred adjacent to the loop and appear to modulate N binding in cooperation with the loop and distal stem. A few GNRA-like hexaloops have moderate activity. Some boxB mutants bind P22 and lambda N, indicating that the requirements imposed on boxB by P22 N overlap those imposed by lambda N. Point mutations can dramatically alter boxB specificity between P22 and lambda N. A boxB specific for P22 N can be mutated to lambda N specificity by a series of single mutations via a bifunctional intermediate, as predicted by neutral theories of evolution.

Molecular genetics of bacteriophage P22 scaffolding protein's functional domains

The assembly intermediates of the Salmonella bacteriophage P22 are well defined but the molecular interactions between the subunits that participate in its assembly are not. The first stable intermediate in the assembly of the P22 virion is the procapsid, a preformed protein shell into which the viral genome is packaged. The procapsid consists of an icosahedrally symmetric shell of 415 molecules of coat protein, a dodecameric ring of portal protein at one of the icosahedral vertices through which the DNA enters, and approximately 250 molecules of scaffolding protein in the interior. Scaffolding protein is required for assembly of the procapsid but is not present in the mature virion. In order to define regions of scaffolding protein that contribute to the different aspects of its function, truncation mutants of the scaffolding protein were expressed during infection with scaffolding deficient phage P22, and the products of assembly were analyzed. Scaffolding protein amino acids 1-20 are not essential, since a mutant missing them is able to fully complement scaffolding deficient phage. Mutants lacking 57 N-terminal amino acids support the assembly of DNA containing virion-like particles; however, these particles have at least three differences from wild-type virions: (i) a less than normal complement of the gene 16 protein, which is required for DNA injection from the virion, (ii) a fraction of the truncated scaffolding protein was retained within the virions, and (iii) the encapsidated DNA molecule is shorter than the wild-type genome. Procapsids assembled in the presence of a scaffolding protein mutant consisting of only the C-terminal 75 amino acids contained the portal protein, but procapsids assembled with the C-terminal 66 did not, suggesting portal recruitment function for the region about 75 amino acids from the C terminus. Finally, scaffolding protein amino acids 280 through 294 constitute its minimal coat protein binding site.

A quantitative description of the binding states and in vitro function of antitermination protein N of bacteriophage lambda

The N protein of bacteriophage lambda activates transcription of genes that lie downstream of termination sequences by suppressing transcription termination. N binds to specific (boxB) and non-specific sites on the transcript RNA and contacts RNA polymerase via cis-RNA looping, resulting in "antitermination" of transcription. To find the effect of N-boxB binding on antitermination, we quantitatively relate binding measurements made in isolation to in vitro antitermination activity. We measure binding of N to boxB RNA, non-specific single-stranded RNA, and non-specific double-stranded DNA fluorimetrically, and use an equilibrium model to describe quantitatively the binding of N to nucleic acids of Escherichia coli transcription elongation complexes. We then test the model by comparison with in vitro N antitermination activity measured in reactions containing these same elongation complexes. We find that binding of N protein to the nucleic acid components of transcription elongation complexes can quantitatively predict antitermination activity, suggesting that antitermination in vitro is determined by a nucleic acid binding equilibrium with one molecule of N protein per RNA transcript being sufficient for antitermination. Elongation complexes contain numerous overlapping non-specific RNA and DNA-binding sites for N; the large number of sites compensates for the low N binding affinity, so multiple N proteins are expected to bind to elongation complexes. The occupancy/activity of these proteins is described by a binomial distribution of proteins on transcripts containing multiple non-specific sites. The contribution of specific (boxB) binding to activity also depends on this distribution. Specificity is not measured accurately by measurements made in the presence and in the absence of boxB. We find that antitermination is inhibited by non-productive binding of N to non-specific sites on template DNA, and that NusA protein covers RNA sites on the transcript, limiting N access and activity. The activity and specificity of regulatory proteins that loop from high-affinity binding sites are likely modulated by multiple non-specific binding events; in vivo activity may also be regulated by the modulation of non-specific binding.

Morphing molecular specificities between Arm-peptide and NUT-RNA in the antitermination complexes of bacteriophages lambda and P22

Bacteriophage lambda's N-protein includes a 17-amino-acid segment, Arm, rich in arginine and having specific affinity for a 15-nucleotide RNA stem-loop called BOX-B. Parallel but different Arm/BOX-B sequences in lambda's cousin, phage P22, account for some of the type specificity that distinguishes lambda from P22: the N of each works only with its cognate BOX-B in vivo. We find that the specificity of N(lambda) can be shifted gradually to that of N(22) by substituting sets of particular amino acids from Arm(22) into Arm of N(lambda). The determinative amino acids are generally those shown by nuclear magnetic resonance to contact BOX-B RNA; gain or loss of these contact amino acids is reasonably expected to contribute to the affinity of each amino acid sequence. Intermediate sequences may show no function with either BOX-B, or weak function with both BOX-B(lambda) and BOX-B(22), the latter suggesting possible evolutionary paths for specificity shifts.

Evidence that the KH RNA-binding domains influence the action of the E. coli NusA protein

The NusA transcription elongation protein, which binds RNA, contains sequences corresponding to the S1 and KH classes of identified RNA binding domains. An essential function in E. coli, NusA is also one of the host factors required for action of the N transcription antitermination protein of lambda. Tandem KH domains have been identified downstream of the S1 domain. We changed the first Gly to Asp of the GXXG motif, a tetrapeptide diagnostic of KH domains, of both NusA KH domains. The change in the first, G253D, has a large effect, while the change in the second, G319D, has a small effect on NusA action. The changes in both KH domains interfere with NusA binding to RNA. A change of a highly conserved Arg in the S1 domain, R199A, has previously been reported to interfere with RNA binding while exerting a small effect on NusA action. However, a nusA allele with both the R199A and G319D changes encodes a functionally inactive NusA protein. These studies provide direct evidence that the both KH as well as the S1 RNA binding domains are important for NusA action in support of bacterial viability as well as transcription antitermination mediated by the lambda N protein.

RNA-mediated signaling in transcription

Structures of phage transcriptional antitermination complexes define novel motifs for recognition of RNA hairpins by arginine-rich peptides. A bent alpha-helix in each case follows the contour of an induced GNRA-like fold. A phage-specific pattern of base pairing, base stacking and base flipping underlies biological specificity and permits engagement with RNA polymerase. The structures suggest a mechanism of RNA-mediated signaling in transcriptional regulation.

Independent ligand-induced folding of the RNA-binding domain and two functionally distinct antitermination regions in the phage lambda N protein

The transcriptional antitermination protein N of bacteriophage lambda binds the boxB component of the RNA enhancer nut (boxA + boxB) and the E. coli elongation factor NusA. Efficient antitermination by N requires an RNA-binding domain (amino acids 1-22) and two activating regions for antitermination: a newly identified NusA-binding region (amino acids 34-47) that suppresses NusA's enhancement of termination, and a carboxy-terminal region (amino acids 73-107) that interacts directly with RNA polymerase. Heteronuclear magnetic resonance experiments demonstrate that N is a disordered protein. Interaction with boxB RNA induces only the RNA-binding domain of N to adopt a folded conformation, while the activating regions of the protein remain disordered in the absence of their target proteins.

Regulation of the elongation-termination decision at intrinsic terminators by antitermination protein N of phage lambda

The mechanisms that control N-protein-dependent antitermination in the phage lambda life cycle have counterparts in the regulatory systems of other organisms. Here we examine N-dependent antitermination at the intrinsic tR' terminator of lambda to elucidate the regulatory principles involved. The tR' terminator consists of a sequence of six base-pairs along the template at which the transcription complex is sufficiently destabilized to make RNA release possible. Within this "zone of opportunity" for termination the termination efficiency (TE) at each template position is determined by a kinetic competition between alternative reaction pathways that lead either to elongation or to termination. TE values at each position within tR' have been mapped as a function of NTP concentration, and it is shown that N protein (in the presence of NusA and a nut site; the minimal system for N-dependent antitermination) can offset increases in TE that are induced by limiting the concentrations of each of the next required NTPs. By limiting NTP concentrations or working at low temperature we show that a significant effect of N within the minimal system is to increase the rate of transcript elongation three- to fivefold at most positions along the template. Assuming that a comparable increase in elongation rate applies at template positions within the terminator, we show that an increase of this magnitude is not sufficient to account for the antitermination efficiency observed and that an approximately 100-fold stabilization of the transcription complex at intrinsic termination sites as a consequence of binding the N-containing antitermination sub-assembly must be invoked as well. A general method for partitioning TE effects in antitermination between changes in elongation rate and termination complex stability is demonstrated, based on competing free energy of activation barriers for the elongation and termination reactions. The analysis and utility of such mixed modes of transcriptional regulation are considered in general terms.

Molding a peptide into an RNA site by in vivo peptide evolution

Short peptides corresponding to the arginine-rich domains of several RNA-binding proteins are able to bind to their specific RNA sites with high affinities and specificities. In the case of the HIV-1 Rev-Rev response element (RRE) complex, the peptide forms a single alpha-helix that binds deeply in a widened, distorted RNA major groove and makes a substantial set of base-specific and backbone contacts. Using a reporter system based on antitermination by the bacteriophage lambda N protein, it has been possible to identify novel arginine-rich peptides from combinatorial libraries that recognize the RRE with affinities and specificities similar to Rev but that appear to bind in nonhelical conformations. Here we have used codon-based mutagenesis to evolve one of these peptides, RSG-1, into an even tighter binder. After two rounds of evolution, RSG-1.2 bound the RRE with 7-fold higher affinity and 15-fold higher specificity than the wild-type Rev peptide, and in vitro competition experiments show that RSG-1.2 completely displaces the intact Rev protein from the RRE at low peptide concentrations. By fusing RRE-binding peptides to the activation domain of HIV-1 Tat, we show that the peptides can deliver Tat to the RRE site and activate transcription in mammalian cells, and more importantly, that the fusion proteins can inhibit the activity of Rev in chloramphenicol acetyltransferase reporter assays. The evolved peptides contain proline and glutamic acid mutations near the middle of their sequences and, despite the presence of a proline, show partial alpha-helix formation in the absence of RNA. These directed evolution experiments illustrate how readily complex peptide structures can be evolved within the context of an RNA framework, perhaps reflecting how early protein structures evolved in an "RNA world."

Complexes of N antitermination protein of phage lambda with specific and nonspecific RNA target sites on the nascent transcript

The mechanisms that control N protein dependent antitermination in phage lambda have counterparts in many eukaryotic systems, including specific regulatory interactions of the antitermination protein with the nascent RNA transcript. Here we describe the specific and nonspecific RNA binding modes of antitermination protein N. These modes differ markedly in RNA binding affinity and in structure. N protein, either free in solution or as a complex with nonspecific RNA, lacks observable secondary and tertiary structure and binds RNA sequences indiscriminately with a dissociation constant (Kd) of approximately 10(-6) M. In contrast N becomes partially folded with at least 16-18 amino acids of ordered alpha-helical structure and binds much more tightly (Kd approximately 10(-9) M) on forming a highly specific 1:1 complex with its cognate boxB RNA hairpin. These observations and others are used to help define a bipartite model of N-dependent antitermination in which these specific and nonspecific interactions control the binding of N to the nascent transcript. Finally the role of RNA looping in delivering the bound N to the transcription complex and determining the stability (and thus the terminator specificity) of the resulting antitermination interaction of N with the RNA polymerase is considered in quantitative terms.

Analysis of bacteriophage N protein and peptide binding to boxB RNA using polyacrylamide gel coelectrophoresis (PACE)

The antitermination protein N from bacteriophage lambda (Nlambda) interacts with the nut site in its own mRNA, as well as host factors, to facilitate formation of a termination-resistant transcription complex. The conserved, amino-terminal arginine-rich domain of Nlambda protein is known to interact with a small RNA hairpin (boxB) derived from the nut site RNA. We have examined the binding of Nlambda protein, peptides derived from the amino terminus of Nlambda, and the related phage P22 N protein to lambda boxB RNAs. To facilitate the study of complexes that are not amenable to gel retardation assays, a new polyacrylamide affinity coelectrophoresis technique (PACE) was developed. Using the PACE assay, we have demonstrated that a 19-amino acid peptide from the amino terminus of Nlambda protein binds lambda boxB RNA with a Kd,app of 5.2 nM. PACE was also used to study the binding affinity of a number of Nlambda peptide and lambda boxB RNA mutants. The PACE technique is complementary to the traditional gel retardation assay for direct measurement of binding interactions, and will be useful for any procedure that requires a pool of RNAs to be resolved based on their relative affinities for proteins or peptides.

Selection of RNA-binding peptides in vivo

Many priniciples of sequence-specific DNA recognition have been established over the past decade, largely from structural studies of protein-DNA and drug-DNA complexes. On the basis of these principles, it has been possible to design or select variants of known structural motifs, including zinc-fingers and minor groove-binding drugs, that bind desired sequences. Here we describe a strategy, based on transcriptional termination in bacteria, to identify specific RNA-binding peptides using the arginine-rich RNA-binding motif as a framework. Peptides were isolated from two combinatorial libraries that bind tightly and specifically to the Rev response element of HIV. It appears that alpha-helical peptides resembling Rev were selected from one library whereas new peptides that probably do not form helices were selected from the other, suggesting that the arginine-rich motif may be a particularly versatile framework for recognizing RNA structures.

Bacteriophage lambda N protein alone can induce transcription antitermination in vitro

Specific and processive antitermination by bacteriophage lambda N protein in vivo and in vitro requires the participation of a large number of Escherichia coli proteins (Nus factors), as well as an RNA hairpin (boxB) within the nut site of the nascent transcript. In this study we show that efficient, though nonprocessive, antitermination can be induced by large concentrations of N alone, even in the absence of a nut site. By adding back individual components of the system, we also show that N with nut+ nascent RNA is much more effective in antitermination than is N alone. This effect is abolished if N is competed away from the nut+ RNA by adding, in trans, an excess of boxB RNA. The addition of NusA makes antitermination by the N-nut+ complex yet more effective. This NusA-dependent increase in antitermination is lost when delta nut transcripts are used. These results suggest the formation of a specific boxB RNA-N-NusA complex within the transcription complex. By assuming an equilibrium model, we estimate a binding constant of 5 x 10(6) M-1 for the interaction of N alone with the transcription complex. This value can be used to estimate a characteristic dissociation time of N from the complex that is comparable to the dwell time of the complex at an average template position, thus explaining the nonprocessivity of the antitermination effect induced by N alone. On this basis, the effective dissociation rate of N should be approximately 1000-fold slower from the minimally processive (100-600 bp) N-NusA-nut+ transcription complex and approximately 10(5)-fold slower from the maximally processive (thousands of base pairs) complex containing all of the components of the in vivo N-dependent antitermination system.

The carboxy-terminal 14 amino acids of phage lambda N protein are dispensable for transcription antitermination

The analogous N proteins encoded by lambdoid bacteriophages lambda, 21, and 22 are very different in amino acid sequence, except at their carboxy-terminal ends. Since N lambda remains functional despite the deletion of most of its terminal region of homology to N21, that region of homology cannot represent a region of conserved function.

Mutations of the phage lambda nutL region that prevent the action of Nun, a site-specific transcription termination factor

Phage HK022 encodes a protein, Nun, that promotes transcription termination within the pL and pR operons of its relative, phage lambda. The lambda sequences required for termination had previously been shown to overlap the nut sites, which are essential for transcription antitermination during normal lambda growth. To further specify the Nun target and to determine its relation to the nut sites, we constructed deletion and base substitution mutations of the lambda nutL region and measured Nun-dependent reduction of the expression of a downstream reporter gene. The shortest construct that retained full Nun responsiveness was a 42-bp segment that included both boxA and boxB, sequences that have been implicated in lambda antitermination. Deletion of boxA reduced Nun termination, and deletion of both sequences eliminated Nun termination. Base substitutions in boxA and the proximal portion of boxB impaired Nun termination, while base substitutions between boxA and boxB, in the distal portion of boxB, and immediately downstream from boxB had no appreciable effect. The termination defect of all of the base substitution mutations was relieved by increasing the level of Nun protein; in contrast, the deletions and a multiple-base substitution did not regain full Nun responsiveness at elevated Nun concentrations. We also asked if these mutant nut regions retained their ability to interact with N, the lambda-encoded antitermination protein. A qualitative assay showed that mutations within boxA or boxB reduced interaction, while mutations outside boxA and boxB did not. These data show that (i) the recognition sites for N and Nun overlap to a very considerable extent but are probably not identical and (ii) a high concentration of Nun promotes its interaction with mutant nut sites, a behavior also reported to be characteristic of N.

Sequence-specific recognition of RNA hairpins by bacteriophage antiterminators requires a conserved arginine-rich motif

We have dissected the protein and nucleic acid determinants that direct a group of transcriptional antiterminators to their specific target operons. These antiterminators, the N gene products of phages lambda, 21, and P22, function solely with their respective recognition sites, nut, to modify RNA polymerase to a termination-resistant form. We demonstrate that a unique hairpin sequence within each nut site, called boxB, confers genome specificity by interacting with a small amino-terminal domain of the cognate N protein. This interaction is dependent upon an arginine-rich subdomain, which is conserved not only among the N proteins but also in many RNA binding proteins from ribosomes and RNA virus capsids. Notably, this motif constitutes an essential domain of the HIV protein Tat whose function as a trans-activator requires a specific hairpin sequence.

A plasmid to visualize and assay termination and antitermination of transcription in Escherichia coli

To facilitate the analysis of termination and antitermination of transcription in prokaryotes, a complex operon has been assembled into the pBR322 replicon, drawing upon natural and synthetic DNA elements. This operon is initiated from a strongly inducible promoter without temperature restraints. It includes a severe transcription terminator and therefore requires antitermination of transcription to express a downstream lacZ reporter gene. Antitermination can be provided by an upstream N-utilization site from phage lambda, working in conjunction with N protein supplied in trans from a compatible plasmid. In this situation, the nusA gene of Salmonella, substituted into the Escherichia coli host, prevents lacZ function, confirming that a good facsimile of lambda's specific antitermination mechanism has been recreated. The nonessential, easily assayed product of this operon, beta-galactosidase, is also screenable by colony color on chromogenic substrate. The plasmid described will therefore serve as a tester for mutations affecting the various aspects of transcription regulation by termination.