Sequences required for antitermination by phage 82 Q protein

Hybrid Vigor: Importance of Hybrid λ Phages in Early Insights in Molecular Biology

Laboratory-generated hybrids between phage λ and related phages played a seminal role in establishment of the λ model system, which, in turn, served to develop many of the foundational concepts of molecular biology, including gene structure and control. Important λ hybrids with phages 21 and 434 were the earliest of such phages. To understand the biology of these hybrids in full detail, we determined the complete genome sequences of phages 21 and 434. Although both genomes are canonical members of the λ-like phage family, they both carry unsuspected bacterial virulence gene types not previously described in this group of phages. In addition, we determined the sequences of the hybrid phages λ imm21, λ imm434, and λ h434 imm21. These sequences show that the replacements of λ DNA by nonhomologous segments of 21 or 434 DNA occurred through homologous recombination in adjacent sequences that are nearly identical in the parental phages. These five genome sequences correct a number of errors in published sequence fragments of the 21 and 434 genomes, and they point out nine nucleotide differences from Sanger's original λ sequence that are likely present in most extant λ strains in laboratory use today. We discuss the historical importance of these hybrid phages in the development of fundamental tenets of molecular biology and in some of the earliest gene cloning vectors. The 434 and 21 genomes reinforce the conclusion that the genomes of essentially all natural λ-like phages are mosaics of sequence modules from a pool of exchangeable segments.

Structural and mechanistic basis of σ-dependent transcriptional pausing

In σ-dependent transcriptional pausing, the transcription initiation factor σ, translocating with RNA polymerase (RNAP), makes sequence-specific protein–DNA interactions with a promoter-like sequence element in the transcribed region, inducing pausing. It has been proposed that, in σ-dependent pausing, the RNAP active center can access off-pathway “backtracked” states that are substrates for the transcript-cleavage factors of the Gre family and on-pathway “scrunched” states that mediate pause escape. Here, using site-specific protein–DNA photocrosslinking to define positions of the RNAP trailing and leading edges and of σ relative to DNA at the λPR′ promoter, we show directly that σ-dependent pausing in the absence of GreB in vitro predominantly involves a state backtracked by 2–4 bp, and σ-dependent pausing in the presence of GreB in vitro and in vivo predominantly involves a state scrunched by 2–3 bp. Analogous experiments with a library of 47 (∼16,000) transcribed-region sequences show that the state scrunched by 2–3 bp—and only that state—is associated with the consensus sequence, T−3N−2Y−1G+1, (where −1 corresponds to the position of the RNA 3′ end), which is identical to the consensus for pausing in initial transcription and which is related to the consensus for pausing in transcription elongation. Experiments with heteroduplex templates show that sequence information at position T−3 resides in the DNA nontemplate strand. A cryoelectron microscopy structure of a complex engaged in σ-dependent pausing reveals positions of DNA scrunching on the DNA nontemplate and template strands and suggests that position T−3 of the consensus sequence exerts its effects by facilitating scrunching.

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.

Initial transcribed region sequences influence the composition and functional properties of the bacterial elongation complex

The bacterial RNA polymerase (RNAP) holoenzyme consists of a catalytic core enzyme (α(2)ββ'ω) in complex with a σ factor that is essential for promoter recognition and transcription initiation. During early elongation, the stability of interactions between σ and the remainder of the transcription complex decreases. Nevertheless, there is no mechanistic requirement for release of σ upon the transition to elongation. Furthermore, σ can remain associated with RNAP during transcription elongation and influence regulatory events that occur during transcription elongation. Here we demonstrate that promoter-like DNA sequence elements within the initial transcribed region that are known to induce early elongation pausing through sequence-specific interactions with σ also function to increase the σ content of downstream elongation complexes. Our findings establish σ-dependent pausing as a mechanism by which initial transcribed region sequences can influence the composition and functional properties of the transcription elongation complex over distances of at least 700 base pairs.

A backtrack-inducing sequence is an essential component of Escherichia coli σ(70)-dependent promoter-proximal pausing

RNA polymerase of both bacteria and eukaryotes can stall or pause within tens of base pairs of its initiation site at the promoter, a state that may reflect important regulatory events in early transcription. In the bacterial model system, the σ(70) initiation factor stabilizes such pauses by binding a downstream repeat of a promoter segment, especially the '-10' promoter element. We first show here that the '-35' promoter element also can stabilize promoter-proximal pausing, through interaction with σ(70) region 4. We further show that an essential element of either type of pause is a sequence just upstream of the site of pausing that stabilizes RNA polymerase backtracking. Although the pause is not intrinsically backtracked, we suggest that the same sequence element is required both to stabilize the paused state and to potentiate backtracking.

RNA-mediated destabilization of the sigma(70) region 4/beta flap interaction facilitates engagement of RNA polymerase by the Q antiterminator

The bacterial RNA polymerase (RNAP) holoenzyme consists of a catalytic core enzyme (alpha(2)betabeta'omega) complexed with a sigma factor that is required for promoter-specific transcription initiation. During early elongation, the stability of interactions between sigma(70) (the primary sigma factor in Escherichia coli) and core decreases due to an ordered displacement of segments of sigma(70) from core triggered by growth of the nascent RNA. Here we demonstrate that the nascent RNA-mediated destabilization of an interaction between sigma(70) region 4 and the flap domain of the beta subunit is required for the bacteriophage lambda Q antiterminator protein to contact holoenzyme during early elongation. We demonstrate further that the requirement for nascent RNA in the process by which Q engages RNAP can be bypassed if sigma(70) region 4 is removed. Our findings illustrate how a regulator can exploit the nascent RNA-mediated reconfiguration of the holoenzyme to gain access to the enzyme during early elongation.

Sigma and RNA polymerase: an on-again, off-again relationship?

In bacteria, a fundamental level of gene regulation occurs by competitive association of promoter-specificity factors called sigmas with RNA polymerase (RNAP). This sigma cycle paradigm underpins much of our understanding of all transcriptional regulation. Here, we review recent challenges to the sigma cycle paradigm in the context of its essential features and of the structural basis of sigma interactions with RNAP and elongation complexes. Although sigmas can play dual roles as both initiation and elongation regulators, we suggest that the key postulate of the sigma cycle, that sigmas compete for binding to RNAP after each round of RNA synthesis, remains the central mechanism for programming transcription initiation in bacteria.

Role of the non-template strand of the elongation bubble in intrinsic transcription termination

Intrinsic transcription terminators of Escherichia coli and other bacteria, consisting primarily of an RNA hairpin preceding a terminal uridine-rich RNA segment, suffice to dissociate the otherwise stable elongation complex of core RNA polymerase. The essential functions of the hairpin and U-rich segments have been established, although the precise mechanism of termination is unknown. We identify another element of the terminator, namely the non-template DNA strand in the region of the terminal transcription bubble. Failure of the terminal bubble to rewind through complementary base-pairing strongly reduces the efficiency of terminator function, suggesting that the natural pathway of termination consists of coupled rewinding of the DNA template and unwinding of the RNA/DNA hybrid at the site of release.

RNA polymerase mutations that impair conversion to a termination-resistant complex by Q antiterminator proteins

Bacteriophage lambda Q-protein stably binds and modifies RNA polymerase (RNAP) to a termination-resistant form. We describe amino acid substitutions in RNAP that disrupt Q-mediated antitermination in vivo and in vitro. The positions of these substitutions in the modeled RNAP/DNA/RNA ternary elongation complex, and their biochemical properties, suggest that they do not define a binding site for Q in RNAP, but instead act by impairing interactions among core RNAP subunits and nucleic acids that are essential for Q modification. A specific conjecture is that Q modification stabilizes interactions of RNAP with the DNA/RNA hybrid and optimizes alignment of the nucleic acids in the catalytic site. Such changes would inhibit the activity of the RNA hairpin of an intrinsic terminator to disrupt the 5'-terminal bases of the hybrid and remove the RNA 3' terminus from the active site.

Function of transcription cleavage factors GreA and GreB at a regulatory pause site

Gre proteins of prokaryotes, and SII proteins of eukaryotes and archaea, are transcription elongation factors that promote an endogenous transcript cleavage activity of RNA polymerases; this process promotes elongation through obstructive regions of DNA, including transcription pauses that act as sites of genetic regulation. We show that a regulatory pause in the early part of the late gene operon of bacteriophage lambda is subject to such cleavage and resynthesis. In cells lacking the cleavage factors GreA and GreB, the pause is prolonged, and RNA polymerase occupies a variant position at the pause site. Furthermore, GreA and GreB are required to mediate efficient function of the lambda gene Q antiterminator at this site. Thus, cleavage factors are necessary for the natural progression of RNA polymerase in vivo.

Function of E. coli RNA polymerase sigma factor sigma 70 in promoter-proximal pausing

The sigma factor sigma 70 of E. coli RNA polymerase acts not only in initiation, but also at an early stage of elongation to induce a transcription pause, and simultaneously to allow the phage lambda gene Q transcription antiterminator to act. We identify the signal in DNA that induces early pausing to be a version of the sigma 70 -10 promoter consensus, and we show that sigma 70 is both necessary for pausing and present in the paused transcription complex. Regions 2 and 3 of sigma 70 suffice to induce pausing. Since pausing is induced by the nontemplate DNA strand of the open transcription bubble, we conclude that RNA polymerase containing sigma 70 carries out base-specific recognition of the nontemplate strand as single stranded DNA. We suggest that sigma 70 remains bound to core RNA polymerase when the -10 promoter contacts are broken, and then moves to the pause-inducing sequence.

Function of a nontranscribed DNA strand site in transcription elongation

A prolonged pause in transcription elongation at positions +16 and +17 of the phage lambda late gene operon has an important role in the modification of RNA polymerase by the lambda gene Q transcription antiterminator. Mutations included in the transcription bubble of the paused transcription complex, particularly at +2 and +6, abolish pausing and the ability of Q protein to modify RNA polymerase. By transcribing heteroduplex templates made in vitro, we show that the sites identified by these mutations act through the nontranscribed strand of DNA. This result suggests unexpected regulatory functions of the nontranscribed DNA strand in transcription.

Transcription termination

Chromosomes are organized into units of expression that are bounded by sites where transcription of DNA sequences into RNA is initiated and terminated. To allow for efficient stepwise assembly of complete transcripts, the transcribing enzyme (RNA polymerase) makes a stable complex with the DNA template until it reaches the terminator. Three general mechanisms of transcription termination have been recognized: one is by a spontaneous dissociation of the RNA at a sequence segment where RNA polymerase does not maintain its usual stable interaction with the nascent chain; another involves the action of a protein (rho factor in bacteria) on the nascent RNA to mediate its dissociation; and a third involves an action triggered by a protein that binds to the DNA at a sequence that is just downstream of the termination stop point. Transcription termination is important in the regulation of gene expression both by modulating the relative levels of various genes within a single unit of expression and by controlling continuation of transcription in response to a metabolic or regulatory signal.

Bacteriophage lysis: mechanism and regulation

Bacteriophage lysis involves at least two fundamentally different strategies. Most phages elaborate at least two proteins, one of which is a murein hydrolase, or lysin, and the other is a membrane protein, which is given the designation holin in this review. The function of the holin is to create a lesion in the cytoplasmic membrane through which the murein hydrolase passes to gain access to the murein layer. This is necessary because phage-encoded lysins never have secretory signal sequences and are thus incapable of unassisted escape from the cytoplasm. The holins, whose prototype is the lambda S protein, share a common organization in terms of the arrangement of charged and hydrophobic residues, and they may all contain at least two transmembrane helical domains. The available evidence suggests that holins oligomerize to form nonspecific holes and that this hole-forming step is the regulated step in phage lysis. The correct scheduling of the lysis event is as much an essential feature of holin function as is the hole formation itself. In the second strategy of lysis, used by the small single-stranded DNA phage phi X174 and the single-stranded RNA phage MS2, no murein hydrolase activity is synthesized. Instead, there is a single species of small membrane protein, unlike the holins in primary structure, which somehow causes disruption of the envelope. These lysis proteins function by activation of cellular autolysins. A host locus is required for the lytic function of the phi X174 lysis gene E.

The phage lambda gene Q transcription antiterminator binds DNA in the late gene promoter as it modifies RNA polymerase

The bacteriophage lambda gene Q transcription antiterminator modifies RNA polymerase during an extended pause in elongation at nt +16 and +17 of the phage late gene promoter transcript. We show here that Q binds a specific DNA site between the -10 and -35 elements of the promoter as it interacts with the enzyme. We show that the pause must reflect a specialized elongation structure that is receptive to modification by Q, because Q does not bind to RNA polymerase stopped artificially after transcribing 16 nt of mutant DNA that does not encode the natural pause. Footprinting shows that RNA polymerase in the paused complex makes distinctive interactions with DNA in the region where Q binds; binding of Q, in turn, changes the footprint both at the Q-binding site and in the transcription bubble. Binding of Q to the paused transcription complex is stabilized by the transcription factor NusA, as expected from the dependence of lambda Q-mediated antitermination on NusA.

Characterization of the late-gene regulatory region of phage 21

A segment of Escherichia coli bacteriophage 21 DNA encoding the late-gene regulator, Q21, and the late-gene leader RNA segment was sequenced; its structure is similar to those of the related phages lambda and 82. The leader RNA is about 45 nucleotides long and consists essentially entirely of sequences encoding the p-independent terminator that is the putative target of the antitermination activity of Q21. Like the corresponding regions of lambda and 82, the 21 late-gene promoter segment encodes an early transcription pause in vitro, at about nucleotide 18, during which Q21 presumably acts to modify RNA polymerase. The 21 Q gene, cloned in isolation, is active on the late-gene leader segment in trans, and its purified product is active as an antiterminator in vitro; Q21 represents a third late-gene antiterminator, in addition to those of lambda and 82. There is little evident similarity in the primary sequences of the three Q genes.

Heterogeneous initiation due to slippage at the bacteriophage 82 late gene promoter in vitro

RNAs synthesized in vitro by purified Escherichia coli RNA polymerase from a bacteriophage 82 promoter are heterogeneous at the 5' end. We show that this heterogeneity results from variable addition of extra adenine residues, allowed by slippage of the initial oligonucleotide pppAAA-OH against its DNA template sequence TTT. Slippage backward by one base allows another A to be added, giving pppAAAA-OH, and this cycle can continue more than 20 times before it is ended by incorporation of UMP encoded by the fourth template base A. Slippage is abolished by mutation of the TTT template sequence to TGT and is sensitive to the concentrations of UTP and ATP in the reaction mixture. Analysis of deletions, substitutions, and point mutants implies that the slippage reaction requires only the existence of TTT at the initiation site of the template strand, although changes in neighboring nucleotides slightly affect its efficiency.

A quantitative assessment for transcriptional pausing of DNA-dependent RNA polymerases in vitro

A simple definition for pause strength (tau i) has been given, quantitatively describing transcriptional pausing of RNA polymerases. It permits derivation of practical assessments, based on single-round transcription reactions, which measure the average time a polymerase stops in vitro at certain sites during transcription elongation. We demonstrate that pause strengths can be determined with high accuracy when transcription elongation is started simultaneously from radioactively labeled and purified ternary complexes and transcripts are separated on sequencing gels. Our concept is exemplified by measuring pause strengths on supercoiled templates in the leader region of the Escherichia coli rrnB operon in the presence and the absence of the transcription factor NusA.

Specificity and mechanism of antitermination by Q proteins of bacteriophages lambda and 82

Lambdoid phage late gene operons are positively regulated by genome-specific antiterminator proteins encoded by the Q gene of each phage. In this paper, we compare the activity of phage lambda and phage 82 Q proteins. Q82-mediated antitermination, like that of Q lambda, involves a transcription pause during which the regulator can modify RNA polymerase. We show that the activities of both Q82 and Q lambda are genome-specific in chasing RNA polymerase out of the early pause sites and in mediating antitermination. Finally, we show that the length of the RNA in the paused complex, or the exact position of the pause, affects the efficiency with which Q82 chases RNA polymerase out of the pause.