Modification of the properties of elongating RNA polymerase by persistent association with nascent antiterminator RNA.

Nascent RNA encoded by putL, a cis-acting antitermination site of bacteriophage HK022, increases readthrough of terminators by directly modifying the transcript elongation complex. To characterize the interaction between the antiterminator RNA and RNA polymerase, we stalled the elongation complex downstream of putL and determined the sensitivity of the transcript to ribonuclease cleavage. Part of PutL RNA was protected from cleavage by wild-type polymerase, but not by a mutant with a defect in put-dependent antitermination. We also exposed the stalled complex to oligonucleotides complementary to putL RNA, restarted transcription, and measured antitermination. Some, but not all, complementary oligonucleotides inhibited antitermination. Finally, cleavage of the RNA between putL and the 3'-end released putL RNA from the stalled complex and prevented antitermination.

Constitutive expression of a transcription termination factor by a repressed prophage: promoters for transcribing the phage HK022 nun gene.

Lysogens of phage HK022 are resistant to infection by phage lambda. Lambda resistance is caused by the action of the HK022 Nun protein, which prematurely terminates early lambda transcripts. We report here that transcription of the nun gene initiates at a constitutive prophage promoter, P(Nun), located just upstream of the protein coding sequence. The 5' end of the transcript was determined by primer extension analysis of RNA isolated from HK022 lysogens or RNA made in vitro by transcribing a template containing the promoter with purified Escherichia coli RNA polymerase. Inactivation of P(Nun) by mutation greatly reduced Nun activity and Nun antigen in an HK022 lysogen. However, a low level of residual activity was detected, suggesting that a secondary promoter also contributes to nun expression. We found one possible secondary promoter, P(Nun)', just upstream of P(Nun). Neither promoter is likely to increase the expression of other phage genes in a lysogen because their transcripts should be terminated downstream of nun. We estimate that HK022 lysogens in stationary phase contain several hundred molecules of Nun per cell and that cells in exponential phase probably contain fewer.

Family values in the age of genomics: comparative analyses of temperate bacteriophage HK022.

HK022 is a temperate coliphage related to phage lambda. Its chromosome has been completely sequenced, and several aspects of its life cycle have been intensively studied. In the overall arrangement, expression, and function of most of its genes, HK022 broadly resembles lambda and other members of the lambda family. Upon closer view, significant differences emerge. The differences reveal alternative strategies used by related phages to cope with similar problems and illuminate previously unknown regulatory and structural motifs. HK022 prophages protect lysogens from superinfection by producing a sequence-specific RNA binding protein that prematurely terminates nascent transcripts of infecting phage. It uses a novel RNA-based mechanism to antiterminate its own early transcription. The HK022 protein shell is strengthened by a complex pattern of covalent subunit interlinking to form a unitary structure that resembles chain-mail armour. Its integrase and repressor proteins are similar to those of lambda, but the differences provide insights into the evolution of biological specificity and the elements needed for construction of a stable genetic switch.

Recognition of core binding sites by bacteriophage integrases.

Bacteriophage integrases promote recombination between DNA molecules that carry attachment sites. They are members of a large and widely distributed family of site-specific recombinases with diverse biological roles. The integrases of phages lambda and HK022 are closely related members of this family, but neither protein efficiently recombines the attachment sites of the other phage. The nucleotides responsible for this specificity difference are located close to the points of recombinational strand exchange, within an integrase binding motif called the extended core binding site. There are four imperfectly repeated copies of this motif in each set of phage attachment sites, but only two, B' and C, contain major specificity determinants. When these specificity determinants were replaced by the corresponding nucleotides from a site with the alternative specificity, the resulting mutant was recombined by both integrases. Thus, the determinants act by impeding recombination promoted by the non-cognate integrase. We found that identical nucleotide substitutions within different core site copies had different effects on recombination, suggesting that integrase does not recognize each of the extended core binding sites in the same way. Finally, substitution at several positions in lambda integrase with the corresponding HK022-specific amino acids prevents recombination of lambda attachment sites, and this defect can be suppressed in an allele-specific manner by appropriate substitutions of HK022-specific nucleotides in the extended core binding sites.

The antiterminator RNA of phage HK022.

The put sites of phage HK022 increase the processivity of transcription and thereby promote the expression of viral genes that are located downstream of transcription terminators. RNA polymerase molecules that have traversed a put site are converted to a terminator-resistant form by the put transcript. We analyzed the structure and function of put transcripts by determining the effects of put mutations on terminator read-through, and by probing wild-type and mutant put RNAs with structure-specific nucleases. The results support the prediction that the secondary structure of the active transcript consists of two hairpin stems that are separated by a single unpaired base. The identity of bases in certain bulges and internal loops is important for activity, while that of most bases in the terminal loops is not. Many bases in the stems can be replaced with little or no effect on activity provided that base-pairing is maintained.

Transcripts that increase the processivity and elongation rate of RNA polymerase.

Transcripts encoded by the cis-acting antitermination sites (put sites) of lambdoid phage HK022 promote readthrough of downstream transcription terminators. Proper conformation of the transcripts is essential for activity, since put mutations that prevent the formation of predicted RNA stems prevented antitermination, and suppressor mutations that restore the stems restored antitermination. Antitermination does not appear to require proteins other than RNA polymerase, since put-dependent readthrough of multiple sequential terminators was observed in a purified transcription system consisting of template, polymerase, substrates, and buffer. Transcription of put also increased the elongation rate of polymerase, very likely by suppressing pausing. A mutation that alters the zinc-finger region of the beta' subunit of polymerase specifically prevented the put-dependent increases in terminator readthrough and elongation rate. The simplicity of HK022 antitermination contrasts with that of other known antitermination pathways. We propose that the central effector is a transcript that directly alters the elongation properties of RNA polymerase.

Identifying determinants of recombination specificity: construction and characterization of chimeric bacteriophage integrases.

Bacteriophage integrases are members of a family of structurally related enzymes that promote recombination between DNA molecules that carry specific sites. Phages lambda and HK022 encode closely related integrases that recognize different sets of sequences within the core regions of their respective attachment sites. To locate the amino acid residues that determine this difference in specificity, we isolated recombinant phages that produce chimeric integrases and measured the ability of these chimeras to promote recombination of lambda and HK022 sites in vivo. A chimera that is of lambda origin except for one HK022 residue at position 99 and 12 HK022 residues located between positions 279 and 329 had wild-type HK022 specificity and activity for both integrative and excisive recombination. Chimeras containing certain subsets of these 13 residues had incomplete specificity. The region around position 99 is not well-conserved in other members of the integrase family, but the 279-329 segment includes residues that are highly conserved and believed to be directly involved in catalysis. Many chimeras were inactive in recombining either HK022 or lambda sites. Selection for mutants that restored activity to these chimeras revealed sets of residues that are likely to interact with each other.

Identifying determinants of recombination specificity: construction and characterization of mutant bacteriophage integrases.

The Integrases of bacteriophages lambda and HK022 promote recombination between DNA molecules that carry attachment sites. The two integrases are about 70% identical in sequence and catalyze nearly identical reactions, but recognize different sets of sites. To identify the amino acids that determine this difference in specificity, we selected mutants of lambda integrase with increased ability to recombine HK022 sites. This selection yielded eleven different amino acid substitutions at eight different positions. Three of the positions belong to a larger set that were identified as important for the lambda/HK022 specificity difference by analysis of chimeric integrases. Substitution of the HK022 for the corresponding lambda residue at each of these three positions increased recombination of HK022 sites, and one double substitution, N99D-E319R, increased recombination to nearly wild-type HK022 levels. Mutations at the other five positions changed residues that are identical in the wild-type proteins or are at positions identified by chimera analysis as unimportant for the lambda/HK022 specificity difference. All of the mutants isolated by selection for increased recombination of HK022 sites retained considerable ability to recombine lambda sites. However, we found that substitution of HK022 for lambda residues at three additional positions, S282P, G283K, and R287K, specifically reduced recombination of lambda sites. These three substitutions when combined with N99D and E319R were sufficient to change the specificity of lambda to that of HK022 integrase. The first three substitutions act principally to prevent recombination of lambda sites, and the second two to remove a barrier to recombination of HK022 sites. We suggest that many natural alterations in the specificity of protein-DNA interactions occur by multi-step changes that first relax and then restrict specificity.

A zinc-binding region in the beta' subunit of RNA polymerase is involved in antitermination of early transcription of phage HK022.

Antitermination of early transcription in phage HK022 requires no virus-encoded proteins and thus differs from antitermination by other lambdoid phages. It does require cis-acting phage sequences, which may be analogous to the lambdoid nut sites. To identify host proteins involved in antitermination, we isolated 14 Escherichia coli mutants that are specifically blocked in HK022 growth. The mutations are located in the rpoC gene, which encodes the beta' subunit of RNA polymerase. Each mutation alters one of three amino acid residues located within a cluster of four completely conserved cysteine residues that are believed to bind zinc. We examined the effect of one mutation on HK022 antitermination in vivo. rpoCY75N greatly reduced readthrough of a strong rho-independent transcription terminator placed downstream of the HK022 PL promoter and nutL analog, but did not decrease promoter activity. Purified enzyme had a similar effect on PL-directed transcription in vitro: wild-type but not mutant polymerase read through a strong rho-independent terminator located immediately downstream of the nutL analog with high efficiency. We suggest that interaction of the putative zinc-binding domain of the RNA polymerase beta' subunit with the HK022 antitermination sites suppresses transcription termination, and that this interaction can occur in the absence of other proteins.

Lambda integrase cleaves DNA in cis.

In the Int family of site-specific recombinases, DNA cleavage is accomplished by nucleophilic attack on the activated scissile phosphodiester bond by a specific tyrosine residue. It has been proposed that this tyrosine is contributed by a protomer bound to a site other than the one being cleaved ('trans' cleavage). To test this hypothesis, the difference in DNA binding specificity between closely related integrases (Ints) from phages lambda and HK022 was exploited to direct wild type Ints and cleavage- or activation-defective mutants to particular sites on bispecific substrates. Analysis of Int cleavage at individual sites strongly indicates that DNA cleavage is catalyzed by the Int bound to the cleaved site ('cis' cleavage). This conclusion contrasts with those from previous experiments with two members of the Int family, FLP and lambda Int, that supported the hypothesis of trans cleavage. We suggest explanations for this difference and discuss the implications of the surprising finding that Int-family recombinases appear capable of both cis and trans mechanisms of DNA cleavage.

Growth phase variation of integration host factor level in Escherichia coli.

We have measured the intracellular abundance of integration host factor (IHF), a site-specific, heterodimeric DNA-binding protein, in exponential- and stationary-phase cultures of Escherichia coli K-12. Western immunoblot analysis showed that cultures that had been growing exponentially for several generations contained 0.5 to 1.0 ng of IHF subunits per microgram of total protein and that this increased to 5 to 6 ng/microgram in late-stationary-phase cultures. IHF is about one-third to one-half as abundant in exponentially growing cells as HU, a structurally related protein that binds DNA with little or no site specificity. Wild-type IHF is metabolically stable, but deletion mutations that eliminated one subunit reduced the abundance of the other when cells enter stationary phase. We attribute this reduction to the loss of stabilizing interactions between subunits. A mutation that inactivates IHF function but not subunit interaction increased IHF abundance, consistent with results of previous work showing that IHF synthesis is negatively autoregulated. We estimate that steady-state exponential-phase cultures contain about 8,500 to 17,000 IHF dimers per cell, a surprisingly large number for a site-specific DNA-binding protein with a limited number of specific sites. Nevertheless, small reductions in IHF abundance had significant effects on several IHF-dependent functions, suggesting that the wild-type exponential phase level is not in large excess of the minimum required for occupancy of physiologically important IHF-binding sites.

A segment of the phage HK022 chromosome is a mosaic of other lambdoid chromosomes.

We report the sequence of a region of the PR operon of lambdoid phage HK022 and an analysis of the proteins it encodes. This region has DNA sequence elements and open reading frames that resemble those found in phages lambda, P22, and phi 80. The open reading frames encode homologs of the lambda CII transcription activator, the P22 DNA replication proteins, and a fourth protein of unknown function.

Use of a gene encoding a suppressor tRNA as a reporter of transcription: analyzing the action of the Nun protein of bacteriophage HK022.

The Nun protein of phage HK022 blocks the expression of genes that lie downstream of the nut sites of phage lambda. Nun is believed to act by promoting premature termination of transcription at or near these sites. To test this hypothesis and to facilitate mapping the sites of termination, we inserted a gene encoding a suppressor tRNA immediately downstream of the lambda nutL site and determined the effect of Nun on tRNA level. We found that Nun severely reduced the accumulation of mature, biologically active tRNA and promoted the accumulation of short, promoter-proximal transcripts whose 3' ends were dispersed over a 100-nucleotide region downstream of nutL. These results are consistent with the hypothesis that Nun terminates transcription within the region immediately downstream of nutL and are inconsistent with the hypothesis that the only action of Nun is to prevent translation of genes located downstream of the nut site. The stability, small size, and easily assayable biological function of suppressor tRNA recommend it as a reporter of transcription in other systems.

Xis and Fis proteins prevent site-specific DNA inversion in lysogens of phage HK022.

HK022, a temperate coliphage related to lambda, forms lysogens by inserting its DNA into the bacterial chromosome through site-specific recombination. The Escherichia coli Fis and phage Xis proteins promote excision of HK022 DNA from the bacterial chromosome. These two proteins also act during lysogenization to prevent a prophage rearrangement: lysogens formed in the absence of either Fis or Xis frequently carried a prophage that had suffered a site-specific internal DNA inversion. The inversion is a product of recombination between the phage attachment site and a secondary attachment site located within the HK022 left operon. In the absence of both Fis and Xis, the majority of lysogens carried a prophage with an inversion. Inversion occurs during lysogenization at about the same time as prophage insertion but is rare during lytic phage growth. Phages carrying the inverted segment are viable but have a defect in lysogenization, and we therefore suggest that prevention of this rearrangement is an important biological role of Xis and Fis for HK022. Although Fis and Xis are known to promote excision of lambda prophage, they had no detectable effect on lambda recombination at secondary attachment sites. HK022 cIts lysogens that were blocked in excisive recombination because of mutation in fis or xis typically produced high yields of phage after thermal induction, regardless of whether they carried an inverted prophage. The usual requirement for prophage excision was bypassed in these lysogens because they carried two or more prophages inserted in tandem at the bacterial attachment site; in such lysogens, viable phage particles can be formed by in situ packaging of unexcised chromosomes.

Antitermination of early transcription in phage HK022. Absence of a phage-encoded antitermination factor.

In phage lambda and its relatives most early phage genes are located downstream from transcription termination sites, and full gene expression requires suppression of termination (or antitermination). Phage HK022, a lambda relative, also antiterminates early transcription, but, unlike its relatives, does so in the absence of any active phage gene product. We found no functional equivalent of the lambda N antitermination protein in HK022. In addition, nus mutations, which alter host proteins required for lambda antitermination, have no apparent effect on HK022 early gene expression. We have shown that terminators located several thousand base-pairs from the start point of transcription are suppressed, and that in the left operon suppression requires a short, promoter-proximal segment. A 40 bp region within this segment is repeated in the right operon. The chromosomal locations of these repeated segments resemble those of the nut antitermination sites of other lambdoid phages, but the HK022 sites lack the conserved sequence elements of the nut sites. It appears that HK022 antiterminates early transcription in a novel way.

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.

The early promoters of bacteriophage HK022: contrasts and similarities to other lambdoid phages.

The pL, pR and pM promoters of lambdoid phages direct the transcription of early phage genes and the prophage repressor gene. We have determined the start points of transcription for these three promoters in the lambdoid phage HK022 and have shown that the HK022 repressor represses the early promoters, pL and pR, and activates the repressor promoter, pM. HK022 resembles other phages of the lambda family in these respects, as it does in the functional organization of most of its early genes and sites. One exception is nun, the first gene of the HK022 pL operon, which is expressed in the presence of prophage repressor and thus differs from its lambda counterpart, gene N. We show that transcription of nun in a lysogen does not initiate at pL but instead starts upstream at the pM promoter. This difference in transcription fits the different roles of Nun and N proteins in the physiology of the two phages: Nun protects HK022 lysogens against superinfection with certain other lambdoid phages, while N promotes the transcription of early lambda genes.

Specificity determinants in the attachment sites of bacteriophages HK022 and lambda.

The Int proteins of bacteriophages HK022 and lambda promote recombination between phage and bacterial attachment sites. Although the proteins and attachment sites of the two phages are similar, neither protein promotes efficient recombination between the pair of attachment sites used by the other phage. To analyze this difference in specificity, we constructed and characterized chimeric attachment sites in which segments of one site were replaced with corresponding segments of the other. Most such chimeras recombined with appropriate partner sites in vivo and in vitro, and their differential responses to the Int proteins of the two phages allowed us to locate determinants of the specificity difference in the bacterial attachment sites and a central segment of the phage attachment sites. The location of these determinants encompasses three of the four core-type binding sites for lambda Int: C, B, and most importantly, B'. The regions corresponding to the C' core binding site and the arm-type binding sites of lambda Int play no role in the specificity difference and, indeed, are well conserved in the two phages. We found, unexpectedly, that the effect of replacement of an Int-binding region on the recombinational potency of one chimeric site was reversed by a change of partner. This novel context effect suggests that postsynaptic interactions affect the specificity of recognition of attachment sites by Int.