Conservation of genome form but not sequence in the transcription antitermination determinants of bacteriophages lambda, phi 21 and P22

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

The N protein of bacteriophage lambda (N lambda) modifies Escherichia coli RNA polymerase in such a way that it transcribes through termination signals, a process called antitermination. N antitermination normally occurs only if the template contains a specific utilization or nut site upstream of the terminators and only in the presence of host-encoded Nus proteins. The lambda-related phages 21 and P22 produce N analogs, N21 and N22, but these require different nut sites and show a different pattern of functional interaction with one of the Nus factors, NusA, according to whether this protein is of E. coli or Salmonella origin (NusAEc or NusASal). We report the overproduction of N lambda, N21, or N22, each of which was induced by isopropyl-beta-D-thiogalactopyranoside at 37 degrees C from its cloned position downstream from ptac on a high-expression plasmid, each in a host that provided NusAEc or NusASal. Overproduction of each of these N proteins resulted in relaxed specificity for nut, which was shown by the ability to complement N mutants of heterologous phages; NusA specificity was determined by the N type that was present in these complementation tests. We also observed that excess N was able to suppress transcriptional polarity in the particular case of cloned 'trpA, the last gene of the tryptophan operon, although there was no effect on polarity within chromosomal trpE. Such polarity is attributed to the presence of cryptic intragenic terminators that become exposed in the absence of translation. Because there is no known nut site cis to 'trpA, we suggest that the 'trpA segment itself fortuitously contains a nut sequence that is able to function with excess N of any of the types tested and with either NusAEc or NusASal. We also found that excess N of any specificity, or even inactive N with missense mutation, could cause an increase in the level of NusAEc or NusASal, possibly because interaction between N and NusA, but independent of nut, whether functional or not, interferes with the autoregulation of NusA synthesis. These observations highlight the importance of protein concentration for the specificity of interactions both with other proteins and with nucleic acids. They also indicate that the interaction between N and NusA requires nut participation both for specificity and functionality.

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.

Cell division inhibition gene dicB is regulated by a locus similar to lambdoid bacteriophage immunity loci

A mutation (dicA1) of a repressor gene located in the terminus region of the Escherichia coli chromosome has previously been shown to lead to temperature-dependent inhibition of division, and to be complemented by plasmids carrying either dicA or an adjacent gene dicC. In this study, operon fusions in the region coding for the division inhibition gene dicB have been used to show that temperature sensitivity does not result from high temperature inactivation of the dicA repressor. Sequence comparisons indicate that dicA and dicC are similar to genes c2 and cro respectively of bacteriophage P22, and carry similarly organized tandem operators, indicating a common evolutionary origin for dicAC and P22 immC. Nevertheless, the consensus half-operator sequence of dicAC, TGTTA-GYYA, differs significantly from that of P22 immC (ATT-TAAGAN). An analysis of the in vivo control of promoters dicAp, dicBp and dicCp placed upstream of malQ shows that the dicAC system is functionally similar to that of an immunity region, with the possible exception of an absence of pairwise cooperative binding. Our results also indicate that the dicA1 mutation causes a switch to permanent control by dicC at all temperatures.

NusA protein is necessary and sufficient in vitro for phage lambda N gene product to suppress a rho-independent terminator placed downstream of nutL

Transcription antitermination by phage lambda N protein is reproduced in vitro solely with purified components. We have placed a strong rho-independent terminator, lambda tR', in the PL operon about 200 base pairs downstream from the N-recognition site, nutL, and have monitored terminated and run-off transcripts produced by single-round transcription of linear plasmids. In the presence of NusA, one of several host factors implicated in antitermination, N is found to virtually abolish termination at tR'. N is unable to suppress termination if the terminator is preceded by a defective nut site. Thus, during transcription through the nut site, N and NusA can modify RNA polymerase to a termination-resistant form in the absence of any other accessory factor.

An elongation control particle containing the N gene transcriptional antitermination protein of bacteriophage lambda

The N gene transcriptional antitermination protein of bacteriophage lambda is incorporated in vitro into transcriptional elongation complexes containing the E. coli proteins NusA and NusB. The binding of NusA to elongating RNA polymerase is sequence-independent and follows the release of sigma 70. Incorporation of N into the elongation complex requires an N utilization site (nut site) on the DNA template. Incorporation of NusB into the complex requires NusA, ribosomal protein S10, and the boxA component of the nut site. T1 RNAase releases N, but not NusB, from the elongation complex. We therefore propose that an N-modified termination-resistant elongation complex includes an elongation control particle (ECP) containing at least NusA, NusB, S10, N, and an RNA transcript of the nut site.

An antitermination protein engages the elongating transcription apparatus at a promoter-proximal recognition site

As a transcriptional activator, the N protein of phage lambda acts to suppress transcription termination by recognizing a promoter-proximal site, nut, which is separated from the terminators by thousands of base pairs. We demonstrate here that N interacts with the elongating RNA polymerase in transit through the boxB domain of nut. This interaction leads to the stable association of N as an integral component of the transcription apparatus. During subsequent elongation, N translocates along with polymerase through several defined terminators positioned beyond nut. Therefore, by being an operon-specific subunit of the transcription apparatus, N presumably prevents the interaction of polymerase with termination signals.

Initiation of bacteriophage P22 DNA packaging series. Analysis of a mutant that alters the DNA target specificity of the packaging apparatus

Bacteriophage P22 is thought to package its double-stranded DNA chromosome from concatemeric replicating DNA in a "processive" sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally from that point. DNA ends are generated near the pac site before or during the condensation reaction. The opposite end of the mature chromosome is created by a cut made in the DNA after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here the identification of a consensus nucleotide sequence for the pac site, and present evidence that supports the idea that the gene 3 protein is a central participant in this recognition event. In addition, we tentatively locate the portion of the gene 3 protein that contacts the pac site during the initiation of packaging.

Functional elements of DNA upstream from the integrase operon that are conserved in bacteriophages 434 and lambda

A 1488-bp restriction fragment of bacteriophage 434 DNA contains the integrase promoter and an adjacent nucleotide sequence (t'I) resembling a Rho-independent terminator. To identify and quantitate transcription termination, DNA segments were cloned into a plasmid between the galactose promoter and assayable galactokinase gene and tested for termination. Whereas the entire fragment effectively terminated transcription, a 331-bp restriction fragment containing the t'I terminator had only weak terminator activity. Random sequential deletions of the 434 DNA segment defined a strong terminator 650-bp upstream from t'I. This proposed Rho-independent terminator called tL4 consists of a 7-bp stem and 6-nt loop followed by a uridine-rich region in the RNA. Phage lambda contains an even stronger tL4 terminator that differs in 4 nt from 434 tL4. Thus, despite some sequence divergence, terminator activity has been conserved in these phages. The 434 DNA segment was also tested for promoter activity. Rightward promoter activity (opposite to pL in the phage) was located about 200 bp to the right of tL4 and was followed by an open reading frame (ORF) capable of encoding a 91 amino acid protein. Promoter activity in the same approximate location was also found in phage lambda. Thus the rightward promoter, the tL4 and t'I terminators, and ORF-55 all are elements in this segment of the genome that are conserved for function despite sequence divergence.

Bacteriophage L: chromosome physical map and structural proteins

Restriction endonuclease cleavage site mapping was used to locate the regions of highest sequence homology in the chromosomes of Salmonella typhimurium bacteriophages L and P22. These lie in the DNA packaging, tail, early transcription antitermination, and perhaps integration "gene modules." Other regions of the two genomes are substantially less closely related. Phage L, which has no functional immunity I region, lacks approximately 1300 bp of DNA when compared to P22 in this section of the chromosome. At least some of the virion structural proteins are interchangeable between the two phages, which suggests that the two phage structural protein genes are very closely related. In addition, the apparent molecular weights of most P22 and L phage structural proteins are very similar. However, the phage L virion contains about 140 molecules of a 15K capsid protein which apparently has no P22 analog.

"N" transcription antitermination proteins of bacteriophages lambda, phi 21 and P22

Comparison is made among the amino acid sequences of three transcription antitermination proteins, based upon the DNA sequences of their genes in bacteriophages lambda, phi 21 and P22. The three proteins are all small (about 100 amino acids), hydrophilic and basic, but otherwise show little homology. A basic region near the amino terminus has several amino acid positions common to all three proteins and is the locus of mutations that alter six different amino acid positions inactivating the lambda N protein. A less basic region near the center is the locus of three mutations affecting the interaction of lambda N with host nusA protein. The N gene of phi 21 has an amino terminus more like that of P22, and a carboxy terminus clearly related to that of lambda.