An RNA polymerase alpha subunit mutant impairs N-dependent transcriptional antitermination in Escherichia coli

The site of action of the antiterminator protein N from the lambdoid phage H-19B

Transcription antitermination by N proteins of lambdoid phages involves specific interactions of the C-terminal domain of N with the elongation complex (EC). The interacting surface of N on the EC is unknown, knowledge of which is essential to understand the mechanism of antitermination. Specific cleavage patterns were generated near the active site Mg2+ of the RNA polymerase of an N-modified stalled EC using iron-(S)-1-(p-bromoacetamidobenzyl)ethylenediaminetetraacetate conjugated to the only cysteine residue in the C-terminal domain of N from a lambdoid phage H-19B. Modification of EC by N also induced conformational changes around the same region as revealed from the limited trypsin digestion and in situ Fe-dithiothreitol cleavage pattern of the same EC. These data, together with the previously obtained H-19B N-specific mutations in RNA polymerase, beta (G1045D), and beta' (P251S, P254L, G336S, and R270C) subunits, suggest that the active center cleft of the EC could be the site of action of this antiterminator. H-19B N induced altered interactions in this region of EC, prevented the backtracking of the stalled EC at the ops pause site and destabilized RNA hairpin-beta subunit flap domain interactions at the his pause site. We propose that the physical proximity of the C-terminal domain of H-19B N to the active center cleft of the EC is required for the process of transcription antitermination and that it involves both stabilization of the weak RNA-DNA hybrid at a terminator and destabilization of the interactions of terminator hairpin in the RNA exit channel.

Escherichia coli RNA polymerase mutations located near the upstream edge of an RNA:DNA hybrid and the beginning of the RNA-exit channel are defective for transcription antitermination by the N protein from lambdoid phage H-19B

Transcription antitermination is an important mechanism that can control regulation of gene expression. The N protein of lambdoid phages modifies the transcription elongation complex (EC) and helps it to overcome downstream terminators. In this modified EC, the C-terminal domain of N makes specific interactions with RNA polymerase (RNAP). The interacting surface of RNAP for N is unknown. Here, we report five mutations in the beta (G1045D) and beta' (P251S, P254L, R270C and G336S) subunits of RNAP that are specifically defective for antitermination by N protein of the lambdoid phage, H-19B. A mutation in the C-terminal domain of N, L108F, suppresses the defect of beta'-P254L. Purified mutant holoenzymes exhibit less processive antitermination. The amino acid substitutions in the mutant RNAPs cluster very close to the RNA:DNA hybrid at the beginning of the RNA-exit channel of the EC. We suggest that the action of H-19B N is exerted through the region defined by these amino acids. Wild-type N stabilizes the EC at terminator sites and in this modified EC a part of the terminator hairpin may form but appears to be unstable. We propose that the action of N close to the active center alters the RNAP-nucleic acid interactions around the RNA:DNA hybrid, which impairs proper folding of the terminator hairpin or stabilizes the weak RNA:DNA hybrid, or both.

Toxicity of the bacteriophage lambda cII gene product to Escherichia coli arises from inhibition of host cell DNA replication

The bacteriophage lambda cII gene codes for a transcriptional activator protein which is a crucial regulator at the stage of the "lysis-versus-lysogeny" decision during phage development. The CII protein is highly toxic to the host, Escherichia coli, when overproduced. However, the molecular mechanism of this toxicity is not known. Here we demonstrate that DNA synthesis, but not total RNA synthesis, is strongly inhibited in cII-overexpressing E. coli cells. The toxicity was also observed when the transcriptional stimulator activity of CII was abolished either by a point mutation in the cII gene or by a point mutation, rpoA341, in the gene coding for the RNA polymerase alpha subunit. Moreover, inhibition of cell growth, caused by both wild-type and mutant CII proteins in either rpoA(+) or rpoA341 hosts, could be relieved by overexpression of the E. coli dnaB and dnaC genes. In vitro replication of an oriC-based plasmid DNA was somewhat impaired by the presence of the CII, and several CII-resistant E. coli strains contain mutations near dnaC. We conclude that the DNA replication machinery may be a target for the toxic activity of CII.

Interplay between DnaA and SeqA proteins during regulation of bacteriophage lambda pR promoter activity

DnaA and SeqA proteins are main regulators (positive and negative, respectively) of the chromosome replication in Escherichia coli. Nevertheless, both these replication regulators were found recently to be also transcription factors. Interestingly, both DnaA and SeqA control activity of the bacteriophage lambdap(R) promoter by binding downstream of the transcription start site, which is unusual among prokaryotic systems. Here we asked what are functional relationships between these two transcription regulators at one promoter region. Both in vivo and in vitro studies revealed that DnaA and SeqA can activate the p(R) promoter independently and separately rather than in co-operation, however, increased concentrations of one of these proteins negatively influenced the transcription stimulation mediated by the second regulator. This may suggest a competition between DnaA and SeqA for binding to the p(R) regulatory region. The physiological significance of this DnaA and SeqA-mediated regulation of p(R) is demonstrated by studies on lambda plasmid DNA replication in vivo.

SeqA-mediated stimulation of a promoter activity by facilitating functions of a transcription activator

It was demonstrated recently that the SeqA protein, a main negative regulator of Escherichia coli chromosome replication initiation, is also a specific transcription factor. SeqA specifically activates the bacteriophage lambda pR promoter while revealing no significant effect on the activity of another lambda promoter, pL. Here, we demonstrate that lysogenization by bacteriophage lambda is impaired in E. coli seqA mutants. Genetic analysis demonstrated that CII-mediated activation of the phage pI and paQ promoters, which are required for efficient lysogenization, is less efficient in the absence of seqA function. This was confirmed in in vitro transcription assays. Interestingly, SeqA stimulated CII-dependent transcription from pI and paQ when it was added to the reaction mixture before CII, although having little effect if added after a preincubation of CII with the DNA template. This SeqA-mediated stimulation was absolutely dependent on DNA methylation, as no effects of this protein were observed when using unmethylated DNA templates. Also, no effects of SeqA on transcription from pI and paQ were observed in the absence of CII. Binding of SeqA to templates containing the tested promoters occurs at GATC sequences located downstream of promoters, as revealed by electron microscopic studies. In contrast to pI and paQ, the activity of the third CII-dependent promoter, pE, devoid of neighbouring downstream GATC sequences, was not affected by SeqA both in vivo and in vitro. We conclude that SeqA stimulates transcription from pI and paQ promoters in co-operation with CII by facilitating functions of this transcription activator, most probably by allowing more efficient binding of CII to the promoter region.

SeqA, the Escherichia coli origin sequestration protein, is also a specific transcription factor

The SeqA protein is a negative regulator of initiation of DNA replication in the Escherichia coli chromosome. Here, we demonstrate that SeqA stimulates transcription from the bacteriophage lambda pR promoter both in vivo and in vitro. The activity of the lambda pL promoter was found not to be affected by this protein. SeqA-mediated stimulation of pR was dependent on the state of template methylation: transcription was activated on fully methylated and hemimethylated templates but not on an unmethylated template. Using electrophoretic mobility shift assay and electron microscopy, we demonstrated that SeqA interacts specifically with a pR promoter region located on both fully methylated and hemimethylated DNA molecules, but not on unmethylated DNA. The activity of SeqA was found to affect the initiation of lambda plasmid replication positively in vivo, probably via pR-dependent expression of lambda replication genes and transcriptional activation of ori lambda. We conclude that, apart from its function in the control of DNA replication, SeqA is also a specific transcription factor.

Bacteriophage lambda cIII gene product has an additional function apart from inhibition of cII degradation

For lysogenization of Escherichia coli cells by bacteriophage lambda, functions of three lambda genes called c are necessary. The cI gene codes for a repressor that blocks activities of lytic promoters. However, early after infection, expression of cI is dependent on the function of the cII gene, coding for a specific transcriptional activator. The cII protein is unstable in E. coli cells due to FtsH-mediated proteolysis. The cIII gene product is an inhibitor of the FtsH protease. Here we demonstrate that cIII may have another function apart from inhibition of cII degradation. We found that overexpression of the cII gene results in impaired lysogenization by phage lambda, however simultaneous overexpression of the cIII gene abolished this negative effect on lysogenization. Analysis of cII-mediated transcriptional activation of certain promoters at different levels of cII and cIII proteins in cells confirmed that observed effects cannot be explained assuming that the only role of cIII is inhibition of FtsH-mediated degradation of cII. We propose that cIII has an additional role apart from its well-known function in indirect stabilization of cII. Apparently, cIII influences not only cII level but also activity of this transcriptional stimulator, especially at its high concentrations.

Regulation of bacteriophage lambda development by guanosine 5'-diphosphate-3'-diphosphate

On infection of its host, Escherichia coli, bacteriophage lambda can follow one of two alternative developmental pathways: lytic or lysogenic. Here we demonstrate that the "lysis-versus-lysogenization" decision is influenced by guanosine tetraphosphate (ppGpp), a nucleotide that is synthesized in E. coli cells in response to amino acid or carbon source starvation. We found that the efficiency of lysogenization is the highest at ppGpp concentrations somewhat higher than the basal level; too low and too high levels of ppGpp result in less efficient lysogenization. Maintenance of the already integrated lambda prophage and phage lytic development were not significantly influenced in the host lacking ppGpp. We found that the level of HflB/FtsH protease, responsible for degradation of the CII protein, an activator of "lysogenic" promoters, depends on ppGpp concentration. The highest levels of HflB/FtsH was found in bacteria lacking ppGpp and in cells bearing increased concentrations of this nucleotide. Using lacZ fusions, we investigated the influence of ppGpp on activities of lambda promoters important at the stage of the lysis-versus-lysogenization decision. We found that each promoter is regulated differentially in response to the abundance of ppGpp. Moreover, our results suggest that the cAMP level may influence ppGpp concentration in cells. The mechanism of the ppGpp-mediated control of lambda development at the stage of the lysis-versus-lysogenization decision may be explained on the basis of differential influence of guanosine tetraphosphate on activities of p(L), p(R), p(E), p(I), and p(aQ) promoters and by dependence of HflB/FtsH protease level on ppGpp concentration.

The C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase is required for efficient rho-dependent transcription termination

We screened a collection of single alanine residue substitution mutants spanning the entire C-terminal domain of the alpha subunit (alphaCTD) of Escherichia coli RNA polymerase (RNAP) for defects in rho-dependent transcription termination at lambdatR1 in vivo and in vitro, and thereby identified a patch of amino acid residues in the alphaCTD required for efficient rho-dependent termination. NusA addition led to the stimulation of rho-dependent termination under our conditions in vitro. The termination defects of a few mutant RNAPs could be attributed to altered interactions with the NusA protein, but rho-dependent termination by most of the defective RNAPs was still stimulated normally by NusA. The NusA-enhanced transcription pausing behaviors of the mutant RNAPs did not always correlate with their rho-dependent termination phenotypes. We conclude that the alphaCTD is a target for interactions with NusA that influence both termination and pausing, but in addition it participates in rho-dependent transcription termination in a NusA-independent manner.

Escherichia coli dnaA gene function and bacteriophage lambda replication

Allele specificity of the Escherichia coli dnaA gene function in the replication of plasmids derived from bacteriophage lambda has been demonstrated previously. Here, using a series of dnaA temperature-sensitive mutants, we investigated dnaA allele specificity of the replication of phages lambda P+ and lambda Pts 1 pi A66. We found that phage lambda P+ produces its progeny efficiently at 43 degrees C irrespective of the dnaA allele, whereas lambda Pts 1 pi A66, which is unable to develop lytically in the dnaA+ host at this temperature, can replicate with different efficiency in certain dnaA mutants. Since the main role of DnaA in lambda development seems to be stimulation of transcription from the pR promoter, we measured the activity of this promoter (using a pR-lacZ fusion) and the abundance of pR-derived transcripts (by Northern blotting analysis) in dnaA+ host and dnaA(ts) mutants at 30 and 43 degrees C. We found significant differences in the activity of pR in various dnaA(ts) mutants at 30 degrees C, which indicate different levels of stimulation of this promoter by products of particular dnaA alleles at permissive temperature. Differential levels of DnaA-mediated stimulation of pR in various dnaA(ts) mutants were also found at 43 degrees C. Stimulation of the pR promoter by DnaA is necessary for both efficient production of the lambda replication proteins, O and P, and effective transcriptional activation of ori lambda. The differences in the efficiency of pR activation observed in dnaA mutants at 30 and 43 degrees C can explain the mechanisms of allele specificity of dnaA gene function in the replication of bacteriophage lambda and plasmids derived from this phage.

DnaA-mediated regulation of phage lambda-derived replicons in the absence of pR and Cro function

Bacteriophage lambda-derived replicons can replicate in Escherichia coli cells as plasmids. In the control of replication of these plasmids, an important role was ascribed to the lambda Cro repressor autoregulatory loop. However, the oR/pR-cro-tR-cII' region could be replaced by the ptetA promoter under the control of the TetR repressor, producing plasmid pTClambda. Here, we demonstrate that stable maintenance of pTClambda depends on the host DnaA function because deletion of one of DnaA-binding sequences present in pTClambda resulted in a decrease in the plasmid (pTClambda) copy number and poor maintenance of pTClambda in E. coli. Moreover, in contrast to the replication of the wild-type lambda plasmid, previously found to be positively regulated by DnaA (acting on a relaxed DnaA box situated immediately downstream of the pR promoter), the replication of pTC plasmids (devoid of pR) was found to be negatively regulated by DnaA. Contrary to wild-type lambda plasmids, in cells harboring lambda cro[temperature-sensitive (ts)] or pTClambda (but not pTClambda) plasmid, the lambda replication complex was heat shock resistant; this complex, however, disassembled after inactivation of DnaA function. This disassembly was blocked by DNA gyrase inhibitors. According to our model outlined previously, we propose that the heat shock resistance of the replication complex of lambdacro- plasmids depends on the interaction of the DNA-bound DnaA protein with the DNA-bound lambda replication complex. The replication complex-DnaA-lambda DNA structure may be directly related to the role of DnaA as the Cro-replacing negative regulator of lambdacro- plasmid replication.

Excess production of phage lambda delayed early proteins under conditions supporting high Escherichia coli growth rates

Bacteriophage lambda is unable to lysogenize Escherichia coli hosts harbouring the rpoA341 mutation due to a drastic reduction in transcription from CII-activated lysogenic promoters (pE, pI and paQ). In addition, the level of early transcripts involved in the lytic pathway of lambda development is also decreased in this genetic background due to impaired N-dependent antitermination. Here, it is demonstrated that despite the reduced level of early lytic pL- and pR-derived transcripts, lytic growth of bacteriophage lambda is not affected in rich media. The level of the late lytic, pR-derived transcripts also remains unaffected by the rpoA341 mutation under these conditions. However, it was found that whilst there is no significant difference in the phage burst size in rpoA+ and rpoA341 hosts growing in rich media, phage lambda is not able to produce progeny in the rpoA341 mutant growing in minimal medium, in contrast to otherwise isogenic rpoA+ bacteria. Provision of an excess of the phage replication proteins O and P in trans or overproduction of the antitermination protein N restore the ability of phage lambda to produce progeny in the rpoA341 mutant under the latter conditions. These results suggest that in rich media phage lambda produces some early proteins in excess of that needed for its effective propagation and indicate that replication proteins may be limiting factors for phage lytic growth in poor media.

Replication of lambda plasmid DNA in the Escherichia coli cell cycle

The Cro repressor autoregulatory loop has long been considered the main regulatory process in controlling lambda plasmid replication initiation in Escherichia coli. However, we found recently that lambda plasmids can be maintained at a constant copy number in the absence of Cro function. Here we demonstrate that shortly after inactivation of the Cro repressor, the synthesis of lambda plasmid DNA increases significantly but is then stabilized at a level similar to that observed in the presence of the Cro function. We found that replication initiation of lambda plasmids carrying a functional cro gene proceeds randomly in the host cell cycle, but in the absence of Cro function the replication initiation of lambda plasmid DNA appears to be cell cycle dependent. The host DnaA protein appears to be at least one of the factors involved in the cell-cycle-specific control of lambda cro- plasmid replication. Therefore, it seems that the lambda cro- plasmid may serve as an amazingly simple model for studies on the regulation of DNA replication in the cell cycle.

Polyadenylation of oop RNA in the regulation of bacteriophage lambda development

We have shown that Escherichia coli pcnB mutants are lysogenized by bacteriophage lambda with lower efficiency as compared to the pcnB+ strains. Our genetic analysis revealed that expression of the lambda cII gene is decreased in the pcnB mutants. However, using various lacZ fusions we demonstrated that neither activities of pL and pR promoters nor transcription termination at tR1 were significantly impaired in the pcnB- host. On the other hand, we found that oop RNA, an antisense RNA for cII expression, is involved in this regulation. Primer protection experiments revealed that oop RNA was polyadenylated and that this polyadenylation was impaired in the pcnB mutant. We found that the oop RNA was more abundant in the pcnB mutant than in the pcnB+ strain. Furthermore, we showed that activity of the pO promoter was not stimulated in the pcnB mutant. Such findings indicated that degradation of oop RNA in the pcnB strain was slower because of inefficient polyadenylation, which could lead to more effective inhibition of cII expression by the antisense oop RNA, resulting in less efficient lysogenization of the host. The oop RNA was found previously to play a role in phage lambda development only under conditions of overproduction of this transcript. Here we demonstrate for the first time, the physiological function of oop RNA in lambda development, confirming that this short transcript plays an important role in the negative regulation of cII gene expression during lambda infection. Moreover, polyadenylation of oop RNA is one of very few known examples of specific RNA polyadenylation by PAP I in prokaryotic cells and its role in gene expression regulation.

Molecular mechanism of heat shock-provoked disassembly of the coliphage lambda replication complex

We have found previously that, in contrast to the free O initiator protein of lambda phage or plasmid rapidly degraded by the Escherichia coli ClpP/ClpX protease, the lambdaO present in the replication complex (RC) is protected from proteolysis. However, in cells growing in a complete medium, a temperature shift from 30 to 43 degrees C resulted in the decay of the lambdaO fraction, which indicated disassembly of RC. This process occurred due to heat shock induction of the groE operon, coding for molecular chaperones of the Hsp60 system. Here we demonstrate that an increase in the cellular concentration of GroEL and GroES proteins is not in itself sufficient to cause RC disassembly. Another requirement is a DNA gyrase-mediated negative resupercoiling of lambda plasmid DNA, which counteracts DNA relaxation and starts to dominate 10 min after the temperature upshift. We presume that RC dissociates from lambda DNA during the negative resupercoiling, becoming susceptible to the subsequent action of GroELS and ClpP/ClpX proteins. In contrast to lambda cro+, in lambda cro- plasmid-harboring cells, the RC reveals heat shock resistance. After temperature upshift of the lambda crots plasmid-harboring cells, a Cro repressor-independent control of lambda DNA replication and heat shock resistance of RC are established before the period of DNA gyrase-mediated negative supercoiling. We suggest that the tight binding of RC to lambda DNA is due to interaction of RC with other DNA-bound proteins, and is related to the molecular basis of the lambda cro- plasmid replication control.

Studies on the NusB protein of Escherichia coli--expression and determination of secondary-structure elements by multinuclear NMR spectroscopy

The product of the nusB gene of Escherichia coli modulates the efficiency of transcription termination at nut (N utilization) sites of various bacterial and bacteriophage lambda genes. Similar control mechanisms operate in eukaryotic viruses (e.g. human immunodeficiency virus). A recombinant strain of E. coli producing relatively large amounts of NusB protein (about 10% of cell protein) was constructed. The protein could be purified with high yield by anion-exchange chromatography followed by gel-permeation chromatography. The protein is a monomer of 15.6 kDa as shown by analytical ultracentrifugation. Structural studies were performed using protein samples labelled with 15N, 13C and 2H in various combinations. Heteronuclear three-dimensional triple-resonance NMR experiments combined with a semi-automatic assignment procedure yielded the sequential assignment of the 1H, 13C and 15N backbone resonances. Based on experimentally derived scalar couplings, chemical-shift values, amide-exchange data, and a semiquantitative interpretation of NOE data, the secondary structure of NusB has classified as alpha helical, comprising seven alpha helices.