Early gene expression in bacteriophage T7. I. In vivo synthesis, inactivation, and translational utilization of early mRNA's

Genetic optimization of a bacteriophage-delivered alkaline phosphatase reporter to detect Escherichia coli

A large fraction of foodborne illnesses are linked to (∼46%) leafy green vegetables contaminated by pathogens harbored in agricultural water. To prevent this, accurate point-of-production detection tools are required to identify and quantify bacterial contaminants in produce before consumers are impacted. In this study, a proof-of-concept model was engineered for a phage-based Escherichia coli detection system. We engineered the coliphage T7 to express alkaline phosphatase (ALP) to serve as the signal for E. coli detection. Wild type phoA (T7ALP) and a dominant-active allele, phoA D153G D330N (T7ALP*) was inserted into the T7 genome, with engineered constructs selected by CRISPR-mediated cleavage of unaltered chromosomes and confirmed by PCR. Engineered phages and E. coli target cells were co-incubated for 16 hours to produce lysates with liberated ALP correlated with input cell concentrations. A colorimetric assay used p-nitrophenyl phosphate (pNPP) to demonstrate significant ALP production by T7ALP and T7ALP* compared to the vector control (T7EV) (p≤ 0.05). Furthermore, T7ALP* produced 2.5-fold more signal than T7ALP (p≤ 0.05) at pH 10. Due to the increase in signal for the modified ALP* allele, we assessed T7ALP* sensitivity in a dose-responsive manner. We observed 3-fold higher signal for target cell populations as low as ∼2 × 10(5) CFU mL(-1) (p≤ 0.05 vs. no-phage control).

Expression of each cistron in the gal operon can be regulated by transcription termination and generation of a galk-specific mRNA, mK2

The gal operon of Escherichia coli has 4 cistrons, galE, galT, galK, and galM. In our previous report (H. J. Lee, H. J. Jeon, S. C. Ji, S. H. Yun, H. M. Lim, J. Mol. Biol. 378: 318-327, 2008), we identified 6 different mRNA species, mE1, mE2, mT1, mK1, mK2, and mM1, in the gal operon and mapped these mRNAs. The mRNA map suggests a gradient of gene expression known as natural polarity. In this study, we investigated how the mRNAs are generated to understand the cause of natural polarity. Results indicated that mE1, mT1, mK1, and mM1, whose 3' ends are located at the end of each cistron, are generated by transcription termination. Since each transcription termination is operating with a certain frequency and those 4 mRNAs have 5' ends at the transcription initiation site(s), these transcription terminations are the basic cause of natural polarity. Transcription terminations at galE-galT and galT-galK junctions, making mE1 and mT1, are Rho dependent. However, the terminations to make mK1 and mM1 are partially Rho dependent. The 5' ends of mK2 are generated by an endonucleolytic cleavage of a pre-mK2 by RNase P, and the 3' ends are generated by Rho termination 260 nucleotides before the end of the operon. The 5' portion of pre-mK2 is likely to become mE2. These results also suggested that galK expression could be regulated through mK2 production independent from natural polarity.

An unstructured mRNA region and a 5' hairpin represent important elements of the E. coli translation initiation signal determined by using the bacteriophage T7 gene 1 translation start site

Gene 1 of bacteriophage T7 early region--the RNA polymerase gene--is very actively translated during the infectious cycle of this phage. A 29 base pair fragment of its ribosome binding site containing the initiation triplet, the Shine-Dalgarno sequence (S-D), 10 nucleotides (nt) upstream and 6 nt downstream of these central elements was cloned into a vector to control the expression of the mouse dihydrofolate reductase gene (dhfr). Although all essential parts of this translation initiation region (TIR) should be present, this fragment showed only very low activity. Computer analysis revealed a potentially inhibitory hairpin binding the S-D sequence into its stem base paired to vector-derived upstream sequences. Mutational alterations demonstrated that this hairpin was not responsible for the low activity. However, addition of 21 nt of the T7 gene 1 upstream sequence to the 29 base pair fragment were capable of increasing the translational efficiency by one order of magnitude. Computer analysis of this sequence, including nucleotide shuffling, revealed that it contains a highly unstructured region lacking mRNA secondary structures but with a hairpin at its 5' end, here formed solely by T7 sequences. There was not much difference in activity whether the mRNA included or lacked vector-derived sequences upstream of the hairpin. Such highly unstructured mRNA regions were found in all very efficiently expressed T7 genes without any obvious sequence homologies. The delta G values of these regions were higher, i.e. potential secondary structural elements were fewer, than in TIR of genes from E. coli. This is likely due to the fact that T7 as a lytic phage is relying for successful infection on much stronger signals which a cell cannot afford because of the indispensable balanced equilibria of its interdependent biochemical processes. When the 5' ends of efficient T7 gene mRNA are formed by the action of RNase III they generally start with an unstructured region. Efficiently expressed T7 genes within a polycistronic mRNA, however, always contain a hairpin preceding the structure free sequence. We suggest that the formation of this 5' hairpin is releasing enough energy to keep the unstructured regions free of secondary RNA structures for sufficient time to give ribosomes and factors a good chance for binding to the TIR. In addition, sequences further downstream of the start codon give rise to an additional increase in efficiency of the TIR by almost two orders of magnitude.

Differential stimulation by polyamines of phage DNA-directed in vitro synthesis of proteins

The effect of polyamines on T7- and lambda rifd18 DNA-directed synthesis of proteins in an Escherichia coli cell-free system has been studied. When T7 DNA was used as a template, the degree of stimulation by spermidine of protein synthesis was larger with T7 RNA polymerase than with Mr 42 K protein, while the synthesis of Mr 13.5 K protein was not stimulated significantly by spermidine. The synthesis of T7 RNA polymerase was stimulated approx. 10-fold by 1 mM spermidine. When lambda rifd18 DNA was used as a template, the synthesis of beta beta' subunits of RNA polymerase was stimulated greatly by spermidine, while the synthesis of elongation factor Tu and ribosomal proteins was not stimulated significantly by spermidine. Spermidine stimulation of T7 DNA-directed synthesis of T7 RNA polymerase was at the level of both translation and transcription. The degree of stimulation by spermidine was greater at the level of translation. Putrescine stimulated the synthesis of T7 RNA polymerase and Mr 42 K protein to a small degree at the level of translation.

Termination of transcription of the coliphage T7 "early" operon in vitro: slowness of enzyme release, and lack of any role for sigma

The leftmost portion of the coliphage T7 genome is transcribed by the RNA polymerase Escherichia coli immediately after infection. This "early" operon is delineated by three promoters on the left, and a transcriptional terminator on the right. The terminator is efficient both in vivo, and with highly purified RNA polymerase in vitro. We have studied termination in vitro, using synchronously initiated transcription reactions with low enzyme:DNA ratios. We show that recognition of the stop signal and release of RNA product are relatively rapid. Dissociation of the enzyme from the DNA is quite slow, and probably rate-limiting for re-cycling of the polymerase. It is well established that the sigma subunit of RNA polymerase is required for specific initiation, but redundant during RNA elongation. By exploiting antisigma antiserum we have obtained evidence that sigma is also redundant during all steps of termination in vitro.

Altered transcriptional termination in a rifampicin-resistant mutant of Escherichia coli which inhibits the growth of bacteriophage T7

A spontaneous rifampicin-resistant mutant of E. coli K12, RpoB26, which inhibits the growth of bacteriophage T7 has been isolated. The mutation is an RNA polymerase mutation; it also restores the wild-type effect of polar mutations in a rho-deficient strain, probably by restoring transcriptional termination. The efficiency of plating (e.o.p.) of wild-type T7, and of some early region deletion and point mutants of T7 tested, is reduced on RpoB26 by a factor of 10(-4). However, some deletion mutants are inhibited more severely (up to 10(-7) on RpoB26. We argue that these differences may reflect variations in the frequency of transcriptional termination before gene 1, an essential gene which codes for the T7 RNA polymerase (Summers and Siegel 1970; Chamberlin et al. 1970). We also present data which suggest that the product of a late T7 gene plays a role, by some interaction with the product of gene 1, in the inhibition of T7 in RpoB26. We suggest that different levels of expression of gene 1 may lead to different degrees of inhibition of T7 strains in RpoB26.

Control sites in the sequence at the beginning of T7 gene 1

The DNA sequence of the fragment Hind.30, 378 bases long, from the beginning of gene 1 of T7 is presented. It contains the C promoter, two in vitro transcriptional terminator sites and a sequence of 171 bases which probably codes for the N terminus of the T7 RNA polymerase. The sequence also codes for the RNase III cleavage site before gene 1. The overlaps with the transcriptional terminators, The RNA transcript of the sequence about the terminators can be arranged in a set of alternative double-stranded hairpin structures. It is suggested that conversion between these structures may have a role in termination; this may be influenced by interactions with ribosomes and RNase III. The region of the C promoter between genes 0.7 and 1 thus contains several sites which may be involved in the control of transcription and translation.

The DNA sequence at the T7 C promoter

Restriction fragments of T7 DNA which selectively bind E. coli RNA polymerase have been identified. These include fragments located close to the beginning of gene 1 where according to Minkley and Pribnow (1973) there is a promoter called C. The smallest fragment from this region which binds RNA polymerase has been sequenced. It contains a promoter-like sequence, at an appropriate distance from the sequence TACA which Minkley and Pribnow suggested should lie at the initiation site of C. RNA synthesised in vitro from these fragments has been sequenced. The RNA sequence corresponds to the sequence to the right of the C promoter. The C promoter differs significantly from the A1 A2 and A3 promoters in sequence. Its structure and position suggest it plays a role in T7 infection.

Restriction enzyme cleavage mapping of T7 virus early region

DNA molecules of seven T7 mutants with overlapping deletions in the early region were cleaved by restriction enzymes HindII, HpaI and II, and HaeIII. The differences in the cleavage patterns after electrophoresis have been used to generate a cleavage map of the restriction sites of this enzyme. It covers the first 9% of the T7 DNA molecule. Cleavage points for HindII are at 0.60, 1.33, 1.59, 1.76, 5.26, 6.27, 7.4 and 8.38%; for HpaI and II at 1.36, 1.62, 4.46, 6.29, 6.62, 7.56, and 8.76%, for HaeIII at 3.85, 6.98, 7.88 and 8.26%. Some fragments have been located in the region containing the early promoters, others carry the complete sequences of gene 0.3.

Effects of ultraviolet irradiation and postirradiation incubation on heterogenous nuclear RNA size in murine cells

We have analyzed the decrease in synthesis of individual size classes of heterogeneous nuclear RNA (hnRNA) in ultraviolet (UV)-irradiated Merwin plasmacytoma (MPC-11) cells at various times of postirradiation incubation. HnRNA from nonirradiated control cells is distributed over a wide range from approximately 60S to 5S, with 42S RNA carrying more label than any other size class. HnRNA from UV-irradiated cells shows a dose-dependent shift in size distribution toward lower molecular weight. The size distribution of hnRNA synthesized after prolonged times of postirradiation incubation is restored toward normal, i.e., synthesis of long RNA molecules increases relative to the synthesis of short ones. Analysis of the total number of hnRNA chains synthesized during a 20-min [(3)H]uridine pulse shows a considerable reduction in their number with increasing UV dose. Murine cell lines are excision-repair-deficient but capable of post replication repair inhibited by caffeine. HnRNA transcripts of cells incubated in its presence were studied. The caffeine, which has no effect on hnRNA size in control cells, inhibits to a considerable extent the restoration of full-length transcripts during postirradiation incubation. The lack of excision repair in MPC-11 was confirmed by the analysis of pyrimidine dimers in trichloracetic acid-insoluble and soluble fractions within 8 h of postirradiation incubation.The size of parental and daughter strand DNA in UV-irradiated cells was correlated with RNA transcript size. The parental DNA in these experiments does not change its size as a consequence of UV exposure and postirradiation incubation. In contrast, daughter DNA strands are short in UV-irradiated cells and they increase in size during postirradiation incubation to reach the size of parental strands after 8 h.

Active protection by bacteriophages T3 and T7 against E. coli B- and K-specific restriction of their DNA

The bacteriophages T3 and T7 are not modified and restricted by E. coli strains with different host specificity (E. coli B, K, O) in vivo. The phages code for a gene product with the ability to overcome classical restriction (ocr): ocr- mutants are subject to modification and restriction via DNA methylation vs cleavage. The T3 genome possesses recognition sites for the restriction endonuclease R.EcoB which, unless the DNA is B-specifically modified, trigger 5-7 DNA cleavages. The ocr gene function of T3 and T7 is located within the gene 0.3 region of these phages and is not identical with the sam (SAMase) function of T3. The mechanism of ocr protection remains unclear, while it is certain that this protection by the gene 0.3 protein is exerted in the infected cell and not through "over-all" modification in the preceding growth cycle of the phage.

Nucleotide sequence surrounding a ribonuclease III processing site in bacteriophage T7 RNA

We have determined a nucleotide seuqence of 87 residues surrounding a ribonuclease III (endoribonuclease III; EC 3.1.4.24) processing site in the bacteriophage T7 intercistronic region between early genes 0.3 and 0.7. The structural requirements necessary for proper recognition and cleavage by RNase III are discussed. In addition, other structural features characteristic of this intercistronic boundary are described.

Utilization of early promotors in mutant far P85 of bacteriophage T4

We show that farP85 is a recessive mutant of T4 incapable of activating the delayed early promotors for genes 43 and 45 and that the farP85 mutation is in the same complementation group as the ts G1 mutation, which is located in the "modifier of transcription" (mot) gene.