RNA initiation with dinucleoside monophosphates during transcription of bacteriophage T4 DNA with RNA polymerase of Escherichia coli

Promoter-sequence determinants and structural basis of primer-dependent transcription initiation in Escherichia coli

Chemical modifications of RNA 5'-ends enable "epitranscriptomic" regulation, influencing multiple aspects of RNA fate. In transcription initiation, a large inventory of substrates compete with nucleoside triphosphates for use as initiating entities, providing an ab initio mechanism for altering the RNA 5'-end. In Escherichia coli cells, RNAs with a 5'-end hydroxyl are generated by use of dinucleotide RNAs as primers for transcription initiation, "primer-dependent initiation." Here, we use massively systematic transcript end readout (MASTER) to detect and quantify RNA 5'-ends generated by primer-dependent initiation for ∼410 (∼1,000,000) promoter sequences in E. coli The results show primer-dependent initiation in E. coli involves any of the 16 possible dinucleotide primers and depends on promoter sequences in, upstream, and downstream of the primer binding site. The results yield a consensus sequence for primer-dependent initiation, YTSS-2NTSS-1NTSSWTSS+1, where TSS is the transcription start site, NTSS-1NTSS is the primer binding site, Y is pyrimidine, and W is A or T. Biochemical and structure-determination studies show that the base pair (nontemplate-strand base:template-strand base) immediately upstream of the primer binding site (Y:RTSS-2, where R is purine) exerts its effect through the base on the DNA template strand (RTSS-2) through interchain base stacking with the RNA primer. Results from analysis of a large set of natural, chromosomally encoded Ecoli promoters support the conclusions from MASTER. Our findings provide a mechanistic and structural description of how TSS-region sequence hard-codes not only the TSS position but also the potential for epitranscriptomic regulation through primer-dependent transcription initiation.

Real-time observation of polymerase-promoter contact remodeling during transcription initiation

Critical contacts made between the RNA polymerase (RNAP) holoenzyme and promoter DNA modulate not only the strength of promoter binding, but also the frequency and timing of promoter escape during transcription. Here, we describe a single-molecule optical-trapping assay to study transcription initiation in real time, and use it to map contacts formed between σ⁷⁰ RNAP holoenzyme from E. coli and the T7A1 promoter, as well as to observe the remodeling of those contacts during the transition to the elongation phase. The strong binding contacts identified in certain well-known promoter regions, such as the −35 and −10 elements, do not necessarily coincide with the most highly conserved portions of these sequences. Strong contacts formed within the spacer region (−10 to −35) and with the −10 element are essential for initiation and promoter escape, respectively, and the holoenzyme releases contacts with promoter elements in a non-sequential fashion during escape.

Contacts between RNA polymerase and promoter DNA modulate the strength of binding and the frequency of promoter escape during transcription. Here, the authors describe a single molecule optical-trapping assay to study transcription initiation and observe the dynamic remodeling of enzyme contacts in real time.

A Conserved Pattern of Primer-Dependent Transcription Initiation in Escherichia coli and Vibrio cholerae Revealed by 5' RNA-seq

Transcription initiation that involves the use of a 2- to ~4-nt oligoribonucleotide primer, “primer-dependent initiation,” (PDI) has been shown to be widely prevalent at promoters of genes expressed during the stationary phase of growth in Escherichia coli. However, the extent to which PDI impacts E. coli physiology, and the extent to which PDI occurs in other bacteria is not known. Here we establish a physiological role for PDI in E. coli as a regulatory mechanism that modulates biofilm formation. We further demonstrate using high-throughput sequencing of RNA 5′ ends (5′ RNA-seq) that PDI occurs in the pathogenic bacterium Vibrio cholerae. A comparative global analysis of PDI in V. cholerae and E. coli reveals that the pattern of PDI is strikingly similar in the two organisms. In particular, PDI is detected in stationary phase, is not detected in exponential phase, and is preferentially apparent at promoters carrying the sequence T₋₁A₊₁ or G₋₁G₊₁ (where position +1 corresponds to the position of de novo initiation). Our findings demonstrate a physiological role for PDI and suggest PDI may be widespread among Gammaproteobacteria. We propose that PDI in both E. coli and V. cholerae occurs though a growth phase-dependent process that leads to the preferential generation of the linear dinucleotides 5´-UA-3´ and 5´-GG-3´.

Primer-dependent transcription initiation, PDI, refers to an alternative mechanism of transcription initiation whereby the first phosphodiester bond within the nascent RNA is formed between a 2- to ~4-nt RNA primer and an incoming nucleoside triphosphate. Although PDI has been shown to occur in E. coli, the impact of PDI on E. coli physiology, and the extent to which PDI occurs in other bacteria is unknown. Here we establish that PDI modulates the ability of E. coli to form biofilms, a surface attached community of bacteria encased in a polymeric matrix. We further describe a significantly improved RNA-seq based method for the detection of PDI in cells. Using this method we document the occurrence of PDI in the pathogenic bacterium Vibrio cholerae. We further show that the pattern of PDI in V. cholerae is identical to that observed in E. coli, suggesting that PDI in these two organisms may occur through a conserved process that produces identical populations of 2- to ~4-nt RNA primers. Our findings suggest PDI may be widespread in Gammaproteobacteria.

The transcription bubble of the RNA polymerase-promoter open complex exhibits conformational heterogeneity and millisecond-scale dynamics: implications for transcription start-site selection

Bacterial transcription is initiated after RNA polymerase (RNAP) binds to promoter DNA, melts ~14 bp around the transcription start site and forms a single-stranded "transcription bubble" within a catalytically active RNAP-DNA open complex (RP(o)). There is significant flexibility in the transcription start site, which causes variable spacing between the promoter elements and the start site; this in turn causes differences in the length and sequence at the 5' end of RNA transcripts and can be important for gene regulation. The start-site variability also implies the presence of some flexibility in the positioning of the DNA relative to the RNAP active site in RP(o). The flexibility may occur in the positioning of the transcription bubble prior to RNA synthesis and may reflect bubble expansion ("scrunching") or bubble contraction ("unscrunching"). Here, we assess the presence of dynamic flexibility in RP(o) with single-molecule FRET (Förster resonance energy transfer). We obtain experimental evidence for dynamic flexibility in RP(o) using different FRET rulers and labeling positions. An analysis of FRET distributions of RP(o) using burst variance analysis reveals conformational fluctuations in RP(o) in the millisecond timescale. Further experiments using subsets of nucleotides and DNA mutations allowed us to reprogram the transcription start sites, in a way that can be described by repositioning of the single-stranded transcription bubble relative to the RNAP active site within RP(o). Our study marks the first experimental observation of conformational dynamics in the transcription bubble of RP(o) and indicates that DNA dynamics within the bubble affect the search for transcription start sites.

A new way to start: nanoRNA-mediated priming of transcription initiation

A recent study provides evidence that RNA polymerase uses 2- to ~4-nt RNAs, species termed "nanoRNAs," to prime transcription initiation in Escherichia coli. Priming of transcription initiation with nanoRNAs represents a previously undocumented component of transcription start site selection and gene expression.

NanoRNAs prime transcription initiation in vivo

It is often presumed that, in vivo, the initiation of RNA synthesis by DNA-dependent RNA polymerases occurs using NTPs alone. Here, using the model Gram-negative bacterium Pseudomonas aeruginosa, we demonstrate that depletion of the small-RNA-specific exonuclease, Oligoribonuclease, causes the accumulation of oligoribonucleotides 2 to ∼4 nt in length, "nanoRNAs," which serve as primers for transcription initiation at a significant fraction of promoters. Widespread use of nanoRNAs to prime transcription initiation is coupled with global alterations in gene expression. Our results, obtained under conditions in which the concentration of nanoRNAs is artificially elevated, establish that small RNAs can be used to initiate transcription in vivo, challenging the idea that all cellular transcription occurs using only NTPs. Our findings further suggest that nanoRNAs could represent a distinct class of functional small RNAs that can affect gene expression through direct incorporation into a target RNA transcript rather than through a traditional antisense-based mechanism.

NanoRNAs: a class of small RNAs that can prime transcription initiation in bacteria

It has been widely assumed that all transcription in cells occur using NTPs only (i.e., de novo). However, it has been known for several decades that both prokaryotic and eukaryotic RNA polymerases can utilize small (2 to ∼5 nt) RNAs to prime transcription initiation in vitro, raising the possibility that small RNAs might also prime transcription initiation in vivo. A new study by Goldman et al. has now provided the first evidence that priming with so-called "nanoRNAs" (i.e., 2 to ∼5 nt RNAs) can, in fact, occur in vivo. Furthermore, this study provides evidence that altering the extent of nanoRNA-mediated priming of transcription initiation can profoundly influence global gene expression. In this perspective, we summarize the findings of Goldman et al. and discuss the prospect that nanoRNA-mediated priming of transcription initiation represents an underappreciated aspect of gene expression in vivo.

Nucleotide sequence and transcriptional analysis of the redD locus of Streptomyces coelicolor A3(2)

Previous genetic evidence suggested that the redD gene product might be involved in the regulation of undecylprodigiosin (Red) biosynthesis in Streptomyces coelicolor. The redD+ gene was subcloned on a 2.2-kilobase-pair restriction fragment from the S. coelicolor redCD region by complementation of S. coelicolor JF1 (redD42). The DNA sequence of the 2.2-kilobase-pair redD-complementing region was determined, and the redD coding sequence was identified by computer analysis and deletion subcloning. Transcription at the redD locus was analyzed by using in vivo promoter probing, high resolution S1 mapping, and in vitro runoff transcription. A face-to-face arrangement of promoters was deduced, in which the proposed redD promoter was opposed by a cluster of four other promoters for another unidentified open reading frame. In time course experiments, redD transcription preceded that at two biosynthetic loci, redE and redBF; transcription at the latter two loci was reduced in redD42 mutants. The putative redD polypeptide lacked any strong sequence similarities to other known proteins.

The agarase gene (dagA) of Streptomyces coelicolor A3(2): nucleotide sequence and transcriptional analysis

The DNA sequence of a 1.77 kb region of the Streptomyces coelicolor chromosome containing the coding and regulatory regions of the extracellular agarase (dagA) gene was determined. The sequence predicts a primary translation product of 309 amino acids and Mr 35132. Comparison of the N-terminal sequence determined for the mature extracellular protein with that of the primary translation product deduced from the DNA sequence predicts the presence of a 30 amino acid signal peptide. Analysis of the transcription of the dagA gene using high resolution S1 mapping, in vitro transcription, dinucleotide-primed in vitro transcription and in vivo promoter probing identified four promoters, initiating transcription approximately 32, 77, 125 and 200 nucleotides upstream of the coding sequence.

Oligonucleotides complementary to a promoter over the region -8...+2 as transcription primers for E. coli RNA polymerase

Primer-dependent transcription by E. coli RNA polymerase on T7 promoter A2 has been studied. Synthetic deoxyribonucleotides complementary to the promoter over the region -8...+2 were taken as primers. A ribonucleoside residue was present at the 3'-end of some of these oligonucleotides. The octanucleotide complementary to the region -8...-1 appeared to be an active primer. Oligonucleotides having lengths from 3 to 6 nucleotide residues complementary to the promoter over the region -4...+2 also exhibited primer activity. The latter was some 5-10 times greater in the case of oligonucleotides having a ribonucleoside residue at the 3'-end. Oligonucleotides which on complementary binding do not reach the center of phosphodiester bond synthesis, as well as the decanucleotides (-8...+2) and octanucleotides (-6...+2) of both the ribo- and deoxyribo-series were inactive as primers.

Bacteriophage SPO1 gene 27: location and nucleotide sequence

Bacteriophage SPO1 gene 27, whose product is required for late gene transcription and DNA replication, has been cloned in Escherichia coli, and its complete nucleotide sequence has been determined. We infer that the product of gene 27 is a highly basic 17,518-dalton protein of 155 amino acids. The gene for this regulatory protein is transcribed from two promoters: an early promoter situated before the adjacent upstream gene 28 and a middle promoter located between genes 28 and 27.

Nucleotide sequences that signal the initiation of transcription and translation in Bacillus subtilis

We have determined the nucleotide sequence of two Bacillus subtilis promoters (veg and tms) that are utilized by the principal form of B. subtilis RNA polymerase found in vegetative cells (sigma 55-RNA polymerase) and have compared our sequences to those of several previously reported Bacillus promoters. Hexanucleotide sequences centered approximately 35 (the "--35" region) and 10 (the "--10" region) base pairs upstream from the veg and tms transcription starting points (and separated by 17 base pairs) corresponded closely to the consensus hexanucleotides (TTGACA and TATAAT) attributed to Escherichia coli promoters. Conformity to the preferred --35 and --10 sequences may not be sufficient to promote efficient utilization by B. subtilis RNA polymerase, however, since three promoters (veg, tms and E. coli tac) that conform to these sequences and that are utilized efficiently by E. coli RNA polymerase were used with highly varied efficiencies by B. subtilis RNA polymerase. We have also analyzed mRNA sequences in DNA located downstream from eight B. subtilis chromosomal and phage promoters for nucleotide sequences that might signal the initiation of translation. In accordance with the rules of McLaughlin, Murray and Rabinowitz (1981), we observe mRNA nucleotide sequences with extensive complementarity to the 3' terminal region of B. subtilis 16S rRNA, followed by an initiation codon and an open reading frame.

Mechanism of inhibition of Escherichia coli RNA polymerase by captan

Captan (N-trichloromethylthiocyclohex-4-ene-1,2-dicarboximide) was shown to inhibit RNA synthesis in vitro catalysed by Escherichia coli RNA polymerase. Incorporation of [gamma-32P]ATP and [gamma-32P]GTP was inhibited by captan to the same extent as overall RNA synthesis. The ratio of [3H]UTP incorporation to that of [gamma-32P]ATP or of [gamma-32P]GTP in control and captan-treated samples indicated that initiation was inhibited, but the length of RNA chains being synthesized was not altered by captan treatment. Limited-substrate assays in which re-initiation of RNA chains did not occur also showed that captan had no effect on the elongation reaction. Studies which measured the interaction of RNA polymerase with template DNA revealed that the binding of enzyme to DNA was inhibited by captan. Glycerol-gradient sedimentation of the captan-treated RNA polymerase indicated that the inhibition of the enzyme was irreversible and did not result in dissociation of its subunits. These data are consistent with a mechanism in which RNA polymerase activity was irreversibly altered by captan, resulting in an inability of the enzyme to bind to the template. This interaction was probably at the DNA-binding site on the polymerase and did not involve reaction of captan with the DNA template.

Nucleotide sequence of a Bacillus subtilis promoter recognized by Bacillus subtilis RNA polymerase containing sigma 37

We report the nucleotide sequence of the promoter for a Bacillus subtilis gene (spoVC) whose transcription is controlled by a 37,000 dalton species of B. subtilis sigma factor known as sigma 37 but not by the principal- sigma factor of 55,000 daltons (sigma 55). Using S1 nuclease mapping we show that the startpoint for sigma 37-directed transcription of the spoVC gene in vitro corresponded closely to the 5' terminus of in vivo synthesized spoVC RNA. The binding site for sigma 37-containing RNA polymerase extended from 43 bp to 51 bp (positions -43 to -51) upstream from the transcription startpoint to 22 bp (position +22) downstream from the startpoint. The nucleotide sequence of the spoVC promoter differed significantly from promoters whose recognition is controlled by sigma 55 but was similar to other sigma 37- controlled promoters in regions known to be important in promoter recognition. Our results are consistent with the hypothesis (Lee and Pero, J. Mol. Biol., in press) that sigma factors work by contacting specific bases in both the -35 and -10 regions of promoters.

Gel electrophoretic separation of transcription complexes: an assay for RNA polymerase selectivity and a method for promoter mapping

We describe a method for analyzing ternary transcription complexes, of RNA polymerase, DNA and nascent RNA32 chains, by agarose gel electrophoresis. When the RNA of such complexes is 32P-labelled, a simple comparison of the DNA fluorogram with an autoradiogram identifies transcriptionally active DNA molecules and restriction fragments in any mixture. Two limitations on the method are described: 1) retardation during electrophoresis of polymerase-DNA complexes relative to their conjugate bare NA fragments; 2) failure of very large ternary complexes to enter gels. The following potential applications of the method are surveyed: transcription unit (elongation) mapping, separation of RNA molecules in a mixture of transcripts, dinucleotide primer mapping and identification of preferred template conformations.

Metal mutagens and carcinogens affect RNA synthesis rates in a distinct manner

Five metal salts (lead, cadmium, cobalt, copper, and manganese),which are mutagenic or carcinogenic, decreasing the fidelity of DNA synthesis in vitro, stimulated chain initiation of RNA synthesis at concentrations that inhibited overall RNA synthesis. In contrast, other metal salts (zinc, magnesium, lithium, sodium,and potassium) not in this category inhibited chain initiation of RNA synthesis at concentrations that inhibited overall RNA synthesis.

On the mechanism of oligonucleotide-primed RNA synthesis. II. Synthesis of specific primer-initiated RNA copies suitable for DNA sequence analysis

The effect of temperature and primer concentration on oligonucleotide-primed transcription has been studied using the separated strands of a well-defined natural DNA as template. Results were similar to those obtained in the homopolymer-directed model systems. At high temperature and excess primer concentration mainly primer-initiated RNA copies are synthesized. Omission of one ribonucleoside triphosphate also makes the termination specific. The unique RNA fragments thus obtained have been used to determine the perfectly-repeated sequence of 68 base pairs in this DNA.

Influenza virion transcriptase: synthesis in vitro of large, polyadenylic acid-containing complementary RNA

The influenza virion transcriptase is capable of synthesizing in vitro complementary RNA (cRNA) that is similar in several characteristics to the cRNA synthesized in the infected cell, which is the viral mRNA. Most of the in vitro cRNA is large (approximately 2.5 X 10(5) to 10(6) daltons), similar in size to in vivo cRNA. The in vitro transcripts initiate in adenosine (A) or guanosine (G) at the 5' end, as also appears to be the case with in vivo cRNA (R.M. Krug et al., 1976). The in vitro transcripts contain covalently linked polyadenylate [poly(A)] sequences, which are longer and more heterogeneous than the poly(A) sequences found on in vivo cRNA. The synthesis in vitro of cRNA with these characteristics requires both the proper divalent cation, Mg2+, and a specific dinulceside monophosphage (DNMP), ApG or GpG. These DNMPs stimulate cRNA synthesis about 100-fold in the presence of Mg2+ and act as primers to initiate RNA chains, as demonstrated by the fact that the 5'-phosphorylated derivatives of these DNMP's, 32pApG or 32pGpG, are incroporated at the 5' end of the product RNA. The RNA synthesized in vitro differs from in vivo cRNA in that neither capping nor methylation of the in vitro transcripts has been detected. The virion does contain a methylase activity, as shown by its ability to methylate exogenous methyl-deficient Escherichia coli tRNA.

Transcription in vitro of phi29 DNA and EcoRI fragments by Bacillus subtilis RNA polymerase

EcoRI fragments A, B and C produced from linear phi29 DNA, but not D or E fragments, are transcribed by purified Bacillus subtilis RNA polymerase. The transcription of fragments A and C is initiated preferentially with GTP and to a lesser extent with ATP; the reverse happens in the case of fragment B. The dinucleotides GpU and GpA respectively, compete specifically with the incorporation of [gamma-32P]GTP directed by fragments A and C. The RNA synthesized in vitro by purified B. subtilis RNA polymerase is highly asymmetric. Most of the RNA synthesis directed by fragments A and C is early RNA. However, most of the RNA produced by fragment B is anti-late-RNA. Addition of crude extracts inhibit the transcription of fragment B but not that of fragments A and C.

Interaction of RNA polymerase from Escherichia coli with DNA. Analysis of T7 DNA early-promoter sites

A method was devised for directing RNA polymerase on a single promoter site on T7 DNA. Initiation complexes were formed on each of the three main promoter sites using one dinucleotide plus one nucleoside triphosphate. The ternary initiation complexes are resistant to rifampicin action, to inhibition by (rI)n at 0 degrees C and are stable at high salt concentrations. A minimum of a trinucleotide is required to form a stable ternary complex. To determine which promoter site was selected by RNA polymerase during initiation, the (rI)n-resistant RNA was digested by RNAse III to generate three characteristic initiator RNA fragments, resolved by gel electrophoresis. The three major promoter sites could be selected individually by using different primer and substrate combinations ApC plus ATP selected promoter A3, CpG plus CTP selected A2 and CpC plus ATP specified preferentially A1. A number of primer-substrate combinations specified each site at low salt concentration but the substrate requirement became very stringent at high salt concentration, suggesting that the postulated local opening of the promoter site could be more or less extensive, depending on the ionic strength. The minimum opening observed at high salt concentration corresponded to the insertion of a leader trinucleotide sequence. The promoter region melted by RNA polymerase at low salt concentration was (G plus C)-rich and corresponded to about 9 to 11 base pairs. Sequences of the melting recognition regions were tentatively inferred from the results.

RNA metabolism in nuclei isolated from HeLa cells

Nuclei with low cytoplasmic contamination, capable of synthesizing RNA for an extended period of time, were prepared from HeLa cells. Besides elongating RNA chains already initiated in vivo, the nuclear preparation initiates the synthesis of new RNA chains. This was shown by labelling the newly synthesized RNA with [gamma-32P]GTP and by detecting the presence of labelled guanosine tetraphosphate among the alkaline hydrolysis products of synthesized RNA. By synthesizing RNA in the presence of each of the four gamma-32P-labelled nucleoside triphosphates, it was possible to conclude that RNA chain synthesis starts predominantly with a purine base. Both nucleolar and nucleoplasmic RNAs are made. The nuclear preparation methylates the nucleolar RNA by utilizing S-adenosyl-L-methionine as a methyl-group donor.

Sequence of the OR operator of phage lambda

A sequence of 79 nucleotides from the lambda OR operator is obtained by primed transcription of repressor protected DNA fragments. The sequence contains the primary repressor binding site plus partial duplications which can be interpreted as secondary repressor binding sites.

Nucleotide sequence of an RNA polymerase binding site at an early T7 promoter

Escherichia coli RNA polymerase (EC 2.7.7.6), bound in a tight complex at an early T7 promoter, protects 41 to 43 base pairs of DNA from digestion by DNase. I. The protected DNA fragment contains both the binding site for RNA polymerase and the mRNA initiation point for the promoter. The sequence of the DNA fragment and the sequence of the mRNA that it codes for are presented here. A seven-base-pair sequence, apparently common to all promoters, is implicated in the formation of a tight binary complex with RNA polymerase.

Initiation characteristics for the synthesis of five T4 phage-specific messenger RNAs in vitro

The involvement of the nucleoside triphosphates in the initiation of the synthesis of the messenger ribonucleic acid of five T4 specific enzymes has been studied. Only one of these, the messenger RNA for deoxynucleosidemonophosphate kinase, can be initiated in the presence of one nucleoside triphosphate, namely ATP. All of the remaining four require the presence of at least two nucleoside triphosphates during the initiation period. The combination of ATP and UTP was best for the initiation of messenger RNA for dihydrofolate reductase, ATP and CTP for deoxycytidylate hydroxymethyltransferase and beta-glucosyltransferase, and ATP and GTP for alpha-glucosyltransferase. We have concluded that there is a great variation in the nucleotide composition and sequence of the initiation sites in T4 DNA. No correlation in the requirements of nucleoside triphosphates during the initiation period could be observed among the five systems studied according to their classification as one type or another of "early" T4 messenger RNA.