Electron microscopic analysis of transcription of a ribosomal RNA operon of E. coli

RNA polymerase collisions and their role in transcription

RNA polymerases are the central enzymes of gene expression and function frequently in either a head-on or co-directional manner on the busy DNA track. Whether and how these collisions between RNA polymerases contribute to transcriptional regulation is mysterious. Increasing evidence from biochemical and single-molecule studies suggests that RNA polymerase collisions function as an important regulator to fine-tune transcription, rather than creating deleterious "traffic jams". This review summarizes the recent progress on elucidating the consequences of RNA polymerase collisions during transcription and highlights the significance of cooperation and coordination between RNA polymerases.

UvrD helicase: an old dog with a new trick: how one step backward leads to many steps forward

Transcription-coupled repair (TCR) is a phenomenon that exists in a wide variety of organisms from bacteria to humans. This mechanism allows cells to repair the actively transcribed DNA strand much faster than the non-transcribed one. At the sites of bulky DNA damage RNA polymerase stalls, initiating recruitment of the repair machinery. It is a commonly accepted paradigm that bacterial cells utilize a sole coupling factor, called Mfd to initiate TCR. According to that model, Mfd removes transcription complexes stalled at the lesion site and simultaneously recruits repair machinery. However, this model was recently put in doubt by various discrepancies between the proposed universal role of Mfd in the TCR and its biochemical and phenotypical properties. Here, I present a second pathway of bacterial TCR recently discovered in my laboratory, which does not involve Mfd but implicates a common repair factor, UvrD, in a central position in the process.

Cooperative RNA polymerase molecules behavior on a stochastic sequence-dependent model for transcription elongation

The transcription process is crucial to life and the enzyme RNA polymerase (RNAP) is the major component of the transcription machinery. The development of single-molecule techniques, such as magnetic and optical tweezers, atomic-force microscopy and single-molecule fluorescence, increased our understanding of the transcription process and complements traditional biochemical studies. Based on these studies, theoretical models have been proposed to explain and predict the kinetics of the RNAP during the polymerization, highlighting the results achieved by models based on the thermodynamic stability of the transcription elongation complex. However, experiments showed that if more than one RNAP initiates from the same promoter, the transcription behavior slightly changes and new phenomenona are observed. We proposed and implemented a theoretical model that considers collisions between RNAPs and predicts their cooperative behavior during multi-round transcription generalizing the Bai et al. stochastic sequence-dependent model. In our approach, collisions between elongating enzymes modify their transcription rate values. We performed the simulations in Mathematica® and compared the results of the single and the multiple-molecule transcription with experimental results and other theoretical models. Our multi-round approach can recover several expected behaviors, showing that the transcription process for the studied sequences can be accelerated up to 48% when collisions are allowed: the dwell times on pause sites are reduced as well as the distance that the RNAPs backtracked from backtracking sites.

Cooperation between RNA polymerase molecules in transcription elongation

Transcription elongation is responsible for rapid synthesis of RNA chains of thousands of nucleotides in vivo. In contrast, a single round of transcription performed in vitro is frequently interrupted by pauses and arrests that drastically reduce the elongation rate and the yield of the full-length transcript. Here we demonstrate that most transcriptional delays disappear if more than one RNA polymerase (RNAP) molecule initiates from the same promoter. Anti-arrest and anti-pause effects of trailing RNAP are due to forward translocation of leading (backtracked) complexes. Such cooperation between RNAP molecules links the rate of elongation to the rate of initiation and explains why elongation is still fast and processive in vivo even without anti-arrest factors.

Regulation of transcription from tandem and convergent promoters

We have examined transcription on templates containing the trp and lac UV5 promoters arranged in tandem or opposing orientations. These studies have revealed that the strengths of the two promoters are comparable, though the lac UV5 promoter is much more sensitive to the level of initiating purine present. Kinetic experiments have shown that a polymerase molecule poised at the lac promoter, or a lac repressor molecule bound to the lac operator, can temporarily block a polymerase molecule initiated from the trp promoter, though transcription eventually continues through. In the convergent construct, transcription from the lac promoter is hindered only when initiation is suboptimal due to low purine concentrations.

Pausing and attenuation of in vitro transcription in the rrnB operon of E. coli

We have determined the effects of the nusA gene protein and the regulatory nucleotide guanosine tetraphosphate (ppGpp) on pausing and termination of transcription in the leader region of the rrnB operon in vitro. The leader region of rrnB contains several types of potential regulatory sequences that act at the level of RNA chain elongation and may be involved in control of bacterial growth. We have mapped a termination site, tL, located 260 bases from rrnB promoter P1. Termination at tL is dependent on the nusA protein and is enhanced by ppGpp. The DNA sequence at tL shows striking homologies with trp t', a terminator also strongly affected in vitro by the nusA protein. These in vitro results suggest that rRNA transcription in vivo may be regulated in part through an attenuation mechanism that leads to termination of rrnB chains in the leader region. In addition to tL, elongation of transcription in the leader region is affected by several pause sites that are sensitive to the concentration of ppGpp and the presence of the nusA gene protein. The location and properties of these pause sites suggest that they may also play a role in regulation of rrnB transcription through a mechanism we have termed "turnstile" attenuation. One pause site, located 90 and 91 bases from P1, is unique in that it is not normally a site for transcriptional pausing, but is dependent on simultaneous binding of polymerase at rrnB promoter P2. This leads to blockage of P1 transcripts at high RNA polymerase densities and may provide an additional locus for regulation of rrn transcription.

Terminal strand-switching of E. coli RNA polymerase transcribing a truncated DNA fragment

When transcribing a restriction fragment containing the promoters and the first part of the rrnE operon of Escherichia coli, RNA polymerase holoenzyme starts exclusively on the promoters. Besides run-off transcripts, molecules longer than template-size are formed by terminal strand switch.