Sedimentation properties of E. coli RNA polymerase and its complexes with polyuridylic acid

Oligomerization states of the Mycobacterium tuberculosis RNA polymerase core and holoenzymes

During the past few decades, a wealth of knowledge has been made available for the transcription machinery in bacteria from the structural, functional and mechanistic point of view. However, comparatively little is known about the homooligomerization of the multisubunit M. tuberculosis RNA polymerase (RNAP) enzyme and its functional relevance. While E. coli RNAP has been extensively studied, many aspects of RNAP of the deadly pathogenic M. tuberculosis are still unclear. We used biophysical and biochemical methods to study the oligomerization states of the core and holoenzymes of M. tuberculosis RNAP. By size exclusion chromatography and negative staining Transmission Electron Microscopy (TEM) studies and quantitative analysis of the TEM images, we demonstrate that the in vivo reconstituted RNAP core enzyme (α2ββ'ω) can also exist as dimers in vitro. Using similar methods, we also show that the holoenzyme (core + σA) does not dimerize in vitro and exist mostly as monomers. It is tempting to suggest that the oligomeric changes that we see in presence of σA factor might have functional relevance in the cellular process. Although reported previously in E. coli, to our knowledge we report here for the first time the study of oligomeric nature of M. tuberculosis RNAP in presence and absence of σA factor.

Transcription-translation coupling: direct interactions of RNA polymerase with ribosomes and ribosomal subunits

In prokaryotes, RNA polymerase and ribosomes can bind concurrently to the same RNA transcript, leading to the functional coupling of transcription and translation. The interactions between RNA polymerase and ribosomes are crucial for the coordination of transcription with translation. Here, we report that RNA polymerase directly binds ribosomes and isolated large and small ribosomal subunits. RNA polymerase and ribosomes form a one-to-one complex with a micromolar dissociation constant. The formation of the complex is modulated by the conformational and functional states of RNA polymerase and the ribosome. The binding interface on the large ribosomal subunit is buried by the small subunit during protein synthesis, whereas that on the small subunit remains solvent-accessible. The RNA polymerase binding site on the ribosome includes that of the isolated small ribosomal subunit. This direct interaction between RNA polymerase and ribosomes may contribute to the coupling of transcription to translation.

Oligomerization of the E. coli core RNA polymerase: formation of (α2ββ'ω)2-DNA complexes and regulation of the oligomerization by auxiliary subunits

In this work, using multiple, dissimilar physico-chemical techniques, we demonstrate that the Escherichia coli RNA polymerase core enzyme obtained through a classic purification procedure forms stable (α₂ββ'ω)₂ complexes in the presence or absence of short DNA probes. Multiple control experiments indicate that this self-association is unlikely to be mediated by RNA polymerase-associated non-protein molecules. We show that the formation of (α₂ββ'ω)₂ complexes is subject to regulation by known RNA polymerase interactors, such as the auxiliary SWI/SNF subunit of RNA polymerase RapA, as well as NusA and σ⁷⁰. We also demonstrate that the separation of the core RNA polymerase and RNA polymerase holoenzyme species during Mono Q chromatography is likely due to oligomerization of the core enzyme. We have analyzed the oligomeric state of the polymerase in the presence or absence of DNA, an aspect that was missing from previous studies. Importantly, our work demonstrates that RNA polymerase oligomerization is compatible with DNA binding. Through in vitro transcription and in vivo experiments (utilizing a RapA^R599/Q602 mutant lacking transcription-stimulatory function), we demonstrate that the formation of tandem (α₂ββ'ω)₂–DNA complexes is likely functionally significant and beneficial for the transcriptional activity of the polymerase. Taken together, our findings suggest a novel structural aspect of the E. coli elongation complex. We hypothesize that transcription by tandem RNA polymerase complexes initiated at hypothetical bidirectional “origins of transcription” may explain recurring switches of the direction of transcription in bacterial genomes.

Footprinting analysis of mammalian RNA polymerase II along its transcript: an alternative view of transcription elongation

Ternary complexes of RNA polymerase II, bearing the nascent RNA transcript, are intermediates in the synthesis of all eukaryotic mRNAs and are implicated as regulatory targets of factors that control RNA chain elongation and termination. Information as to the structure of such complexes is essential in understanding the catalytic and regulatory properties of the RNA polymerase. We have prepared complexes of purified RNA polymerase II halted at defined positions along a DNA template and used RNase footprinting to map interactions of the polymerase with the nascent RNA. Unexpectedly, the transcript is sensitive to cleavage by RNases A and T1 at positions as close as 3 nucleotides from the 3'-terminal growing point. Ternary complexes in which the transcript has been cleaved to give a short fragment can retain that fragment and remain active and able to continue elongation. Since DNA.RNA hybrid structures are completely resistant to cleavage under our reaction conditions, the results suggest that any DNA.RNA hybrid intermediate can extend for no more than 3 base pairs, in dramatic contrast to recent models for transcription elongation. At lower RNase concentrations, the transcript is protected from cleavage out to about 24 nucleotides from the 3' terminus. We interpret this partial protection as due to the presence of an RNA binding site on the polymerase that binds the nascent transcript during elongation, a model proposed earlier by several workers in preference to the hybrid model. The properties of this RNA binding site are likely to play a central role in the process of transcription elongation and termination and in their regulation.