Fabian Blombach

Eukaryotic and archaeal TBP and TFB/TF(II)B follow different promoter DNA bending pathways

During transcription initiation, the promoter DNA is recognized and bent by the basal transcription factor TATA-binding protein (TBP). Subsequent association of transcription factor B (TFB) with the TBP–DNA complex is followed by the recruitment of the ribonucleic acid polymerase resulting in the formation of the pre-initiation complex. TBP and TFB/TF(II)B are highly conserved in structure and function among the eukaryotic-archaeal domain but intriguingly have to operate under vastly different conditions. Employing single-pair fluorescence resonance energy transfer, we monitored DNA bending by eukaryotic and archaeal TBPs in the absence and presence of TFB in real-time. We observed that the lifetime of the TBP–DNA interaction differs significantly between the archaeal and eukaryotic system. We show that the eukaryotic DNA-TBP interaction is characterized by a linear, stepwise bending mechanism with an intermediate state distinguished by a distinct bending angle. TF(II)B specifically stabilizes the fully bent TBP–promoter DNA complex and we identify this step as a regulatory checkpoint. In contrast, the archaeal TBP–DNA interaction is extremely dynamic and TBP from the archaeal organism Sulfolobus acidocaldarius strictly requires TFB for DNA bending. Thus, we demonstrate that transcription initiation follows diverse pathways on the way to the formation of the pre-initiation complex.

Archaeal TFEα/β is a hybrid of TFIIE and the RNA polymerase III subcomplex hRPC62/39

Transcription initiation of archaeal RNA polymerase (RNAP) and eukaryotic RNAPII is assisted by conserved basal transcription factors. The eukaryotic transcription factor TFIIE consists of α and β subunits. Here we have identified and characterised the function of the TFIIEβ homologue in archaea that on the primary sequence level is related to the RNAPIII subunit hRPC39. Both archaeal TFEβ and hRPC39 harbour a cubane 4Fe-4S cluster, which is crucial for heterodimerization of TFEα/β and its engagement with the RNAP clamp. TFEα/β stabilises the preinitiation complex, enhances DNA melting, and stimulates abortive and productive transcription. These activities are strictly dependent on the β subunit and the promoter sequence. Our results suggest that archaeal TFEα/β is likely to represent the evolutionary ancestor of TFIIE-like factors in extant eukaryotes. DOI: http://dx.doi.org/10.7554/eLife.08378.001

Molecular Mechanisms of Transcription Initiation—Structure, Function, and Evolution of TFE/TFIIE-Like Factors and Open Complex Formation

Transcription initiation requires that the promoter DNA is melted and the template strand is loaded into the active site of the RNA polymerase (RNAP), forming the open complex (OC). The archaeal initiation factor TFE and its eukaryotic counterpart TFIIE facilitate this process. Recent structural and biophysical studies have revealed the position of TFE/TFIIE within the pre-initiation complex (PIC) and illuminated its role in OC formation. TFE operates via allosteric and direct mechanisms. Firstly, it interacts with the RNAP and induces the opening of the flexible RNAP clamp domain, concomitant with DNA melting and template loading. Secondly, TFE binds physically to single-stranded DNA in the transcription bubble of the OC and increases its stability. The identification of the β-subunit of archaeal TFE enabled us to reconstruct the evolutionary history of TFE/TFIIE-like factors, which is characterised by winged helix (WH) domain expansion in eukaryotes and loss of metal centres including iron-sulfur clusters and Zinc ribbons. OC formation is an important target for the regulation of transcription in all domains of life. We propose that TFE and the bacterial general transcription factor CarD, although structurally and evolutionary unrelated, show interesting parallels in their mechanism to enhance OC formation. We argue that OC formation is used as a way to regulate transcription in all domains of life, and these regulatory mechanisms coevolved with the basal transcription machinery.

A global analysis of transcription reveals two modes of Spt4/5 recruitment to archaeal RNA polymerase

The archaeal transcription apparatus is closely related to the eukaryotic RNA polymerase (RNAP) II system, while archaeal genomes are more similar to bacteria with densely packed genes organized in operons. This makes understanding transcription in archaea vital, both in terms of molecular mechanisms and evolution. Very little is known about how archaeal cells orchestrate transcription on a systems level. We have characterized the genome-wide occupancy of the Methanocaldococcus jannaschii transcription machinery and its transcriptome. Our data reveal how the TATA and BRE promoter elements facilitate recruitment of the essential initiation factors TATA-binding protein and transcription factor B, respectively, which in turn are responsible for the loading of RNAP into the transcription units. The occupancies of RNAP and Spt4/5 strongly correlate with each other and with RNA levels. Our results show that Spt4/5 is a general elongation factor in archaea as its presence on all genes matches RNAP. Spt4/5 is recruited proximal to the transcription start site on the majority of transcription units, while on a subset of genes, including rRNA and CRISPR loci, Spt4/5 is recruited to the transcription elongation complex during early elongation within 500 base pairs of the transcription start site and akin to its bacterial homologue NusG.

Repression of RNA polymerase by the archaeo-viral regulator ORF145/RIP.

Little is known about how archaeal viruses perturb the transcription machinery of their hosts. Here we provide the first example of an archaeo-viral transcription factor that directly targets the host RNA polymerase (RNAP) and efficiently represses its activity. ORF145 from the temperate Acidianus two-tailed virus (ATV) forms a high-affinity complex with RNAP by binding inside the DNA-binding channel where it locks the flexible RNAP clamp in one position. This counteracts the formation of transcription pre-initiation complexes in vitro and represses abortive and productive transcription initiation, as well as elongation. Both host and viral promoters are subjected to ORF145 repression. Thus, ORF145 has the properties of a global transcription repressor and its overexpression is toxic for Sulfolobus. On the basis of its properties, we have re-named ORF145 RNAP Inhibitory Protein (RIP).

Transcription in Archaea: in vitro transcription assays for mjRNAP

The fully recombinant Methanocaldococcus jannaschii RNA polymerase allows for a detailed dissection of the different stages of the transcription. In the previous chapter, we discussed how to purify the different components of the M. jannaschii transcription system, the RNA polymerase subunits, and general transcription factors and how to assemble a functional M. jannaschii enzyme. Standard in vitro transcription assays can be used to examine the different stages of transcription. In this chapter, we describe how some of these assays have been optimized for M. jannaschii RNA polymerase, which transcribes at much higher temperatures than many other transcription complexes.

Transcription in Archaea: Preparation of Methanocaldococcus jannaschii Transcription Machinery

Archaeal RNA polymerase and general transcription factors are more closely related to those of eukaryotes than of bacteria. As such the study of transcription of archaea is important both in terms of examination of the evolution of the transcriptional machinery and as a simplified tool for eukaryotic transcription. In particular, the hyperthermophilic Methanocaldococcus jannaschii provides us with a fully recombinant RNA polymerase system allowing for much more detailed in vitro examination of the roles of different components during the transcription cycle than otherwise possible. The individual subunits of M. jannaschii enzyme are easily expressed and purified from heterologous expression systems. Forming functional RNA polymerase involves simply combining the different subunits under denaturing conditions and slowly removing the denaturant.

Structural and functional adaptation of Haloferax volcanii TFEα/β

Abstract The basal transcription factor TFE enhances transcription initiation by catalysing DNA strand-separation, a process that varies with temperature and ionic strength. Canonical TFE forms a heterodimeric complex whose integrity and function critically relies on a cubane iron-sulphur cluster residing in the TFEβ subunit. Halophilic archaea such as Haloferax volcanii have highly divergent putative TFEβ homologues with unknown properties. Here, we demonstrate that Haloferax TFEβ lacks the prototypical iron-sulphur cluster yet still forms a stable complex with TFEα. A second metal cluster contained in the zinc ribbon domain in TFEα is highly degenerate but retains low binding affinity for zinc, which contributes to protein folding and stability. The deletion of the tfeB gene in H. volcanii results in the aberrant expression of approximately one third of all genes, consistent with its function as a basal transcription initiation factor. Interestingly, tfeB deletion particularly affects foreign genes including a prophage region. Our results reveal the loss of metal centres in Hvo transcription factors, and confirm the dual function of TFE as basal factor and regulator of transcription.

Same same but different: The evolution of TBP in archaea and their eukaryotic offspring

ABSTRACT Transcription factors TBP and TF(II)B assemble with RNA polymerase at the promoter DNA forming the initiation complex. Despite a high degree of conservation, the molecular binding mechanisms of archaeal and eukaryotic TBP and TF(II)B differ significantly. Based on recent biophysical data, we speculate how the mechanisms co-evolved with transcription regulation and TBP multiplicity.

A Global Characterisation of the Archaeal Transcription Machinery

Archaea employ a eukaryote-like transcription apparatus to transcribe a bacteria-like genome; while the RNA polymerase, basal factors and promoter elements mirror the eukaryotic RNA polymerase II system, archaeal genomes are densely packed with genes organised into multicistronic transcription units. The molecular mechanisms of archaeal transcription have been studied and characterised in great detail in vitro, but until recently relatively little was known about its global characteristics. In this chapter we discuss an integrated view of transcription from the molecular to the global level. Systems biology approaches have provided compelling insights into promoter and terminator DNA elements, the genome-wide distribution of transcription initiation- and elongation factors and RNA polymerase, the archaeal transcriptome and chromatin organisation. Overall these analyses illuminate transcription from a genome-wide perspective and serve as a resource for the community. In addition, Big Data can often validate mechanistic models based on biochemical and structural information, and generate new working hypotheses that can be thoroughly tested and dissected in vitro. This is an exciting time to study gene expression in the archaea since we are at the brink of a comprehensive yet detailed understanding of transcription.