Combined SPT and FCS methods reveal a mechanism of RNAP II oversampling in cell nuclei.

Gene expression orchestration is a key question in fundamental and applied research. Different models for transcription regulation were proposed, yet the dynamic regulation of RNA polymerase II (RNAP II) activity remains a matter of debate. To improve our knowledge of this topic, we investigated RNAP II motility in eukaryotic cells by combining single particle tracking (SPT) and fluorescence correlation spectroscopy (FCS) techniques, to take advantage of their different sensitivities in order to analyze together slow and fast molecular movements. Thanks to calibrated samples, we developed a benchmark for quantitative analysis of molecular dynamics, to eliminate the main potential instrumental biases. We applied this workflow to study the diffusion of RPB1, the catalytic subunit of RNAP II. By a cross-analysis of FCS and SPT, we could highlight different RPB1 motility states and identifyed a stationary state, a slow diffusion state, and two different modes of subdiffusion. Interestingly, our analysis also unveiled the oversampling by RPB1 of nuclear subdomains. Based on these data, we propose a novel model of spatio-temporal transcription regulation. Altogether, our results highlight the importance of combining microscopy approaches at different time scales to get a full insight into the real complexity of molecular kinetics in cells.

[P-TEFb and Brd4: actors of the transcription pause release as therapeutical targets]. / P-TEFb et Brd4 - Acteurs de la levée de pause transcriptionnelle, possibles cibles thérapeutiques.

Most cell physiology events are dictated by the integration of perceived signals and the elaboration by cells of adapted answers via the execution of proper transcriptional programs. In order to ensure an optimal control of these answers, many regulation mechanisms have been selected throughout the evolution, thus allowing to fine-tune transcript expression. The transcriptional pause and its release by P-TEFb (Positive Transcription Elongation Factor) have been evidenced two decades ago. Since then, the importance of such mechanisms has been highlighted by the association between alterations of this machinery and the appearance of diseases. P-TEFb and Brd4 have thus recently emerged as potential therapeutical targets for cancers and AIDS notably. In this review, we present a brief case history and an up-to-date synthesis of models for transcriptional pause release. We later discuss on the pathophysiological processes associated with this mechanism and clinical trials targeting Brd4 and P-TEFb.