The Dulin lab is fascinated by cellular and viral processes involved in RNA synthesis. To investigate RNA synthesis, we use single molecule techniques, such as magnetic tweezers and single molecule fluorescence resonance energy transfer (FRET), as described in Single molecule biophysics and techniques.
In the Central dogma of molecular biology, RNA production is the intermediate step for protein synthesis. The genes encoded in the DNA are read and transcribed by the RNA polymerases (RNAP) into RNA, part of which, called messenger RNA, is subsequently translated into proteins by the ribosomes.
Being a key process in gene expression, transcription is therefore highly regulated in cells and is divided in three steps, i.e. initiation, elongation and termination.
During initiation, the pre-initiation complex (PIC), formed by the RNAP and its associated factors, recognises the promoter, i.e. a DNA sequence that precedes the gene, and binds to it specifically, which forms the RNAP-promoter closed complex (RPc). The PIC subsequently opens the DNA promoter to make a transcription bubble, which forms the RNAP-promoter open complex (RPo) and places the RNAP active site at the transcription start site of the gene. In the presence of nucleotides (NTP), the RNAP initiates RNA synthesis (RPitc, itc: initially transcribing complex), which leads to either promoter escape towards elongation and dissociation from the PIC co-factors, or to abortive initiation, i.e. release of the nascent RNA, bringing the PIC back to the RPo stage. Interestingly, some promoters are rate-limiting for gene expression at the RPo stage, which is driven by promoter-PIC interactions, others at RPitc, driven by the initially transcribed sequence. Understanding the nature of these interactions and how they modulate promoter-based gene expression regulation is therefore of great importance.
As every single steps during transcription initiation is reversible and stochastic, transcription initiation study using classical biochemistry ensemble experiments provides only the averaged behaviour of a heterogeneous sample. Therefore, ensemble techniques cannot access the kinetics of every intermediates, and provide an accurate description of transcription initiation. Single molecule techniques, such as single molecule FRET and magnetic tweezers, have been very useful to decipher the complex branched biochemical pathways of transcription initiation using their ability to observe the dynamics of individual RNA polymerases, and therefore discovered, e.g. pauses of various biochemical origins that regulates initial transcription in bacteria.
In the Dulin lab, we investigate transcription initiation on various cellular systems, such as the human mitochondria transcription complex, using bespoke high throughput magnetic tweezers. We are currently developing a bespoke TIRF microscope for single molecule FRET experiments to complement our magnetic tweezers approach.
During elongation, it has been shown that the RNAP encounters various type of pauses that halt transcription. These pauses are important regulatory checkpoints for, e.g. transcription factor to bind the RNAP, to synchronise with co-transcriptional processes such as translation in bacteria. The high throughput capability of our magnetic tweezers assay offers the possibility to deeply probe transcription elongation and characterise rare – but relevant – biochemical states.
At the end of the gene, the RNAP encounters a termination signal, which comes in the form of, e.g. DNA sequence that encodes a termination signal, such as an RNA hairpin, a protein complex that blocks and dissociates the RNAP. We are particularly interested in understanding protein roadblock mediated transcription termination, such as the one used to terminate human mitochondria transcription, where the mitochondrial termination factor 1 (MTERF1) promotes transcription termination in a directional manner.
(+)RNA virus replication
The Dulin lab has strong expertise in RNA virus replication study at the single molecule level, having pioneered the first studies of elongating viral RNA-dependent RNA polymerases (RdRp’s), the polymerase responsible for the synthesis of all viral genome. In particular, we focus our research on (+)RNA virus replication, i.e. virus of which the viral genome encodes directly the viral proteins. As any virus, (+)RNA viruses need the host cell translation machinery to synthesise the viral proteins from the 5-30 kilobases long viral genome.
Furthermore, the viral RdRp is also largely responsible for virus evolution and adaptation to the host antiviral defence mechanism, as it incorporates mutations in the viral genome and assist viral genome recombination, i.e. the mechanism by which part of the genome of two viruses are recombined to form a new viral genome. Given its importance, the viral RdRp is an important target for both drugs, e.g. antiviral nucleotide analogues, and vaccine development, e.g. by affecting the RdRp replication fidelity. Therefore, understanding viral replication kinetics and viral replication machinery interactions with the viral genome is of utmost importance. To characterise the mechanism of nucleotide misincorporation by the viral RdRp, we need a technique that allows the observation of rare (misincorporation probability ~0.001-0.0001/nucleotide incorporation) and asynchronous events. Furthermore, we need near single nucleotide spatial resolution and ~10-100ms temporal resolution, while using kilobases long template to collect enough miscincorporation events. High throughput magnetic tweezers are particularly suitable to solve this conundrum, as it offers the possibility to follow hundreds of polymerase simultaneously on kilobases long template, with ~0.3 nm tracking resolution at 1 s and constant applied force.
The study of the kinetics of viral RdRp’s using single molecule high throughput magnetic tweezers has been essential to discover a new mechanism for nucleotide misincorporation that generates a pause during viral genome replication (Dulin et al., Cell Reports 2015, 2017), but also to study how antiviral nucleotide analogues affect viral replication in the presence of all the natural nucleotides at saturating concentration, which is inaccessible for ensemble studies (as the antiviral nucleotide analogues are strongly selected against by the RdRp). This work has lead to the discovery of a new mode of action for antiviral nucleotides analogue, i.e. very long pauses linked to RdRp backtracking.
The Dulin lab is now looking into how viral genome sequence affects viral replication kinetics, as well as how the viral genome interacts with the viral replication machinery. We particularly interested by the following virus genus, i.e. enterovirus (poliovirus, Rhinovirus-C), flavivirus (Dengue) and coronavirus (SARS).