ERC FUNDED PROJECTS

Over 100 types of distinct modifications are catalyzed on RNA molecules post-transcriptionally. In an analogous manner to well-studied chemical modifications on proteins or DNA, modifications on RNA - and particularly on mRNA - harbor the exciting potential of regulating the complex and interlinked life cycle of these molecules. The most abundant modification in mammalian and yeast mRNA is N6-methyladenosine (m6A). We have pioneered approaches for mapping m6A in a transcriptome wide manner, and we and others have identified factors involved in encoding and decoding m6A. While experimental disruption of these factors is associated with severe phenotypes, the role of m6A remains enigmatic. No single methylated site has been shown to causally underlie any physiological or molecular function. This proposal aims to establish a framework for systematically deciphering the molecular function of a modification and its underlying mechanisms and to uncover the physiological role of the modification in regulation of a cellular response. We will apply this framework to m6A in the context of meiosis in budding yeast, as m6A dynamically accumulates on meiotic mRNAs and as the methyltransferase catalyzing m6A is essential for meiosis. We will (1) aim to elucidate the physiological targets of methylation governing entry into meiosis (2) seek to elucidate the function of m6A at the molecular level, and understand its impact on the various steps of the mRNA life cycle, (3) seek to understand the mechanisms underlying its effects. These aims will provide a comprehensive framework for understanding how the epitranscriptome, an emerging post-transcriptional layer of regulation, fine-tunes gene regulation and impacts cellular decision making in a dynamic response, and will set the stage towards dissecting the roles of m6A and of an expanding set of mRNA modifications in more complex and disease related systems.

1 402 666 €

Start date: 2016-11-01, End date: 2021-10-31

Circadian (24hs) rhythms in locomotor activity are one of the best-characterized behaviors at the molecular, cellular and neural levels. Despite that, our understanding of how these rhythms are generated is still limited. A major shortcoming of the current approaches in the field is that they depict the circadian clock as a mere addition of steps (and/or combination of parts). By doing so, the circadian oscillator is portrayed as a static rather than a dynamic system. We have recently shown for the first time that miRNA-mediated regulation plays a role in circadian timekeeping in Drosophila. In the present project we will exploit complementary and cutting-edge approaches that will provide an integrative and comprehensive view of the circadian timekeeping system. As we believe that miRNAs are key mediators of this integration, we will dissect their role in the circadian clock at the molecular, cellular and neural levels in Drosophila. At the molecular level, we will determine the mechanisms, and proteins that mediate the circadian regulation of miRNAs function. Moreover, by the use of high-throughput methodology we will assess and characterize the impact of translational regulation on both the circadian transcriptome and proteome. At the cellular level, we plan to determine how this type of regulation integrates with other circadian pathways and which specific pathways and proteins mediate this process. As a final goal of the proposed project we plan to generate a complete genetic interaction map of the known circadian regulators, which will integrate the different molecular and cellular events involved in timekeeping. This will be a key step towards the understanding of the circadian clock as a dynamic adjustable process. Last, but not least, we will study the role of miRNAs in the circadian neural network. For doing so we will set up an ex vivo approach (fly brain's culture) that will assess circadian parameters through fluorescent continuous live imaging.

1 478 606 €

Start date: 2011-02-01, End date: 2016-01-31

Pioneering studies from the recent year, including those published by the PI of this proposal, are revolutionizing our perception of prokaryotic transcriptomes, and reveal unexpected regulatory complexity. Two central concepts are arising: the unanticipated abundance of cis-antisense RNAs overlapping protein coding genes, and alternative transcripts resulting from a dynamic behaviour of operon structures (where genes can be included or excluded from a polycistronic transcript in response to environmental cues). Understanding these phenomena holds a great potential for our ability to decipher how bacteria regulate their complex life styles and pathogenic behaviours, but their dynamics, regulatory roles, and effects on combinatorially increasing the regulatory capacity of the genome are completely unknown. The primary objectives of this proposed research are: i) to understand the extent, regulatory roles, and evolutionary consequences of cis-antisense RNAs in prokaryotes; ii) to understand the regulatory code, combinatorial effects and dynamics of alternative operon structures; and, in parallel iii) to develop a unified framework for comparative prokaryotic transcriptomics. Our strategy is based on a combination of deep sequencing technologies, computational modelling and data analyses, systems biology approaches, and focused molecular biology experiments. We will identify the extent and the impact of these RNA-based regulatory layers in representative pathogenic and non-pathogenic species across the prokaryotic tree of life, study their functional and evolutionary consequences, and break the regulatory code controlling them. Our planned research has the potential of producing methodological and conceptual breakthroughs in the emerging field of prokaryotic transcriptomics.

1 499 540 €

Start date: 2011-01-01, End date: 2016-06-30