ERC FUNDED PROJECTS

Brain and spinal cord diseases affect 38% of the European population and cost over 800 billion € annually; representing by far the largest health challenge. ALS is a prevalent neurological disease caused by motor neuron death with an invariably fatal outcome. I contributed to ALS research with the groundbreaking discovery of TDP-43 mutations, functionally characterized these mutations in the first vertebrate model and demonstrated a genetic interaction with another major ALS gene FUS. Emerging evidence indicates that four major causative factors in ALS, C9orf72, TDP-43, FUS & SQSTM1, genetically interact and could function in common cellular mechanisms. Here, I will develop zebrafish transgenic lines for all four genes, using state of the art genomic editing tools to combine simultaneous gene knockout and expression of the mutant alleles. Using these innovative disease models I will study the functional interactions amongst these four genes and their converging effect on key ALS pathogenic mechanisms: autophagy degradation, stress granule formation and RNA regulation. These studies will permit to pinpoint the molecular cascades that underlie ALS-related neurodegeneration. We will further expand the current ALS network by proposing and validating novel genetic interactors, which will be further screened for disease-causing variants and as pathological markers in patient samples. The power of zebrafish as a vertebrate model amenable to high-content phenotype-based screens will enable discovery of bioactive compounds that are neuroprotective in multiple animal models of disease. This project will increase the fundamental understanding of the relevance of C9orf72, TDP-43, FUS and SQSTM1 by developing animal models to characterize common pathophysiological mechanisms. Furthermore, I will uncover novel genetic, disease-related and pharmacological modifiers to extend the ALS network that will facilitate development of therapeutic strategies for neurodegenerative disorders

2 000 000 €

Start date: 2017-04-01, End date: 2022-03-31

Brain information processing is commonly thought to be a neuronal performance. However recent data point to a key role of astrocytes in brain development, activity and pathology. Indeed astrocytes are now viewed as crucial elements of the brain circuitry that control synapse formation, maturation, activity and elimination. How do astrocytes exert such control is matter of intense research, as they are now known to participate in critical developmental periods as well as in psychiatric disorders involving synapse alterations. Thus unraveling how astrocytes control synaptic circuit formation and maturation is crucial, not only for our understanding of brain development, but also for identifying novel therapeutic targets. We recently found that connexin 30 (Cx30), an astroglial gap junction subunit expressed postnatally, tunes synaptic activity via an unprecedented non-channel function setting the proximity of glial processes to synaptic clefts, essential for synaptic glutamate clearance efficacy. Our work not only reveals Cx30 as a key determinant of glial synapse coverage, but also extends the classical model of neuroglial interactions in which astrocytes are generally considered as extrasynaptic elements indirectly regulating neurotransmission. Yet the molecular mechanisms involved in such control, its dynamic regulation by activity and impact in a native developmental context are unknown. We will now address these important questions, focusing on the involvement of this novel astroglial function in wiring developing synaptic circuits. Thus using a multidisciplinary approach we will investigate: 1) the molecular and cellular mechanisms underlying Cx30 regulation of synaptic function 2) the activity-dependent dynamics of Cx30 function at synapses 3) a role for Cx30 in wiring synaptic circuits during critical developmental periods This ambitious project will provide essential knowledge on the molecular mechanisms underlying astroglial control of synaptic circuits.

2 000 000 €

Start date: 2016-10-01, End date: 2021-09-30

Background. We have detailed maps of brain structure and function, yet are lacking understanding of how the highly connected units interact and give rise to mental processes. The Virtual Brain (TVB), a whole brain simulation framework, aims to bridge that gap. Yet it is still developing. We are proposing here breakthrough advances that reveal mechanisms of brain function and foster collaboration between research groups. Vision. Clinical applications that simulate individual patient brains and predict trajectories of recovery or decline or test therapies to select the best one for that person. Goal. Using biologically realistic brain models and multimodal functional and structural imaging data to elucidate control mechanisms of the human brain in aging. A database collects key data and allows identifying most generic models and mechanisms below the spatial and temporal resolution of non-invasive imaging techniques taking into account the complex interaction in the brain that without a model would be impossible to keep track of. Objectives. 1) Parameter optimization for large parameter space search and a library of dynamical regimes linking dynamical regimes and underlying mechanisms to biological (cognitive) age. 2) Identifying the role of intrinsic plasticity for network reconfigurations in the resting state and its age dependency. 3) Model based identification of task related plasticity mechanisms and their functional consequences for network reconfigurations in coordination learning in aging. 4) An interactive tool that provides access to the dynamical regimes library and makes pre-computed simulations easily accessible allowing researchers to benefit and learn from existing work. Impact. Understanding development, aging and brain disorders from the perspective of disruption of information processing architectures provides an opportunity for new interventions that re-establish control in brain pathology hence posing a breakthrough in the health and biotech sector.

1 870 588 €

Start date: 2016-08-01, End date: 2021-07-31

It is a fundamental but still elusive question how nociceptive processing is performed in neuronal networks in the cortex for the conscious experience of pain. The objective of this project is to identify and characterize the cortical microcircuits in the anterior cingulate cortex (ACC) that are involved in pain processing with cellular resolution. The ACC is essential for evaluating the emotional/affective component of pain. Our research will investigate the elusive question if a dedicated pain circuit exists in the ACC. We will dissect the detailed structure and connectivity of this pain circuit and investigate how it generates affective behavioural responses related to pain. At the core of this project, we will characterize the neuronal networks in the ACC that are engaged in the processing of noxious stimuli. It will be highly interesting to determine the neuronal dynamics in the ACC during nociception and in chronic pain conditions on the cellular and network level. Furthermore, we will elucidate the downstream targets that are influenced by the pain circuits in the ACC to generate the appropriate behavioural responses. These aims will be achieved by a combination of electrophysiology, 2-photon Ca2+ imaging and pharmaco- and opto-genetic approaches both in vivo and in vitro and behavioural testing of pain affect in mice. This project will give a comprehensive picture of how a cortical microcircuit processes afferent noxious stimuli to generate an affective behavioural response. This study will give important insight into the fundamental question of cortical information processing and it is highly relevant to understand pain processing and the changes in the network dynamics that manifest the transition to chronic pain. Eventually this might contribute to the development of novel treatment strategies for this pathological condition.

1 928 125 €

Start date: 2016-09-01, End date: 2021-08-31