ERC FUNDED PROJECTS

"How are actions initiated by the human brain when there is no external sensory cue or other immediate imperative? How do subtle ongoing interactions within the brain and between the brain, body, and sensory context influence the spontaneous initiation of action? How should we approach the problem of trying to identify the neural events that cause spontaneous voluntary action? Much is understood about how the brain decides between competing alternatives, leading to different behavioral responses. But far less is known about how the brain decides ""when"" to perform an action, or ""whether"" to perform an action in the first place, especially in a context where there is no sensory cue to act such as during foraging. This project seeks to open a new chapter in the study of spontaneous voluntary action building on a novel hypothesis recently introduced by the applicant (Schurger et al, PNAS 2012) concerning the role of ongoing neural activity in action initiation. We introduce brain-behavior forecasting, the converse of movement-locked averaging, as an approach to identifying the neurodynamic states that commit the motor system to performing an action ""now"", and will apply it in the context of information foraging. Spontaneous action remains a profound mystery in the brain basis of behavior, in humans and other animals, and is also central to the problem of asynchronous intention-detection in brain-computer interfaces (BCIs). A BCI must not only interpret what the user intends, but also must detect ""when"" the user intends to act, and not respond otherwise. This remains the biggest challenge in the development of high-performance BCIs, whether invasive or non-invasive. This project will take a systematic and collaborative approach to the study of spontaneous self-initiated action, incorporating computational modeling, neuroimaging, and machine learning techniques towards a deeper understanding of voluntary behavior and the robust asynchronous detection of decisions-to-act."

1 338 130 €

Start date: 2015-10-01, End date: 2020-09-30

The project outlined here addresses the fundamental question how the brain encodes and controls behavior. While we have a reasonable understanding of the role of entire brain areas in such processes, and of mechanisms at the molecular and synaptic levels, there is a big gap in our knowledge of how behavior is controlled at the level of defined neuronal circuits. In natural environments, chances for survival depend on learning about possible aversive and appetitive outcomes and on the appropriate behavioral responses. Most studies addressing the underlying mechanisms at the level of neuronal circuits have focused on aversive learning, such as in Pavlovian fear conditioning. Understanding how activity in defined neuronal circuits mediates appetitive learning, as well as how these circuitries are shared and interact with aversive learning circuits, is a central question in the neuroscience of learning and memory and the focus of this grant application. Using a multidisciplinary approach in mice, combining behavioral, in vivo and in vitro electrophysiological, imaging, optogenetic and state-of-the-art viral circuit tracing techniques, we aim at dissecting the neuronal circuitry of appetitive Pavlovian conditioning with a focus on the amygdala, a key brain region important for both aversive and appetitive learning. Ultimately, elucidating these mechanisms at the level of defined neurons and circuits is fundamental not only for an understanding of memory processes in the brain in general, but also to inform a mechanistic approach to psychiatric conditions associated with amygdala dysfunction and dysregulated emotional responses including anxiety and mood disorders.

2 497 200 €

Start date: 2016-01-01, End date: 2020-12-31

Brain computations rely on proper signal flow through the complex network of connected brain regions. Despite a wealth of anatomical and functional data – from microscopic to macroscopic scale – we still poorly understand the principles of how signal flow is routed through neuronal networks to generate appropriate behavior. Brain dynamics on the 'mesoscopic' scale, the intermediate level where local microcircuits communicate via axonal pathways, has remained a particular blind spot of research as it has been difficult to access under in vivo conditions. Here, I propose to tackle the mesoscopic level of brain dynamics both experimentally and theoretically, adopting a fresh perspective centered on neuronal pathway dynamics. Experimentally, we will utilize and further advance state-of-the-art genetic and optical techniques to create a toolbox for measuring and manipulating signal flow in pathway networks across a broad range of temporal scales. In particular, we will improve fiber-optic based methods for probing the activity of either individual or multiple neuronal pathways with high specificity. Using these tools we will set out to reveal mesoscopic brain dynamics across relevant cortical and subcortical regions in awake, behaving mice. Specifically, we will investigate sensorimotor learning for a reward-based texture discrimination task and rapid sensorimotor control during skilled locomotion. Moreover, by combining fiber-optic methods with two-photon microscopy and fMRI, respectively, we will start linking the meso-level to the micro- and macro-levels. Throughout the project, experiments will be complemented by computational approaches to analyse data, model pathway dynamics, and conceptualize a formal theory of mesoscopic dynamics. This project may transform the field by bridging the hierarchical brain levels and opening significant new avenues to assess physiological as well as pathological signal flow in the brain.

2 498 915 €

Start date: 2016-02-01, End date: 2021-01-31

An expanded GGGGCC repeat in a non-coding region of the C9orf72 gene is the most common known cause of frontotemporal dementia (FTD) and amyotrophic lateral sclerosis (ALS). The repeat RNA is transcribed and accumulates in neuronal RNA aggregates, implicating RNA toxicity as a key pathogenic mechanism. However, the pathways that lead to neurodegeneration are unknown. My lab has made pioneering contributions to the understanding of C9orf72 FTD/ALS, and reported the first structure of the repeat RNA, and the first description of both sense and antisense RNA aggregates in patient brain. We have now developed new disease models that allow, for the first time, the dissection of RNA toxicity both in vivo and in sophisticated neuronal culture models. We have also used our knowledge of the repeat structure to identify novel small molecules that show very strong binding to the repeats. We will utilise our innovative disease models in a multidisciplinary approach to fully dissect the cellular pathways underlying C9orf72 repeat RNA toxicity in vivo, on a genome-wide scale. Altered RNA metabolism has been implicated in a wide range of neurodegenerative diseases, indicating that our findings will provide profound new insight into fundamental mechanisms of neuronal maintenance and survival. This research programme will also deliver a step change in our understanding of C9orf72 FTD/ALS pathogenesis and provide essential insight for the identification of small molecules with genuine therapeutic potential. RNA-mediated mechanisms are now known to be a common theme in neurodegeneration, suggesting these findings will have broad significance.

1 985 699 €

Start date: 2015-10-01, End date: 2021-03-31