Project acronym BARINAFLD
Project Using Bariatric Surgery to Discover Weight-Loss Independent Mechanisms Leading to the Reversal of Fatty Liver Disease
Researcher (PI) Danny Ben-Zvi
Host Institution (HI) THE HEBREW UNIVERSITY OF JERUSALEM
Call Details Starting Grant (StG), LS4, ERC-2018-STG
Summary Non-Alcoholic Fatty Liver Disease (NAFLD), a disease characterized by accumulation of lipid droplets in the liver, is the major precursor for liver failure and liver cancer, and constitutes a global health challenge. An estimated 25% of the adult population suffers from NAFLD, but no FDA approved drugs are available to treat this condition. Obesity is a major NAFLD risk factor and weight-loss improves disease severity in obese patients. Bariatric surgeries are an effective treatment for obesity when lifestyle modifications fail and often lead to improvement in NAFLD and type 2 diabetes.
The overreaching objective of this proposal is to combine bariatric surgery in mice and humans with advanced molecular and computational analyses to discover novel, weight-loss independent mechanisms that lead to NAFLD alleviation, and harness them to treat NAFLD.
In preliminary studies, I discovered that bariatric surgery clears lipid droplets from the livers of obese db/db mice without inducing weight-loss. Using metabolic and computational analysis, I found that bariatric surgery shifts hepatic gene expression and blood metabolome of post-bariatric patients to a new trajectory, distinct from lean or sick patients. Data analysis revealed the transcription factor Egr1 and one-carbon and choline metabolism to be key drivers of weight-loss independent effects of bariatric surgery.
I will use two NAFLD mouse models that do not lose weight after bariatric surgery to characterize livers of mice post-surgery. Human patients do lose weight following surgery, therefore I will use computational methods to elucidate weight-independent pathways induced by surgery, by comparing livers of lean patients to those of NAFLD patients before and shortly after bariatric surgery. Candidate pathways will be studied by metabolic flux analysis and manipulated genetically, with the ultimate goal of reaching systems-levels understanding of NAFLD and identifying surgery-mimetic therapies for this disease.
Summary
Non-Alcoholic Fatty Liver Disease (NAFLD), a disease characterized by accumulation of lipid droplets in the liver, is the major precursor for liver failure and liver cancer, and constitutes a global health challenge. An estimated 25% of the adult population suffers from NAFLD, but no FDA approved drugs are available to treat this condition. Obesity is a major NAFLD risk factor and weight-loss improves disease severity in obese patients. Bariatric surgeries are an effective treatment for obesity when lifestyle modifications fail and often lead to improvement in NAFLD and type 2 diabetes.
The overreaching objective of this proposal is to combine bariatric surgery in mice and humans with advanced molecular and computational analyses to discover novel, weight-loss independent mechanisms that lead to NAFLD alleviation, and harness them to treat NAFLD.
In preliminary studies, I discovered that bariatric surgery clears lipid droplets from the livers of obese db/db mice without inducing weight-loss. Using metabolic and computational analysis, I found that bariatric surgery shifts hepatic gene expression and blood metabolome of post-bariatric patients to a new trajectory, distinct from lean or sick patients. Data analysis revealed the transcription factor Egr1 and one-carbon and choline metabolism to be key drivers of weight-loss independent effects of bariatric surgery.
I will use two NAFLD mouse models that do not lose weight after bariatric surgery to characterize livers of mice post-surgery. Human patients do lose weight following surgery, therefore I will use computational methods to elucidate weight-independent pathways induced by surgery, by comparing livers of lean patients to those of NAFLD patients before and shortly after bariatric surgery. Candidate pathways will be studied by metabolic flux analysis and manipulated genetically, with the ultimate goal of reaching systems-levels understanding of NAFLD and identifying surgery-mimetic therapies for this disease.
Max ERC Funding
1 499 354 €
Duration
Start date: 2018-11-01, End date: 2023-10-31
Project acronym BBBARRIER
Project Mechanisms of regulation of the blood-brain barrier; towards opening and closing the barrier on demand
Researcher (PI) Björn Christer Betsholtz
Host Institution (HI) UPPSALA UNIVERSITET
Call Details Advanced Grant (AdG), LS4, ERC-2011-ADG_20110310
Summary In the bone-enclosed CNS, increased vascular permeability may cause life-threatening tissue swelling, and/or ischemia and inflammation which compromise tissue repair after trauma or stroke. The brain vasculature possesses several unique features collectively named the blood-brain barrier (BBB) in which passive permeability is almost completely abolished and replaced by a complex of specific transport mechanisms. The BBB is necessary to uphold the specific milieu necessary for neuronal function. Whereas breakdown of the BBB is part of many CNS diseases, including stroke, neuroinflammation, trauma and neurodegenerative disorders, its molecular mechanisms and consequences are unclear and debated. Conversely, the intact BBB is a huge obstacle for drug delivery to the brain. Research on the BBB therefore has two seemingly opposing aims: 1) to seal a damaged BBB and protect the brain from toxic blood products, and 2) to open the BBB “on demand” for drug delivery. A major problem in the BBB field has been the lack of in vivo animal models for molecular and functional studies. So far, available in vitro models are not recapitulating the in vivo BBB. Our recent work on mouse models lacking pericytes, a BBB-associated cell type, demonstrates a specific role for pericytes in the development and regulation of the mammalian BBB. These animal models are the first ones showing a general and significant BBB impairment in adulthood, and as such they provide a unique opportunity to address molecular mechanisms of BBB disruption in disease and in drug transport across the BBB. Importantly, the new models and tools that we have developed allow us to search for relevant druggable mechanisms and molecular targets in the BBB. The long-term goals of this proposal are to develop molecular strategies and tools to open and close the BBB “on demand” for drug delivery to the CNS, and to explore the importance and mechanisms of BBB dysfunction in neurodegenerative diseases and stroke.
Summary
In the bone-enclosed CNS, increased vascular permeability may cause life-threatening tissue swelling, and/or ischemia and inflammation which compromise tissue repair after trauma or stroke. The brain vasculature possesses several unique features collectively named the blood-brain barrier (BBB) in which passive permeability is almost completely abolished and replaced by a complex of specific transport mechanisms. The BBB is necessary to uphold the specific milieu necessary for neuronal function. Whereas breakdown of the BBB is part of many CNS diseases, including stroke, neuroinflammation, trauma and neurodegenerative disorders, its molecular mechanisms and consequences are unclear and debated. Conversely, the intact BBB is a huge obstacle for drug delivery to the brain. Research on the BBB therefore has two seemingly opposing aims: 1) to seal a damaged BBB and protect the brain from toxic blood products, and 2) to open the BBB “on demand” for drug delivery. A major problem in the BBB field has been the lack of in vivo animal models for molecular and functional studies. So far, available in vitro models are not recapitulating the in vivo BBB. Our recent work on mouse models lacking pericytes, a BBB-associated cell type, demonstrates a specific role for pericytes in the development and regulation of the mammalian BBB. These animal models are the first ones showing a general and significant BBB impairment in adulthood, and as such they provide a unique opportunity to address molecular mechanisms of BBB disruption in disease and in drug transport across the BBB. Importantly, the new models and tools that we have developed allow us to search for relevant druggable mechanisms and molecular targets in the BBB. The long-term goals of this proposal are to develop molecular strategies and tools to open and close the BBB “on demand” for drug delivery to the CNS, and to explore the importance and mechanisms of BBB dysfunction in neurodegenerative diseases and stroke.
Max ERC Funding
2 499 427 €
Duration
Start date: 2012-08-01, End date: 2017-07-31
Project acronym BCM-UPS
Project Dissecting the role of the ubiquitin proteasome system in the pathogenesis and therapy of B-cell malignancies
Researcher (PI) Florian Christoph Bassermann
Host Institution (HI) KLINIKUM RECHTS DER ISAR DER TECHNISCHEN UNIVERSITAT MUNCHEN
Call Details Consolidator Grant (CoG), LS4, ERC-2015-CoG
Summary B-cell malignancies are characterized by high levels of genomic instability, which critically contribute to their pathogenesis and evolution. Recently, the fundamental role of the ubiquitin proteasome system (UPS) in maintaining genome integrity has been appreciated. Two major new therapeutic modalities in B-cell malignancies, proteasome inhibitors and imunomodulatory drugs (IMiDs), target the UPS and demonstrate particular efficacy in multiple myeloma (MM) and mantle cell lymphoma (MCL), two incurable entities with poor prognosis. This suggests the presence of aberrant ubiquitylation events, whose identities have however remained mostly elusive.
Our recent studies identify fundamental roles of orphan ubiquitin ligases of the Cullin Ring ligase family (CRLs) and their counterparts, the deubiquitylating enzymes (DUBs) in the cellular DNA damage response machinery, and characterize these candidates as novel oncogenes or tumour suppressors in MM and MCL. These findings provide the foundation for our hypothesis that deregulated ubiquitylation events involving CRLs and DUBs have a far reaching impact on the pathogenesis of B-cell malignancies and can serve as new therapeutic targets and biomarkers.
We therefore propose a multistep strategy in which we will (1) characterize previously orphan CRLs and DUBs, which we have distinguished as candidate oncogenes and tumour suppressors in MM (FBXO3, USP24), MCL (FBXO25), or MM and MCL (CRBN), respectively; (2) decipher the global role of CRLs and DUBs in MM and MCL using defined genetic screens; (3) identify relevant substrates of CRLs/DUBs discovered in (2) using mass spectrometry; and (4) validate CRL/DUB candidates in preclinical mouse models and defined patient cohorts as to their disease relevance.
We expect that our interdisciplinary approach will unravel the overall role of the UPS in the pathophysiology, evolution and treatment of B-cell malignancies.
Summary
B-cell malignancies are characterized by high levels of genomic instability, which critically contribute to their pathogenesis and evolution. Recently, the fundamental role of the ubiquitin proteasome system (UPS) in maintaining genome integrity has been appreciated. Two major new therapeutic modalities in B-cell malignancies, proteasome inhibitors and imunomodulatory drugs (IMiDs), target the UPS and demonstrate particular efficacy in multiple myeloma (MM) and mantle cell lymphoma (MCL), two incurable entities with poor prognosis. This suggests the presence of aberrant ubiquitylation events, whose identities have however remained mostly elusive.
Our recent studies identify fundamental roles of orphan ubiquitin ligases of the Cullin Ring ligase family (CRLs) and their counterparts, the deubiquitylating enzymes (DUBs) in the cellular DNA damage response machinery, and characterize these candidates as novel oncogenes or tumour suppressors in MM and MCL. These findings provide the foundation for our hypothesis that deregulated ubiquitylation events involving CRLs and DUBs have a far reaching impact on the pathogenesis of B-cell malignancies and can serve as new therapeutic targets and biomarkers.
We therefore propose a multistep strategy in which we will (1) characterize previously orphan CRLs and DUBs, which we have distinguished as candidate oncogenes and tumour suppressors in MM (FBXO3, USP24), MCL (FBXO25), or MM and MCL (CRBN), respectively; (2) decipher the global role of CRLs and DUBs in MM and MCL using defined genetic screens; (3) identify relevant substrates of CRLs/DUBs discovered in (2) using mass spectrometry; and (4) validate CRL/DUB candidates in preclinical mouse models and defined patient cohorts as to their disease relevance.
We expect that our interdisciplinary approach will unravel the overall role of the UPS in the pathophysiology, evolution and treatment of B-cell malignancies.
Max ERC Funding
1 973 255 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
Project acronym BETAIMAGE
Project An in vivo imaging approach to understand pancreatic beta-cell signal-transduction
Researcher (PI) Per-Olof Berggren
Host Institution (HI) KAROLINSKA INSTITUTET
Call Details Advanced Grant (AdG), LS4, ERC-2013-ADG
Summary The challenge in cell physiology/pathology today is to translate in vitro findings to the living organism. We have developed a unique approach where signal-transduction can be investigated in vivo non-invasively, longitudinally at single cell resolution, using the anterior chamber of the eye as a natural body window for imaging. We will use this approach to understand how the universally important and highly complex signal Ca2+ is regulated in the pancreatic beta-cell, while localized in the vascularized and innervated islet of Langerhans, and how that affects the insulin secretory machinery in vivo. Engrafted islets in the eye take on identical innervation- and vascularization patterns as those in the pancreas and are proficient in regulating glucose homeostasis in the animal. Since the pancreatic islet constitutes a micro-organ, this imaging approach offers a seminal model system to understand Ca2+ signaling in individual cells at the organ level in real life. We will test the hypothesis that the Ca2+-signal has a key role in pancreatic beta-cell function and survival in vivo and that perturbation in the Ca2+-signal serves as a common denominator for beta-cell pathology associated with impaired glucose homeostasis and diabetes. Of special interest is how innervation impacts on Ca2+-dynamics and the integration of autocrine, paracrine and endocrine signals in fine-tuning the Ca2+-signal with regard to beta-cell function and survival. We aim to define key defects in the machinery regulating Ca2+-dynamics in association with the autoimmune reaction, inflammation and obesity eventually resulting in diabetes. Our imaging platform will be applied to clarify in vivo regulation of Ca2+-dynamics in both healthy and diabetic human beta-cells. To define novel drugable targets for treatment of diabetes, it is crucial to identify similarities and differences in the molecular machinery regulating the in vivo Ca2+-signal in the human and in the rodent beta-cell.
Summary
The challenge in cell physiology/pathology today is to translate in vitro findings to the living organism. We have developed a unique approach where signal-transduction can be investigated in vivo non-invasively, longitudinally at single cell resolution, using the anterior chamber of the eye as a natural body window for imaging. We will use this approach to understand how the universally important and highly complex signal Ca2+ is regulated in the pancreatic beta-cell, while localized in the vascularized and innervated islet of Langerhans, and how that affects the insulin secretory machinery in vivo. Engrafted islets in the eye take on identical innervation- and vascularization patterns as those in the pancreas and are proficient in regulating glucose homeostasis in the animal. Since the pancreatic islet constitutes a micro-organ, this imaging approach offers a seminal model system to understand Ca2+ signaling in individual cells at the organ level in real life. We will test the hypothesis that the Ca2+-signal has a key role in pancreatic beta-cell function and survival in vivo and that perturbation in the Ca2+-signal serves as a common denominator for beta-cell pathology associated with impaired glucose homeostasis and diabetes. Of special interest is how innervation impacts on Ca2+-dynamics and the integration of autocrine, paracrine and endocrine signals in fine-tuning the Ca2+-signal with regard to beta-cell function and survival. We aim to define key defects in the machinery regulating Ca2+-dynamics in association with the autoimmune reaction, inflammation and obesity eventually resulting in diabetes. Our imaging platform will be applied to clarify in vivo regulation of Ca2+-dynamics in both healthy and diabetic human beta-cells. To define novel drugable targets for treatment of diabetes, it is crucial to identify similarities and differences in the molecular machinery regulating the in vivo Ca2+-signal in the human and in the rodent beta-cell.
Max ERC Funding
2 499 590 €
Duration
Start date: 2014-03-01, End date: 2019-02-28
Project acronym BetaRegeneration
Project Induction of Insulin-producing beta-cells Regeneration in vivo
Researcher (PI) Patrick Collombat
Host Institution (HI) INSTITUT NATIONAL DE LA SANTE ET DE LA RECHERCHE MEDICALE
Call Details Starting Grant (StG), LS4, ERC-2011-StG_20101109
Summary Diabetes has become one of the most widespread metabolic disorders with epidemic dimensions affecting almost 6% of the world’s population. Despite modern treatments, the life expectancy of patients with Type 1 diabetes remains reduced as compared to healthy subjects. There is therefore a need for alternative therapies. Towards this aim, using the mouse, we recently demonstrated that the in vivo forced expression of a single factor in pancreatic alpha-cells is sufficient to induce a continuous regeneration of alpha-cells and their subsequent conversion into beta-like cells, such converted cells being capable of reversing the consequences of chemically-induced diabetes in vivo (Collombat et al. Cell, 2009).
The PI and his team therefore propose to further decipher the mechanisms involved in this alpha-cell-mediated beta-cell regeneration process and determine whether this approach may be applied to adult animals and whether it would efficiently reverse Type 1 diabetes. Furthermore, a major effort will be made to verify whether our findings could be translated to human. Specifically, we will use a tri-partite approach to address the following issues: (1) Can the in vivo alpha-cell-mediated beta-cell regeneration be induced in adults mice? What would be the genetic determinants involved? (2) Can alpha-cell-mediated beta-cell regeneration reverse diabetes in the NOD Type 1 diabetes mouse model? (3) Can adult human alpha-cells be converted into beta-like cells?
Together, these ambitious objectives will most certainly allow us to gain new insight into the mechanisms defining the identity and the reprogramming capabilities of mouse and human endocrine cells and may thereby open new avenues for the treatment of diabetes. Similarly, the determination of the molecular triggers implicated in the beta-cell regeneration observed in our diabetic mice may lead to exciting new findings, including the identification of “drugable” targets of importance for human diabetic patients.
Summary
Diabetes has become one of the most widespread metabolic disorders with epidemic dimensions affecting almost 6% of the world’s population. Despite modern treatments, the life expectancy of patients with Type 1 diabetes remains reduced as compared to healthy subjects. There is therefore a need for alternative therapies. Towards this aim, using the mouse, we recently demonstrated that the in vivo forced expression of a single factor in pancreatic alpha-cells is sufficient to induce a continuous regeneration of alpha-cells and their subsequent conversion into beta-like cells, such converted cells being capable of reversing the consequences of chemically-induced diabetes in vivo (Collombat et al. Cell, 2009).
The PI and his team therefore propose to further decipher the mechanisms involved in this alpha-cell-mediated beta-cell regeneration process and determine whether this approach may be applied to adult animals and whether it would efficiently reverse Type 1 diabetes. Furthermore, a major effort will be made to verify whether our findings could be translated to human. Specifically, we will use a tri-partite approach to address the following issues: (1) Can the in vivo alpha-cell-mediated beta-cell regeneration be induced in adults mice? What would be the genetic determinants involved? (2) Can alpha-cell-mediated beta-cell regeneration reverse diabetes in the NOD Type 1 diabetes mouse model? (3) Can adult human alpha-cells be converted into beta-like cells?
Together, these ambitious objectives will most certainly allow us to gain new insight into the mechanisms defining the identity and the reprogramming capabilities of mouse and human endocrine cells and may thereby open new avenues for the treatment of diabetes. Similarly, the determination of the molecular triggers implicated in the beta-cell regeneration observed in our diabetic mice may lead to exciting new findings, including the identification of “drugable” targets of importance for human diabetic patients.
Max ERC Funding
1 500 000 €
Duration
Start date: 2012-01-01, End date: 2016-12-31
Project acronym BETATOBETA
Project The molecular basis of pancreatic beta cell replication
Researcher (PI) Yuval Dor
Host Institution (HI) THE HEBREW UNIVERSITY OF JERUSALEM
Call Details Starting Grant (StG), LS4, ERC-2010-StG_20091118
Summary A fundamental challenge of pancreas biology is to understand and manipulate the determinants of beta cell mass. The homeostatic maintenance of adult beta cell mass relies largely on replication of differentiated beta cells, but the triggers and signaling pathways involved remain poorly understood. Here I propose to investigate the physiological and molecular mechanisms that control beta cell replication. First, novel transgenic mouse tools will be used to isolate live replicating beta cells and to examine the genetic program of beta cell replication in vivo. Information gained will provide insights into the molecular biology of cell division in vivo. Additionally, these experiments will address critical unresolved questions in beta cell biology, for example whether duplication involves transient dedifferentiation. Second, genetic and pharmacologic tools will be used to dissect the signaling pathways controlling the entry of beta cells to the cell division cycle, with emphasis on the roles of glucose and insulin, the key physiological input and output of beta cells. The expected outcome of these studies is a detailed molecular understanding of the homeostatic maintenance of beta cell mass, describing how beta cell function is linked to beta cell number in vivo. This may suggest new targets and concepts for pharmacologic intervention, towards the development of regenerative therapy strategies in diabetes. More generally, the experiments will shed light on one of the greatest mysteries of developmental biology, namely how organs achieve and maintain their correct size. A fundamental challenge of pancreas biology is to understand and manipulate the determinants of beta cell mass. The homeostatic maintenance of adult beta cell mass relies largely on replication of differentiated beta cells, but the triggers and signaling pathways involved remain poorly understood. Here I propose to investigate the physiological and molecular mechanisms that control beta cell replication. First, novel transgenic mouse tools will be used to isolate live replicating beta cells and to examine the genetic program of beta cell replication in vivo. Information gained will provide insights into the molecular biology of cell division in vivo. Additionally, these experiments will address critical unresolved questions in beta cell biology, for example whether duplication involves transient dedifferentiation. Second, genetic and pharmacologic tools will be used to dissect the signaling pathways controlling the entry of beta cells to the cell division cycle, with emphasis on the roles of glucose and insulin, the key physiological input and output of beta cells. The expected outcome of these studies is a detailed molecular understanding of the homeostatic maintenance of beta cell mass, describing how beta cell function is linked to beta cell number in vivo. This may suggest new targets and concepts for pharmacologic intervention, towards the development of regenerative therapy strategies in diabetes. More generally, the experiments will shed light on one of the greatest mysteries of developmental biology, namely how organs achieve and maintain their correct size.
Summary
A fundamental challenge of pancreas biology is to understand and manipulate the determinants of beta cell mass. The homeostatic maintenance of adult beta cell mass relies largely on replication of differentiated beta cells, but the triggers and signaling pathways involved remain poorly understood. Here I propose to investigate the physiological and molecular mechanisms that control beta cell replication. First, novel transgenic mouse tools will be used to isolate live replicating beta cells and to examine the genetic program of beta cell replication in vivo. Information gained will provide insights into the molecular biology of cell division in vivo. Additionally, these experiments will address critical unresolved questions in beta cell biology, for example whether duplication involves transient dedifferentiation. Second, genetic and pharmacologic tools will be used to dissect the signaling pathways controlling the entry of beta cells to the cell division cycle, with emphasis on the roles of glucose and insulin, the key physiological input and output of beta cells. The expected outcome of these studies is a detailed molecular understanding of the homeostatic maintenance of beta cell mass, describing how beta cell function is linked to beta cell number in vivo. This may suggest new targets and concepts for pharmacologic intervention, towards the development of regenerative therapy strategies in diabetes. More generally, the experiments will shed light on one of the greatest mysteries of developmental biology, namely how organs achieve and maintain their correct size. A fundamental challenge of pancreas biology is to understand and manipulate the determinants of beta cell mass. The homeostatic maintenance of adult beta cell mass relies largely on replication of differentiated beta cells, but the triggers and signaling pathways involved remain poorly understood. Here I propose to investigate the physiological and molecular mechanisms that control beta cell replication. First, novel transgenic mouse tools will be used to isolate live replicating beta cells and to examine the genetic program of beta cell replication in vivo. Information gained will provide insights into the molecular biology of cell division in vivo. Additionally, these experiments will address critical unresolved questions in beta cell biology, for example whether duplication involves transient dedifferentiation. Second, genetic and pharmacologic tools will be used to dissect the signaling pathways controlling the entry of beta cells to the cell division cycle, with emphasis on the roles of glucose and insulin, the key physiological input and output of beta cells. The expected outcome of these studies is a detailed molecular understanding of the homeostatic maintenance of beta cell mass, describing how beta cell function is linked to beta cell number in vivo. This may suggest new targets and concepts for pharmacologic intervention, towards the development of regenerative therapy strategies in diabetes. More generally, the experiments will shed light on one of the greatest mysteries of developmental biology, namely how organs achieve and maintain their correct size.
Max ERC Funding
1 445 000 €
Duration
Start date: 2010-09-01, End date: 2015-08-31
Project acronym BEYOND
Project METABOLIC BASIS OF NEURODEGENERATIVE DISEASE
Researcher (PI) Thomas Franz Erich Willnow
Host Institution (HI) MAX DELBRUECK CENTRUM FUER MOLEKULARE MEDIZIN IN DER HELMHOLTZ-GEMEINSCHAFT (MDC)
Call Details Advanced Grant (AdG), LS4, ERC-2013-ADG
Summary Alzheimer disease (AD) is the most common form of age-related dementia affecting millions of patients worldwide. Disturbingly, disorders of lipid and glucose metabolism emerge as major risk factors for onset and progression of neurodegeneration in the human population. Thus, an increasing life expectance combined with an observable rise in metabolic disturbances is expected to turn AD into one of the most serious health problems for future generations. Still, the molecular mechanisms whereby dysregulation of glucose and lipid homeostasis elicits noxious insults to the brain remain poorly understood. We characterized a novel class of intracellular sorting receptors, termed VPS10P domain receptors with dual roles in regulation of neuronal viability and function, but also in modulation of glucose and lipid homeostasis. Our proposal aims at elucidating an important yet poorly understood link between metabolism and neurodegeneration that converges on these receptors. Our approach is unique and novel in several ways. Thematically, our studies focus on a novel class of receptors previously not considered. Based on the receptors’ ability to act as sorting proteins, we propose faulty protein trafficking as a major unifying concept underlying neurodegenerative and metabolic disorders. Conceptually, our approach relies on the interdisciplinary effort of neuroscientists and metabolism researchers working jointly on pathophysiological pathways converging on these receptors. Through this effort, we are confident to gain important insights into the crosstalk between brain and peripheral tissues, and to elucidate pathways common to metabolic disturbances and dementia, two prevailing degenerative disorders inflicting our societies.
Summary
Alzheimer disease (AD) is the most common form of age-related dementia affecting millions of patients worldwide. Disturbingly, disorders of lipid and glucose metabolism emerge as major risk factors for onset and progression of neurodegeneration in the human population. Thus, an increasing life expectance combined with an observable rise in metabolic disturbances is expected to turn AD into one of the most serious health problems for future generations. Still, the molecular mechanisms whereby dysregulation of glucose and lipid homeostasis elicits noxious insults to the brain remain poorly understood. We characterized a novel class of intracellular sorting receptors, termed VPS10P domain receptors with dual roles in regulation of neuronal viability and function, but also in modulation of glucose and lipid homeostasis. Our proposal aims at elucidating an important yet poorly understood link between metabolism and neurodegeneration that converges on these receptors. Our approach is unique and novel in several ways. Thematically, our studies focus on a novel class of receptors previously not considered. Based on the receptors’ ability to act as sorting proteins, we propose faulty protein trafficking as a major unifying concept underlying neurodegenerative and metabolic disorders. Conceptually, our approach relies on the interdisciplinary effort of neuroscientists and metabolism researchers working jointly on pathophysiological pathways converging on these receptors. Through this effort, we are confident to gain important insights into the crosstalk between brain and peripheral tissues, and to elucidate pathways common to metabolic disturbances and dementia, two prevailing degenerative disorders inflicting our societies.
Max ERC Funding
2 415 229 €
Duration
Start date: 2014-02-01, End date: 2019-01-31
Project acronym BIOCARD
Project Deep BIOmodeling of human CARDiogenesis
Researcher (PI) Alessandra MORETTI
Host Institution (HI) KLINIKUM RECHTS DER ISAR DER TECHNISCHEN UNIVERSITAT MUNCHEN
Call Details Advanced Grant (AdG), LS4, ERC-2017-ADG
Summary The heart is one of the first and most complex organs formed during human embryogenesis. While its anatomy and physiology have been extensively studied over centuries, the normal development of human heart and dysregulation in disease still remain poorly understood at the molecular/cellular level. Stem cell technologies hold promise for modelling development, analysing disease mechanisms, and developing potential therapies. By combining multidisciplinary approaches centred on human induced pluripotent stem cells (hiPSCs), BIOCARD aims at decoding the cellular and molecular principles of human cardiogenesis and developing advanced inter-chimeric human-pig models of cardiac development and disease. State-of-the-art genetic modification techniques and functional genomics will be used to establish a molecular atlas of cell type intermediates of human cardiogenesis in vitro and unravel how their proliferation, differentiation and lineage choice are regulated in health and disease. This in vitro approach will be complemented by detailed analyses of how distinct hiPSC-derived cardiac progenitor populations commit and contribute to specific cardiac compartments in interspecies chimeric hearts in vivo. Finally, we will capitalize on the novel concept that combinations of different well-defined hiPSC-derived cardiac progenitor pools with timely-matched, native extracellular matrix from embryonic hearts will accomplish for the first time the realization of human heart organoids as 3D culture systems of developing heart structures. Clearly, BIOCARD will open game-changing opportunities for devising novel biomedical applications, such as human heart chamber-specific disease modelling, large-scale drug testing in appropriate human 3D cardiac bio-mimics, and regenerative cell therapies based on functional ventricular-muscle patches and direct cell conversion in vivo.
Summary
The heart is one of the first and most complex organs formed during human embryogenesis. While its anatomy and physiology have been extensively studied over centuries, the normal development of human heart and dysregulation in disease still remain poorly understood at the molecular/cellular level. Stem cell technologies hold promise for modelling development, analysing disease mechanisms, and developing potential therapies. By combining multidisciplinary approaches centred on human induced pluripotent stem cells (hiPSCs), BIOCARD aims at decoding the cellular and molecular principles of human cardiogenesis and developing advanced inter-chimeric human-pig models of cardiac development and disease. State-of-the-art genetic modification techniques and functional genomics will be used to establish a molecular atlas of cell type intermediates of human cardiogenesis in vitro and unravel how their proliferation, differentiation and lineage choice are regulated in health and disease. This in vitro approach will be complemented by detailed analyses of how distinct hiPSC-derived cardiac progenitor populations commit and contribute to specific cardiac compartments in interspecies chimeric hearts in vivo. Finally, we will capitalize on the novel concept that combinations of different well-defined hiPSC-derived cardiac progenitor pools with timely-matched, native extracellular matrix from embryonic hearts will accomplish for the first time the realization of human heart organoids as 3D culture systems of developing heart structures. Clearly, BIOCARD will open game-changing opportunities for devising novel biomedical applications, such as human heart chamber-specific disease modelling, large-scale drug testing in appropriate human 3D cardiac bio-mimics, and regenerative cell therapies based on functional ventricular-muscle patches and direct cell conversion in vivo.
Max ERC Funding
2 285 625 €
Duration
Start date: 2018-09-01, End date: 2023-08-31
Project acronym BODY-OWNERSHIP
Project Neural mechanisms of body ownership and the projection of ownership onto artificial bodies
Researcher (PI) H. Henrik Ehrsson
Host Institution (HI) KAROLINSKA INSTITUTET
Call Details Starting Grant (StG), LS4, ERC-2007-StG
Summary How do we recognize that our limbs are part of our own body, and why do we feel that one’s self is located inside the body? These fundamental questions have been discussed in theology, philosophy and psychology for millennia. The aim of my ground-breaking research programme is to identify the neuronal mechanisms that produce the sense of ownership of the body, and the processes responsible for the feeling that the self is located inside the physical body. To solve these questions I will adopt an inter-disciplinary approach using state-of-the-art methods from the fields of imaging neuroscience, experimental psychology, computer science and robotics. My first hypothesis is that the mechanism for body ownership is the integration of information from different sensory modalities (vision, touch and muscle sense) in multi-sensory brain areas (ventral premotor and intraparietal cortex). My second hypothesis is that the sense of where you are located in the environment is mediated by allocentric spatial representations in medial temporal lobes. To test this, I will use perceptual illusions and virtual-reality techniques that allow me to manipulate body ownership and the perceived location of the self, in conjunction with non-invasive recordings of brain activity in healthy humans. Functional magnetic resonance imaging and electroencephalography will be used to identify the neuronal correlates of ownership and ‘in-body experiences’, while transcranial magnetic stimulation will be used to examine the causal relationship between neural activity and ownership. It is no overstatement to say that my pioneering work could define a new sub-field in cognitive neuroscience dealing with how the brain represents the self. These basic scientific discoveries will be used in new frontier applications. For example, the development of a prosthetic limb that feels just like a real limb, and a method of controlling humanoid robots by the illusion of ‘becoming the robot’.
Summary
How do we recognize that our limbs are part of our own body, and why do we feel that one’s self is located inside the body? These fundamental questions have been discussed in theology, philosophy and psychology for millennia. The aim of my ground-breaking research programme is to identify the neuronal mechanisms that produce the sense of ownership of the body, and the processes responsible for the feeling that the self is located inside the physical body. To solve these questions I will adopt an inter-disciplinary approach using state-of-the-art methods from the fields of imaging neuroscience, experimental psychology, computer science and robotics. My first hypothesis is that the mechanism for body ownership is the integration of information from different sensory modalities (vision, touch and muscle sense) in multi-sensory brain areas (ventral premotor and intraparietal cortex). My second hypothesis is that the sense of where you are located in the environment is mediated by allocentric spatial representations in medial temporal lobes. To test this, I will use perceptual illusions and virtual-reality techniques that allow me to manipulate body ownership and the perceived location of the self, in conjunction with non-invasive recordings of brain activity in healthy humans. Functional magnetic resonance imaging and electroencephalography will be used to identify the neuronal correlates of ownership and ‘in-body experiences’, while transcranial magnetic stimulation will be used to examine the causal relationship between neural activity and ownership. It is no overstatement to say that my pioneering work could define a new sub-field in cognitive neuroscience dealing with how the brain represents the self. These basic scientific discoveries will be used in new frontier applications. For example, the development of a prosthetic limb that feels just like a real limb, and a method of controlling humanoid robots by the illusion of ‘becoming the robot’.
Max ERC Funding
909 850 €
Duration
Start date: 2008-12-01, End date: 2013-11-30
Project acronym BONEPHAGY
Project Defining the role of the FGF – autophagy axis in bone physiology
Researcher (PI) Carmine SETTEMBRE
Host Institution (HI) FONDAZIONE TELETHON
Call Details Starting Grant (StG), LS4, ERC-2016-STG
Summary Autophagy is a fundamental cellular catabolic process deputed to the degradation and recycling of a variety of intracellular materials. Autophagy plays a significant role in multiple human physio-pathological processes and is now emerging as a critical regulator of skeletal development and homeostasis. We have discovered that during postnatal development in mice, the growth factor FGF18 induces autophagy in the chondrocyte cells of the growth plate to regulate the secretion of type II collagen, a major component of cartilaginous extracellular matrix. The FGF signaling pathways play crucial roles during skeletal development and maintenance and are deregulated in many skeletal disorders. Hence our findings may offer the unique opportunity to uncover new molecular mechanisms through which FGF pathways regulate skeletal development and maintenance and to identify new targets for the treatment of FGF-related skeletal disorders. In this grant application we propose to study the role played by the different FGF ligands and receptors on autophagy regulation and to investigate the physiological relevance of these findings in the context of skeletal growth, homeostasis and maintenance. We will also investigate the intracellular machinery that links FGF signalling pathways to the regulation of autophagy. In addition, we generated preliminary data showing an impairment of autophagy in chondrocyte models of Achondroplasia (ACH) and Thanathoporic dysplasia, two skeletal disorders caused by mutations in FGFR3. We propose to study the role of autophagy in the pathogenesis of FGFR3-related dwarfisms and explore the pharmacological modulation of autophagy as new therapeutic approach for achondroplasia. This application, which combines cell biology, mouse genetics and pharmacological approaches, has the potential to shed light on new mechanisms involved in organismal development and homeostasis, which could be targeted to treat bone and cartilage diseases.
Summary
Autophagy is a fundamental cellular catabolic process deputed to the degradation and recycling of a variety of intracellular materials. Autophagy plays a significant role in multiple human physio-pathological processes and is now emerging as a critical regulator of skeletal development and homeostasis. We have discovered that during postnatal development in mice, the growth factor FGF18 induces autophagy in the chondrocyte cells of the growth plate to regulate the secretion of type II collagen, a major component of cartilaginous extracellular matrix. The FGF signaling pathways play crucial roles during skeletal development and maintenance and are deregulated in many skeletal disorders. Hence our findings may offer the unique opportunity to uncover new molecular mechanisms through which FGF pathways regulate skeletal development and maintenance and to identify new targets for the treatment of FGF-related skeletal disorders. In this grant application we propose to study the role played by the different FGF ligands and receptors on autophagy regulation and to investigate the physiological relevance of these findings in the context of skeletal growth, homeostasis and maintenance. We will also investigate the intracellular machinery that links FGF signalling pathways to the regulation of autophagy. In addition, we generated preliminary data showing an impairment of autophagy in chondrocyte models of Achondroplasia (ACH) and Thanathoporic dysplasia, two skeletal disorders caused by mutations in FGFR3. We propose to study the role of autophagy in the pathogenesis of FGFR3-related dwarfisms and explore the pharmacological modulation of autophagy as new therapeutic approach for achondroplasia. This application, which combines cell biology, mouse genetics and pharmacological approaches, has the potential to shed light on new mechanisms involved in organismal development and homeostasis, which could be targeted to treat bone and cartilage diseases.
Max ERC Funding
1 586 430 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
