Project acronym AXIAL.EC
Project PRINCIPLES OF AXIAL POLARITY-DRIVEN VASCULAR PATTERNING
Researcher (PI) Claudio Franco
Host Institution (HI) INSTITUTO DE MEDICINA MOLECULAR JOAO LOBO ANTUNES
Call Details Starting Grant (StG), LS4, ERC-2015-STG
Summary The formation of a functional patterned vascular network is essential for development, tissue growth and organ physiology. Several human vascular disorders arise from the mis-patterning of blood vessels, such as arteriovenous malformations, aneurysms and diabetic retinopathy. Although blood flow is recognised as a stimulus for vascular patterning, very little is known about the molecular mechanisms that regulate endothelial cell behaviour in response to flow and promote vascular patterning.
Recently, we uncovered that endothelial cells migrate extensively in the immature vascular network, and that endothelial cells polarise against the blood flow direction. Here, we put forward the hypothesis that vascular patterning is dependent on the polarisation and migration of endothelial cells against the flow direction, in a continuous flux of cells going from low-shear stress to high-shear stress regions. We will establish new reporter mouse lines to observe and manipulate endothelial polarity in vivo in order to investigate how polarisation and coordination of endothelial cells movements are orchestrated to generate vascular patterning. We will manipulate cell polarity using mouse models to understand the importance of cell polarisation in vascular patterning. Also, using a unique zebrafish line allowing analysis of endothelial cell polarity, we will perform a screen to identify novel regulators of vascular patterning. Finally, we will explore the hypothesis that defective flow-dependent endothelial polarisation underlies arteriovenous malformations using two genetic models.
This integrative approach, based on high-resolution imaging and unique experimental models, will provide a unifying model defining the cellular and molecular principles involved in vascular patterning. Given the physiological relevance of vascular patterning in health and disease, this research plan will set the basis for the development of novel clinical therapies targeting vascular disorders.
Summary
The formation of a functional patterned vascular network is essential for development, tissue growth and organ physiology. Several human vascular disorders arise from the mis-patterning of blood vessels, such as arteriovenous malformations, aneurysms and diabetic retinopathy. Although blood flow is recognised as a stimulus for vascular patterning, very little is known about the molecular mechanisms that regulate endothelial cell behaviour in response to flow and promote vascular patterning.
Recently, we uncovered that endothelial cells migrate extensively in the immature vascular network, and that endothelial cells polarise against the blood flow direction. Here, we put forward the hypothesis that vascular patterning is dependent on the polarisation and migration of endothelial cells against the flow direction, in a continuous flux of cells going from low-shear stress to high-shear stress regions. We will establish new reporter mouse lines to observe and manipulate endothelial polarity in vivo in order to investigate how polarisation and coordination of endothelial cells movements are orchestrated to generate vascular patterning. We will manipulate cell polarity using mouse models to understand the importance of cell polarisation in vascular patterning. Also, using a unique zebrafish line allowing analysis of endothelial cell polarity, we will perform a screen to identify novel regulators of vascular patterning. Finally, we will explore the hypothesis that defective flow-dependent endothelial polarisation underlies arteriovenous malformations using two genetic models.
This integrative approach, based on high-resolution imaging and unique experimental models, will provide a unifying model defining the cellular and molecular principles involved in vascular patterning. Given the physiological relevance of vascular patterning in health and disease, this research plan will set the basis for the development of novel clinical therapies targeting vascular disorders.
Max ERC Funding
1 618 750 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
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 BYPASSWITHOUTSURGERY
Project Reaching the effects of gastric bypass on diabetes and obesity without surgery
Researcher (PI) Jens Juul Holst
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Advanced Grant (AdG), LS4, ERC-2015-AdG
Summary Gastric bypass surgery results in massive weight loss and diabetes remission. The effect is superior to intensive medical treatment, showing that there are mechanisms within the body that can cure diabetes and obesity. Revealing the nature of these mechanisms could lead to new, cost-efficient, similarly effective, non-invasive treatments of these conditions. The hypothesis is that hyper-secretion of a number of gut hormones mediates the effect of surgery, as indicated by a series of our recent studies, demonstrating that hypersecretion of GLP-1, a hormone discovered in my laboratory and basis for the antidiabetic medication of millions of patients, is essential for the improved insulin secretion and glucose tolerance. But what are the mechanisms behind the up to 30-fold elevations in secretion of these hormones following surgery? Constantly with a translational scope, all elements involved in these responses will be addressed in this project, from detailed analysis of food items responsible for hormone secretion, to identification of the responsible regions of the gut, and to the molecular mechanisms leading to hypersecretion. Novel approaches for studies of human gut hormone secreting cells, including specific expression analysis, are combined with our advanced and unique isolated perfused gut preparations, the only tool that can provide physiologically relevant results with a translational potential regarding regulation of hormone secretion in the gut. This will lead to further groundbreaking experimental attempts to mimic and engage the identified mechanisms, creating similar hypersecretion and obtaining similar improvements as the operations in patients with obesity and diabetes. Based on our profound knowledge of gut hormone biology accumulated through decades of intensive and successful research and our successful elucidation of the antidiabetic actions of gastric bypass surgery, we are in a unique position to reach this ambitious goal.
Summary
Gastric bypass surgery results in massive weight loss and diabetes remission. The effect is superior to intensive medical treatment, showing that there are mechanisms within the body that can cure diabetes and obesity. Revealing the nature of these mechanisms could lead to new, cost-efficient, similarly effective, non-invasive treatments of these conditions. The hypothesis is that hyper-secretion of a number of gut hormones mediates the effect of surgery, as indicated by a series of our recent studies, demonstrating that hypersecretion of GLP-1, a hormone discovered in my laboratory and basis for the antidiabetic medication of millions of patients, is essential for the improved insulin secretion and glucose tolerance. But what are the mechanisms behind the up to 30-fold elevations in secretion of these hormones following surgery? Constantly with a translational scope, all elements involved in these responses will be addressed in this project, from detailed analysis of food items responsible for hormone secretion, to identification of the responsible regions of the gut, and to the molecular mechanisms leading to hypersecretion. Novel approaches for studies of human gut hormone secreting cells, including specific expression analysis, are combined with our advanced and unique isolated perfused gut preparations, the only tool that can provide physiologically relevant results with a translational potential regarding regulation of hormone secretion in the gut. This will lead to further groundbreaking experimental attempts to mimic and engage the identified mechanisms, creating similar hypersecretion and obtaining similar improvements as the operations in patients with obesity and diabetes. Based on our profound knowledge of gut hormone biology accumulated through decades of intensive and successful research and our successful elucidation of the antidiabetic actions of gastric bypass surgery, we are in a unique position to reach this ambitious goal.
Max ERC Funding
2 500 000 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
Project acronym CaNANObinoids
Project From Peripheralized to Cell- and Organelle-Targeted Medicine: The 3rd Generation of Cannabinoid-1 Receptor Antagonists for the Treatment of Chronic Kidney Disease
Researcher (PI) Yossef Tam
Host Institution (HI) THE HEBREW UNIVERSITY OF JERUSALEM
Call Details Starting Grant (StG), LS4, ERC-2015-STG
Summary Clinical experience with globally-acting cannabinoid-1 receptor (CB1R) antagonists revealed the benefits of blocking CB1Rs for the treatment of obesity and diabetes. However, their use is hampered by increased CNS-mediated side effects. Recently, I have demonstrated that peripherally-restricted CB1R antagonists have the potential to treat the metabolic syndrome without eliciting these adverse effects. While these results are promising and are currently being developed into the clinic, our ability to rationally design CB1R blockers that would target a diseased organ is limited.
The current proposal aims to develop and test cell- and organelle-specific CB1R antagonists. To establish this paradigm, I will focus our interest on the kidney, since chronic kidney disease (CKD) is the leading cause of increased morbidity and mortality of patients with diabetes. Our first goal will be to characterize the obligatory role of the renal proximal tubular CB1R in the pathogenesis of diabetic renal complications. Next, we will attempt to link renal proximal CB1R with diabetic mitochondrial dysfunction. Finally, we will develop proximal tubular (cell-specific) and mitochondrial (organelle-specific) CB1R blockers and test their effectiveness in treating CKD. To that end, we will encapsulate CB1R blockers into biocompatible polymeric nanoparticles that will serve as targeted drug delivery systems, via their conjugation to targeting ligands.
The implications of this work are far reaching as they will (i) point to renal proximal tubule CB1R as a novel target for CKD; (ii) identify mitochondrial CB1R as a new player in the regulation of proximal tubular cell function, and (iii) eventually become the drug-of-choice in treating diabetic CKD and its comorbidities. Moreover, this work will lead to the development of a novel organ-specific drug delivery system for CB1R blockers, which could be then exploited in other tissues affected by obesity, diabetes and the metabolic syndrome.
Summary
Clinical experience with globally-acting cannabinoid-1 receptor (CB1R) antagonists revealed the benefits of blocking CB1Rs for the treatment of obesity and diabetes. However, their use is hampered by increased CNS-mediated side effects. Recently, I have demonstrated that peripherally-restricted CB1R antagonists have the potential to treat the metabolic syndrome without eliciting these adverse effects. While these results are promising and are currently being developed into the clinic, our ability to rationally design CB1R blockers that would target a diseased organ is limited.
The current proposal aims to develop and test cell- and organelle-specific CB1R antagonists. To establish this paradigm, I will focus our interest on the kidney, since chronic kidney disease (CKD) is the leading cause of increased morbidity and mortality of patients with diabetes. Our first goal will be to characterize the obligatory role of the renal proximal tubular CB1R in the pathogenesis of diabetic renal complications. Next, we will attempt to link renal proximal CB1R with diabetic mitochondrial dysfunction. Finally, we will develop proximal tubular (cell-specific) and mitochondrial (organelle-specific) CB1R blockers and test their effectiveness in treating CKD. To that end, we will encapsulate CB1R blockers into biocompatible polymeric nanoparticles that will serve as targeted drug delivery systems, via their conjugation to targeting ligands.
The implications of this work are far reaching as they will (i) point to renal proximal tubule CB1R as a novel target for CKD; (ii) identify mitochondrial CB1R as a new player in the regulation of proximal tubular cell function, and (iii) eventually become the drug-of-choice in treating diabetic CKD and its comorbidities. Moreover, this work will lead to the development of a novel organ-specific drug delivery system for CB1R blockers, which could be then exploited in other tissues affected by obesity, diabetes and the metabolic syndrome.
Max ERC Funding
1 500 000 €
Duration
Start date: 2016-04-01, End date: 2021-03-31
Project acronym CD40-INN
Project CD40 goes innate: defining and targeting CD40 signaling intermediates in the macrophage to treat atherosclerosis
Researcher (PI) Esther Lutgens Leiner
Host Institution (HI) ACADEMISCH MEDISCH CENTRUM BIJ DE UNIVERSITEIT VAN AMSTERDAM
Call Details Consolidator Grant (CoG), LS4, ERC-2015-CoG
Summary Atherosclerosis, the underlying cause of the majority of cardiovascular diseases (CVD), is a lipid driven, inflammatory disease of the large arteries. Despite a 25% relative risk reduction achieved by lipid-lowering treatment, the vast majority of atherosclerosis-induced CVD risk remains unaddressed. Therefore, characterizing mediators of the inflammatory aspect of atherosclerosis is a widely recognized scientific goal with great therapeutic implications.
Co-stimulatory molecules are key players in modulating immune interactions. My laboratory has defined the co-stimulatory CD40-CD40L dyad as a major driver of atherosclerosis. Inhibition of CD40, and of its interaction with the adaptor molecule TRAF6 by genetic deficiency, antibody treatment or (nanoparticle based) small molecule inhibitor (SMI) treatment, is one of the most powerful therapies to reduce atherosclerosis in a laboratory setting. Although CD40-CD40L interactions are associated with adaptive immunity, I recently identified the macrophage as a driver of CD40-induced inflammation in atherosclerosis. We will use state-of-the-art in vitro experiments, live cell-, super resolution imaging, proteomics approaches and mutant mouse models to unravel the role of macrophage CD40 in atherosclerosis. Moreover, using structure based virtual ligand screening, I will develop lead SMIs targeting macrophage CD40-signaling, which I will deliver using macrophage-targeting nanoparticles. My goal is to define the role of macrophage CD40 in inflammation and immunity and disentangle how its activation affects atherosclerosis. I will finally test the feasibility of targeting macrophage CD40-signaling as a treatment for CVD.
These studies will define the role of CD40-signaling in the innate immune system in health and (cardiovascular) disease. As components of macrophage CD40-signaling have the potential to be amenable to pharmacological manipulation, we will establish their feasibility as novel targets for (CVD) treatment.
Summary
Atherosclerosis, the underlying cause of the majority of cardiovascular diseases (CVD), is a lipid driven, inflammatory disease of the large arteries. Despite a 25% relative risk reduction achieved by lipid-lowering treatment, the vast majority of atherosclerosis-induced CVD risk remains unaddressed. Therefore, characterizing mediators of the inflammatory aspect of atherosclerosis is a widely recognized scientific goal with great therapeutic implications.
Co-stimulatory molecules are key players in modulating immune interactions. My laboratory has defined the co-stimulatory CD40-CD40L dyad as a major driver of atherosclerosis. Inhibition of CD40, and of its interaction with the adaptor molecule TRAF6 by genetic deficiency, antibody treatment or (nanoparticle based) small molecule inhibitor (SMI) treatment, is one of the most powerful therapies to reduce atherosclerosis in a laboratory setting. Although CD40-CD40L interactions are associated with adaptive immunity, I recently identified the macrophage as a driver of CD40-induced inflammation in atherosclerosis. We will use state-of-the-art in vitro experiments, live cell-, super resolution imaging, proteomics approaches and mutant mouse models to unravel the role of macrophage CD40 in atherosclerosis. Moreover, using structure based virtual ligand screening, I will develop lead SMIs targeting macrophage CD40-signaling, which I will deliver using macrophage-targeting nanoparticles. My goal is to define the role of macrophage CD40 in inflammation and immunity and disentangle how its activation affects atherosclerosis. I will finally test the feasibility of targeting macrophage CD40-signaling as a treatment for CVD.
These studies will define the role of CD40-signaling in the innate immune system in health and (cardiovascular) disease. As components of macrophage CD40-signaling have the potential to be amenable to pharmacological manipulation, we will establish their feasibility as novel targets for (CVD) treatment.
Max ERC Funding
1 999 420 €
Duration
Start date: 2016-12-01, End date: 2021-11-30
Project acronym CFS modelling
Project Chromosomal Common Fragile Sites: Unravelling their biological functions and the basis of their instability
Researcher (PI) Andres Joaquin Lopez-Contreras
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Starting Grant (StG), LS4, ERC-2015-STG
Summary Cancer and other diseases are driven by genomic alterations initiated by DNA breaks. Within our genomes, some regions are particularly prone to breakage, and these are known as common fragile sites (CFSs). CFSs are present in every person and are frequently sites of oncogenic chromosomal rearrangements. Intriguingly, despite their fragility, many CFSs are well conserved through evolution, suggesting that these regions have important physiological functions that remain elusive. My previous background in genome editing, proteomics and replication-born DNA damage has given me the tools to propose an ambitious and comprehensive plan that tackles fundamental questions on the biology of CFSs. First, we will perform a systematic analysis of the function of CFSs. Most of the CFSs contain very large genes, which has made technically difficult to dissect whether the CFS role is due to the locus itself or to the encoded gene product. However, the emergence of the CRISPR/Cas9 technology now enables the study of CFSs on a more systematic basis. We will pioneer the engineering of mammalian models harbouring large deletions at CFS loci to investigate their physiological functions at the cellular and organism levels. For those CFSs that contain genes, the cDNAs will be re-introduced at a distal locus. Using this strategy, we will be able to achieve the first comprehensive characterization of CFS roles. Second, we will develop novel targeted approaches to interrogate the chromatin-bound proteome of CFSs and its dynamics during DNA replication. Finally, and given that CFS fragility is influenced both by cell cycle checkpoints and dNTP availability, we will use mouse models to study the impact of ATR/CHK1 pathway and dNTP levels on CFS instability and cancer. Taken together, I propose an ambitious, yet feasible, project to functionally annotate and characterise these poorly understood regions of the human genome, with important potential implications for improving human health.
Summary
Cancer and other diseases are driven by genomic alterations initiated by DNA breaks. Within our genomes, some regions are particularly prone to breakage, and these are known as common fragile sites (CFSs). CFSs are present in every person and are frequently sites of oncogenic chromosomal rearrangements. Intriguingly, despite their fragility, many CFSs are well conserved through evolution, suggesting that these regions have important physiological functions that remain elusive. My previous background in genome editing, proteomics and replication-born DNA damage has given me the tools to propose an ambitious and comprehensive plan that tackles fundamental questions on the biology of CFSs. First, we will perform a systematic analysis of the function of CFSs. Most of the CFSs contain very large genes, which has made technically difficult to dissect whether the CFS role is due to the locus itself or to the encoded gene product. However, the emergence of the CRISPR/Cas9 technology now enables the study of CFSs on a more systematic basis. We will pioneer the engineering of mammalian models harbouring large deletions at CFS loci to investigate their physiological functions at the cellular and organism levels. For those CFSs that contain genes, the cDNAs will be re-introduced at a distal locus. Using this strategy, we will be able to achieve the first comprehensive characterization of CFS roles. Second, we will develop novel targeted approaches to interrogate the chromatin-bound proteome of CFSs and its dynamics during DNA replication. Finally, and given that CFS fragility is influenced both by cell cycle checkpoints and dNTP availability, we will use mouse models to study the impact of ATR/CHK1 pathway and dNTP levels on CFS instability and cancer. Taken together, I propose an ambitious, yet feasible, project to functionally annotate and characterise these poorly understood regions of the human genome, with important potential implications for improving human health.
Max ERC Funding
1 499 711 €
Duration
Start date: 2016-05-01, End date: 2021-04-30
Project acronym CLONCELLBREAST
Project CLONAL AND CELLULAR HETEROGENEITY OF BREAST CANCER AND ITS DYNAMIC EVOLUTION WITH TREATMENT
Researcher (PI) Carlos Manuel SIMAO DA SILVA CALDAS
Host Institution (HI) THE CHANCELLOR MASTERS AND SCHOLARSOF THE UNIVERSITY OF CAMBRIDGE
Call Details Advanced Grant (AdG), LS4, ERC-2015-AdG
Summary CLONAL AND CELLULAR HETEROGENEITY OF BREAST CANCER AND ITS DYNAMIC EVOLUTION WITH TREATMENT
Breast cancer remains one of the leading causes of cancer death in women. One of the greatest challenges is that breast cancer is a heterogeneous group of 10 diseases defined by genomic profiling. In addition, each tumor is composed of clones and clonal evolution underpins the successive acquisition of the hallmarks of cancer, including metastasis and resistance to therapy. Furthermore tumors display biologically and clinically relevant cellular heterogeneity: immune system, vasculature, and stroma. This cellular heterogeneity both shapes and is shaped by the malignant compartment and modulates response to therapy.
This proposal will use longitudinal studies to unravel the clonal and cellular heterogeneity of breast cancer and its dynamic evolution with treatment. The overall goal is to provide a systems level view of evolving clonal and cellular architectures in space and time along the clinical continuum of breast cancers in the clinic, leading to the discovery of new biological and clinical paradigms which will transform our understanding of the disease.
The overall approach is to capture the evolution of clonal and cellular heterogeneity of breast cancers in space and time using unique clinical cohorts where samples (biopsies and blood/plasma) are available spanning the whole disease continuum: early breast cancer surgically treated with curative intent, neo-adjuvant therapy, and matched relapse/metastasis. The 4 aims of the proposal are:
1. Characterization of the clonal and cellular heterogeneity of primary tumours from the 10 genomic driver-based breast cancer subtypes (ICs)
2. Comparative characterization of the clonal and cellular heterogeneity of matched pairs of primary and metastatic cancers
3. Characterization of the clonal and epigenetic evolution across therapy courses
4. Characterization of the immune response across therapy courses
Summary
CLONAL AND CELLULAR HETEROGENEITY OF BREAST CANCER AND ITS DYNAMIC EVOLUTION WITH TREATMENT
Breast cancer remains one of the leading causes of cancer death in women. One of the greatest challenges is that breast cancer is a heterogeneous group of 10 diseases defined by genomic profiling. In addition, each tumor is composed of clones and clonal evolution underpins the successive acquisition of the hallmarks of cancer, including metastasis and resistance to therapy. Furthermore tumors display biologically and clinically relevant cellular heterogeneity: immune system, vasculature, and stroma. This cellular heterogeneity both shapes and is shaped by the malignant compartment and modulates response to therapy.
This proposal will use longitudinal studies to unravel the clonal and cellular heterogeneity of breast cancer and its dynamic evolution with treatment. The overall goal is to provide a systems level view of evolving clonal and cellular architectures in space and time along the clinical continuum of breast cancers in the clinic, leading to the discovery of new biological and clinical paradigms which will transform our understanding of the disease.
The overall approach is to capture the evolution of clonal and cellular heterogeneity of breast cancers in space and time using unique clinical cohorts where samples (biopsies and blood/plasma) are available spanning the whole disease continuum: early breast cancer surgically treated with curative intent, neo-adjuvant therapy, and matched relapse/metastasis. The 4 aims of the proposal are:
1. Characterization of the clonal and cellular heterogeneity of primary tumours from the 10 genomic driver-based breast cancer subtypes (ICs)
2. Comparative characterization of the clonal and cellular heterogeneity of matched pairs of primary and metastatic cancers
3. Characterization of the clonal and epigenetic evolution across therapy courses
4. Characterization of the immune response across therapy courses
Max ERC Funding
2 497 660 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
Project acronym CureCKDHeart
Project Targeting perivascular myofibroblast progenitors to treat cardiac fibrosis and heart failure in chronic kidney disease
Researcher (PI) Rafael Johannes Thomas Kramann
Host Institution (HI) UNIVERSITAETSKLINIKUM AACHEN
Call Details Starting Grant (StG), LS4, ERC-2015-STG
Summary Chronic kidney disease (CKD) is a growing public health problem with a massively increased cardiovascular mortality. Patients with advanced CKD mostly die from sudden cardiac death and recurrent heart failure due to premature cardiac aging with hypertrophy, fibrosis, and capillary rarefaction. I have recently identified the long sought key cardiac myofibroblast progenitor population, an emerging breakthrough that carries the potential to develop novel targeted therapeutics. Genetic ablation of these Gli1+ perivascular progenitors ameliorates fibrosis, cardiac hypertrophy and rescues left-ventricular function. I propose that Gli1+ cells are critically involved in all major pathophysiologic changes in cardiac aging and uremic cardiomyopathy including fibrosis, hypertrophy and capillary rarefaction. I will perform state of the art genetic fate tracing, ablation and in vivo CRISPR/Cas9 genome editing experiments to untangle their complex mechanism of activation and communication with endothelial cells and cardiomyocytes promoting fibrosis, capillary rarefaction, cardiac hypertrophy and heart failure. To identify novel druggable targets I will utilize new mouse models that allow comparative transcript and proteasome profiling assays of these critical myofibroblast precusors in homeostasis, aging and premature aging in CKD. Novel assays with immortalized cardiac Gli1+ cells will allow high throughput screens to identify uremia associated factors of cell activation and inhibitory compounds to facilitate the development of novel therapeutics.
This ambitious interdisciplinary project requires the expertise of chemists, physiologists, biomedical researchers and physician scientists to develop novel targeted therapies in cardiac remodeling during aging and CKD. The passion that drives this project results from a simple emerging hypothesis: It is possible to treat heart failure and sudden cardiac death in aging and CKD by targeting perivascular myofibroblast progenitors.
Summary
Chronic kidney disease (CKD) is a growing public health problem with a massively increased cardiovascular mortality. Patients with advanced CKD mostly die from sudden cardiac death and recurrent heart failure due to premature cardiac aging with hypertrophy, fibrosis, and capillary rarefaction. I have recently identified the long sought key cardiac myofibroblast progenitor population, an emerging breakthrough that carries the potential to develop novel targeted therapeutics. Genetic ablation of these Gli1+ perivascular progenitors ameliorates fibrosis, cardiac hypertrophy and rescues left-ventricular function. I propose that Gli1+ cells are critically involved in all major pathophysiologic changes in cardiac aging and uremic cardiomyopathy including fibrosis, hypertrophy and capillary rarefaction. I will perform state of the art genetic fate tracing, ablation and in vivo CRISPR/Cas9 genome editing experiments to untangle their complex mechanism of activation and communication with endothelial cells and cardiomyocytes promoting fibrosis, capillary rarefaction, cardiac hypertrophy and heart failure. To identify novel druggable targets I will utilize new mouse models that allow comparative transcript and proteasome profiling assays of these critical myofibroblast precusors in homeostasis, aging and premature aging in CKD. Novel assays with immortalized cardiac Gli1+ cells will allow high throughput screens to identify uremia associated factors of cell activation and inhibitory compounds to facilitate the development of novel therapeutics.
This ambitious interdisciplinary project requires the expertise of chemists, physiologists, biomedical researchers and physician scientists to develop novel targeted therapies in cardiac remodeling during aging and CKD. The passion that drives this project results from a simple emerging hypothesis: It is possible to treat heart failure and sudden cardiac death in aging and CKD by targeting perivascular myofibroblast progenitors.
Max ERC Funding
1 497 888 €
Duration
Start date: 2016-05-01, End date: 2021-04-30
Project acronym DEMETINL
Project Decisions in metabolic inflammation of the liver: Adhesive interactions involved in leukocyte retention and resolution of inflammation in metabolic-inflammatory liver disease
Researcher (PI) Triantafyllos Chavakis
Host Institution (HI) TECHNISCHE UNIVERSITAET DRESDEN
Call Details Consolidator Grant (CoG), LS4, ERC-2015-CoG
Summary Resolution of acute inflammation, involving limiting further leukocyte recruitment, apoptosis and clearance
of inflammatory cells via macrophages as well as egress of the inflammatory cells, is operative in acute
inflammation but dysfunctional in chronic inflammatory disease. In the latter scenario, the retention and
activation of leukocytes in the inflamed tissue linked with failure to resolve inflammation contributes to
perpetuation of organ damage and loss of homeostasis. Interestingly, persistent inflammation in insulintarget
organs, such as the adipose tissue and the liver in the context of obesity significantly contributes to
development of insulin resistance (IR), diabetes and non-alcoholic fatty liver disease (NAFLD). So far,
investigations have mainly addressed obesity-related inflammatory mechanisms in the AT and rather less in
other metabolic organs, e.g. the liver. Therefore, the aims of this proposal are: (i) To characterize in the
context of obesity-related metabolic disease novel processes mediating inflammatory cell retention,
especially in the liver. In this context, we will also address the novel hypothesis that adhesive interactions of
inflammatory cells (with e.g. parenchymal cells) in the metabolically challenged environment of obese
organs may activate them via alterations in their cellular metabolism, thereby contributing to perpetuation of
inflammation. (ii) To understand resolution of inflammation including inflammatory cell egress from
metabolic organs, especially from the liver in metabolic-inflammatory disease. To this end, we will also
utilize models of acute inflammation, which is capable to resolve, in order to understand resolution principles
and apply them to non-resolving metabolic-inflammatory disease. In this regard, we will also assess the
therapeutic potential of novel inflammation-modulating factors identified by our lab.
Summary
Resolution of acute inflammation, involving limiting further leukocyte recruitment, apoptosis and clearance
of inflammatory cells via macrophages as well as egress of the inflammatory cells, is operative in acute
inflammation but dysfunctional in chronic inflammatory disease. In the latter scenario, the retention and
activation of leukocytes in the inflamed tissue linked with failure to resolve inflammation contributes to
perpetuation of organ damage and loss of homeostasis. Interestingly, persistent inflammation in insulintarget
organs, such as the adipose tissue and the liver in the context of obesity significantly contributes to
development of insulin resistance (IR), diabetes and non-alcoholic fatty liver disease (NAFLD). So far,
investigations have mainly addressed obesity-related inflammatory mechanisms in the AT and rather less in
other metabolic organs, e.g. the liver. Therefore, the aims of this proposal are: (i) To characterize in the
context of obesity-related metabolic disease novel processes mediating inflammatory cell retention,
especially in the liver. In this context, we will also address the novel hypothesis that adhesive interactions of
inflammatory cells (with e.g. parenchymal cells) in the metabolically challenged environment of obese
organs may activate them via alterations in their cellular metabolism, thereby contributing to perpetuation of
inflammation. (ii) To understand resolution of inflammation including inflammatory cell egress from
metabolic organs, especially from the liver in metabolic-inflammatory disease. To this end, we will also
utilize models of acute inflammation, which is capable to resolve, in order to understand resolution principles
and apply them to non-resolving metabolic-inflammatory disease. In this regard, we will also assess the
therapeutic potential of novel inflammation-modulating factors identified by our lab.
Max ERC Funding
1 953 250 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
Project acronym DismantlingNoise
Project Dissecting the (epi)genetic origins of phenotypic variation and metabolic disease susceptibility
Researcher (PI) John Andrew Pospisilik
Host Institution (HI) MAX-PLANCK-GESELLSCHAFT ZUR FORDERUNG DER WISSENSCHAFTEN EV
Call Details Consolidator Grant (CoG), LS4, ERC-2015-CoG
Summary Current estimates place the prevalence of obesity beyond 1 billion by the year 2030. As a critical risk factor for heart disease, diabetes and stroke, obesity represents one of the chief socio-economic challenges of our day. While studies have mapped a genetic framework for understanding obesity, the etiological contribution of several regulatory layers, and in particular epigenetic regulation, remain poorly understood. A perfect example, we know that isogenic C57Bl6/J mice can vary by as much as 100% in body weight upon high fat feeding; currently, we have no mechanistic explanation for the emergence of such phenotypic variation. Here, I propose three aims dedicated towards understanding the (epi)genetic control of phenotypic variation and disease susceptibility. First, we will catalogue epigenome and phenome variation to an unprecedented depth and resolution in the isogenic context. Next, we will examine two completely novel models of epigenetically sensitized bi-stable obesity and thus begin a mechanistic dissection of phenotypic variation. Finally, we will map a series of gene-gene and gene-environment epistasis interactions including eight models of developmental plasticity and approximately a dozen chromatin regulator mutants. The latter epistasis matrix will identify the molecular mechanisms that trigger, amplify and buffer phenotypic variation and stochastic obesity in mice. The functional (epi)phenomics approach is unique. It builds the first unbiased framework against which to understand developmental plasticity and phenotypic variation, and at the same time generates powerful resources for disease researchers worldwide.
Summary
Current estimates place the prevalence of obesity beyond 1 billion by the year 2030. As a critical risk factor for heart disease, diabetes and stroke, obesity represents one of the chief socio-economic challenges of our day. While studies have mapped a genetic framework for understanding obesity, the etiological contribution of several regulatory layers, and in particular epigenetic regulation, remain poorly understood. A perfect example, we know that isogenic C57Bl6/J mice can vary by as much as 100% in body weight upon high fat feeding; currently, we have no mechanistic explanation for the emergence of such phenotypic variation. Here, I propose three aims dedicated towards understanding the (epi)genetic control of phenotypic variation and disease susceptibility. First, we will catalogue epigenome and phenome variation to an unprecedented depth and resolution in the isogenic context. Next, we will examine two completely novel models of epigenetically sensitized bi-stable obesity and thus begin a mechanistic dissection of phenotypic variation. Finally, we will map a series of gene-gene and gene-environment epistasis interactions including eight models of developmental plasticity and approximately a dozen chromatin regulator mutants. The latter epistasis matrix will identify the molecular mechanisms that trigger, amplify and buffer phenotypic variation and stochastic obesity in mice. The functional (epi)phenomics approach is unique. It builds the first unbiased framework against which to understand developmental plasticity and phenotypic variation, and at the same time generates powerful resources for disease researchers worldwide.
Max ERC Funding
1 997 853 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
