Project acronym AGNES
Project ACTIVE AGEING – RESILIENCE AND EXTERNAL SUPPORT AS MODIFIERS OF THE DISABLEMENT OUTCOME
Researcher (PI) Taina Tuulikki RANTANEN
Host Institution (HI) JYVASKYLAN YLIOPISTO
Country Finland
Call Details Advanced Grant (AdG), SH3, ERC-2015-AdG
Summary The goals are 1. To develop a scale assessing the diversity of active ageing with four dimensions that are ability (what people can do), activity (what people do do), ambition (what are the valued activities that people want to do), and autonomy (how satisfied people are with the opportunity to do valued activities); 2. To examine health and physical and psychological functioning as the determinants and social and build environment, resilience and personal skills as modifiers of active ageing; 3. To develop a multicomponent sustainable intervention aiming to promote active ageing (methods: counselling, information technology, help from volunteers); 4. To test the feasibility and effectiveness on the intervention; and 5. To study cohort effects on the phenotypes on the pathway to active ageing.
“If You Can Measure It, You Can Change It.” Active ageing assessment needs conceptual progress, which I propose to do. A quantifiable scale will be developed that captures the diversity of active ageing stemming from the WHO definition of active ageing as the process of optimizing opportunities for health and participation in the society for all people in line with their needs, goals and capacities as they age. I will collect cross-sectional data (N=1000, ages 75, 80 and 85 years) and model the pathway to active ageing with state-of-the art statistical methods. By doing this I will create novel knowledge on preconditions for active ageing. The collected cohort data will be compared to a pre-existing cohort data that was collected 25 years ago to obtain knowledge about changes over time in functioning of older people. A randomized controlled trial (N=200) will be conducted to assess the effectiveness of the envisioned intervention promoting active ageing through participation. The project will regenerate ageing research by launching a novel scale, by training young scientists, by creating new concepts and theory development and by producing evidence for active ageing promotion
Summary
The goals are 1. To develop a scale assessing the diversity of active ageing with four dimensions that are ability (what people can do), activity (what people do do), ambition (what are the valued activities that people want to do), and autonomy (how satisfied people are with the opportunity to do valued activities); 2. To examine health and physical and psychological functioning as the determinants and social and build environment, resilience and personal skills as modifiers of active ageing; 3. To develop a multicomponent sustainable intervention aiming to promote active ageing (methods: counselling, information technology, help from volunteers); 4. To test the feasibility and effectiveness on the intervention; and 5. To study cohort effects on the phenotypes on the pathway to active ageing.
“If You Can Measure It, You Can Change It.” Active ageing assessment needs conceptual progress, which I propose to do. A quantifiable scale will be developed that captures the diversity of active ageing stemming from the WHO definition of active ageing as the process of optimizing opportunities for health and participation in the society for all people in line with their needs, goals and capacities as they age. I will collect cross-sectional data (N=1000, ages 75, 80 and 85 years) and model the pathway to active ageing with state-of-the art statistical methods. By doing this I will create novel knowledge on preconditions for active ageing. The collected cohort data will be compared to a pre-existing cohort data that was collected 25 years ago to obtain knowledge about changes over time in functioning of older people. A randomized controlled trial (N=200) will be conducted to assess the effectiveness of the envisioned intervention promoting active ageing through participation. The project will regenerate ageing research by launching a novel scale, by training young scientists, by creating new concepts and theory development and by producing evidence for active ageing promotion
Max ERC Funding
2 044 364 €
Duration
Start date: 2016-09-01, End date: 2021-08-31
Project acronym ALICE
Project Strange Mirrors, Unsuspected Lessons: Leading Europe to a new way of sharing the world experiences
Researcher (PI) Boaventura De Sousa Santos
Host Institution (HI) CENTRO DE ESTUDOS SOCIAIS
Country Portugal
Call Details Advanced Grant (AdG), SH2, ERC-2010-AdG_20100407
Summary Europe sits uncomfortably on the idea that there are no political and cultural alternatives credible enough to respond to the current uneasiness or malaise caused by both a world that is more and more non-European and a Europe that increasingly questions what is European about itself. This project will develop a new grounded theoretical paradigm for contemporary Europe based on two key ideas: the understanding of the world by far exceeds the European understanding of the world; social, political and institutional transformation in Europe may benefit from innovations taking place in regions and countries with which Europe is increasingly interdependent. I will pursue this objective focusing on four main interconnected topics: democratizing democracy, intercultural constitutionalism, the other economy, human rights (right to health in particular).
In a sense that the European challenges are unique but, in one way or another, are being experienced in different corners of the world. The novelty resides in bringing new ideas and experiences into the European conversation, show their relevance to our current uncertainties and aspirations and thereby contribute to face them with new intellectual and political resources. The usefulness and relevance of non-European conceptions and experiences un-thinking the conventional knowledge through two epistemological devices I have developed: the ecology of knowledges and intercultural translation. By resorting to them I will show that there are alternatives but they cannot be made credible and powerful if we go on relying on the modes of theoretical and political thinking that have dominated so far. In other words, the claim put forward by and worked through this project is that in Europe we don’t need alternatives but rather an alternative thinking of alternatives.
Summary
Europe sits uncomfortably on the idea that there are no political and cultural alternatives credible enough to respond to the current uneasiness or malaise caused by both a world that is more and more non-European and a Europe that increasingly questions what is European about itself. This project will develop a new grounded theoretical paradigm for contemporary Europe based on two key ideas: the understanding of the world by far exceeds the European understanding of the world; social, political and institutional transformation in Europe may benefit from innovations taking place in regions and countries with which Europe is increasingly interdependent. I will pursue this objective focusing on four main interconnected topics: democratizing democracy, intercultural constitutionalism, the other economy, human rights (right to health in particular).
In a sense that the European challenges are unique but, in one way or another, are being experienced in different corners of the world. The novelty resides in bringing new ideas and experiences into the European conversation, show their relevance to our current uncertainties and aspirations and thereby contribute to face them with new intellectual and political resources. The usefulness and relevance of non-European conceptions and experiences un-thinking the conventional knowledge through two epistemological devices I have developed: the ecology of knowledges and intercultural translation. By resorting to them I will show that there are alternatives but they cannot be made credible and powerful if we go on relying on the modes of theoretical and political thinking that have dominated so far. In other words, the claim put forward by and worked through this project is that in Europe we don’t need alternatives but rather an alternative thinking of alternatives.
Max ERC Funding
2 423 140 €
Duration
Start date: 2011-07-01, End date: 2016-12-31
Project acronym ANTEGEFI
Project Analytic Techniques for Geometric and Functional Inequalities
Researcher (PI) Nicola Fusco
Host Institution (HI) UNIVERSITA DEGLI STUDI DI NAPOLI FEDERICO II
Country Italy
Call Details Advanced Grant (AdG), PE1, ERC-2008-AdG
Summary Isoperimetric and Sobolev inequalities are the best known examples of geometric-functional inequalities. In recent years the PI and collaborators have obtained new and sharp quantitative versions of these and other important related inequalities. These results have been obtained by the combined use of classical symmetrization methods, new tools coming from mass transportation theory, deep geometric measure tools and ad hoc symmetrizations. The objective of this project is to further develop thes techniques in order to get: sharp quantitative versions of Faber-Krahn inequality, Gaussian isoperimetric inequality, Brunn-Minkowski inequality, Poincaré and Sobolev logarithm inequalities; sharp decay rates for the quantitative Sobolev inequalities and Polya-Szegö inequality.
Summary
Isoperimetric and Sobolev inequalities are the best known examples of geometric-functional inequalities. In recent years the PI and collaborators have obtained new and sharp quantitative versions of these and other important related inequalities. These results have been obtained by the combined use of classical symmetrization methods, new tools coming from mass transportation theory, deep geometric measure tools and ad hoc symmetrizations. The objective of this project is to further develop thes techniques in order to get: sharp quantitative versions of Faber-Krahn inequality, Gaussian isoperimetric inequality, Brunn-Minkowski inequality, Poincaré and Sobolev logarithm inequalities; sharp decay rates for the quantitative Sobolev inequalities and Polya-Szegö inequality.
Max ERC Funding
600 000 €
Duration
Start date: 2009-01-01, End date: 2013-12-31
Project acronym AQUAMS
Project Analysis of quantum many-body systems
Researcher (PI) Robert Seiringer
Host Institution (HI) INSTITUTE OF SCIENCE AND TECHNOLOGY AUSTRIA
Country Austria
Call Details Advanced Grant (AdG), PE1, ERC-2015-AdG
Summary The main focus of this project is the mathematical analysis of many-body quantum systems, in particular, interacting quantum gases at low temperature. The recent experimental advances in studying ultra-cold atomic gases have led to renewed interest in these systems. They display a rich variety of quantum phenomena, including, e.g., Bose–Einstein condensation and superfluidity, which makes them interesting both from a physical and a mathematical point of view.
The goal of this project is the development of new mathematical tools for dealing with complex problems in many-body quantum systems. New mathematical methods lead to different points of view and thus increase our understanding of physical systems. From the point of view of mathematical physics, there has been significant progress in the last few years in understanding the interesting phenomena occurring in quantum gases, and the goal of this project is to investigate some of the key issues that remain unsolved. Due to the complex nature of the problems, new mathematical ideas
and methods will have to be developed for this purpose. One of the main question addressed in this proposal is the validity of the Bogoliubov approximation for the excitation spectrum of many-body quantum systems. While its accuracy has been
successfully shown for the ground state energy of various models, its predictions concerning the excitation spectrum have so far only been verified in the Hartree limit, an extreme form of a mean-field limit where the interaction among the particles is very weak and ranges over the whole system. The central part of this project is concerned with the extension of these results to the case of short-range interactions. Apart from being mathematically much more challenging, the short-range case is the
one most relevant for the description of actual physical systems. Hence progress along these lines can be expected to yield valuable insight into the complex behavior of these many-body quantum systems.
Summary
The main focus of this project is the mathematical analysis of many-body quantum systems, in particular, interacting quantum gases at low temperature. The recent experimental advances in studying ultra-cold atomic gases have led to renewed interest in these systems. They display a rich variety of quantum phenomena, including, e.g., Bose–Einstein condensation and superfluidity, which makes them interesting both from a physical and a mathematical point of view.
The goal of this project is the development of new mathematical tools for dealing with complex problems in many-body quantum systems. New mathematical methods lead to different points of view and thus increase our understanding of physical systems. From the point of view of mathematical physics, there has been significant progress in the last few years in understanding the interesting phenomena occurring in quantum gases, and the goal of this project is to investigate some of the key issues that remain unsolved. Due to the complex nature of the problems, new mathematical ideas
and methods will have to be developed for this purpose. One of the main question addressed in this proposal is the validity of the Bogoliubov approximation for the excitation spectrum of many-body quantum systems. While its accuracy has been
successfully shown for the ground state energy of various models, its predictions concerning the excitation spectrum have so far only been verified in the Hartree limit, an extreme form of a mean-field limit where the interaction among the particles is very weak and ranges over the whole system. The central part of this project is concerned with the extension of these results to the case of short-range interactions. Apart from being mathematically much more challenging, the short-range case is the
one most relevant for the description of actual physical systems. Hence progress along these lines can be expected to yield valuable insight into the complex behavior of these many-body quantum systems.
Max ERC Funding
1 497 755 €
Duration
Start date: 2016-10-01, End date: 2022-03-31
Project acronym ARCHADAPT
Project The architecture of adaptation to novel environments
Researcher (PI) Christian Werner Schloetterer
Host Institution (HI) VETERINAERMEDIZINISCHE UNIVERSITAET WIEN
Country Austria
Call Details Advanced Grant (AdG), LS8, ERC-2011-ADG_20110310
Summary One of the central goals in evolutionary biology is to understand adaptation. Experimental evolution represents a highly promising approach to study adaptation. In this proposal, a freshly collected D. simulans population will be allowed to adapt to laboratory conditions under two different temperature regimes: hot (27°C) and cold (18°C). The trajectories of adaptation to these novel environments will be monitored on three levels: 1) genomic, 2) transcriptomic, 3) phenotypic. Allele frequency changes during the experiment will be measured by next generation sequencing of DNA pools (Pool-Seq) to identify targets of selection. RNA-Seq will be used to trace adaptation on the transcriptomic level during three developmental stages. Eight different phenotypes will be scored to measure the phenotypic consequences of adaptation. Combining the adaptive trajectories on these three levels will provide a picture of adaptation for a multicellular, outcrossing organism that is far more detailed than any previous results.
Furthermore, the proposal addresses the question of how adaptation on these three levels is reversible if the environment reverts to ancestral conditions. The third aspect of adaptation covered in the proposal is the question of repeatability of adaptation. Again, this question will be addressed on the three levels: genomic, transcriptomic and phenotypic. Using replicates with different degrees of genetic similarity, as well as closely related species, we will test how similar the adaptive response is.
This large-scale study will provide new insights into the importance of standing variation for the adaptation to novel environments. Hence, apart from providing significant evolutionary insights on the trajectories of adaptation, the results we will obtain will have important implications for conservation genetics and commercial breeding.
Summary
One of the central goals in evolutionary biology is to understand adaptation. Experimental evolution represents a highly promising approach to study adaptation. In this proposal, a freshly collected D. simulans population will be allowed to adapt to laboratory conditions under two different temperature regimes: hot (27°C) and cold (18°C). The trajectories of adaptation to these novel environments will be monitored on three levels: 1) genomic, 2) transcriptomic, 3) phenotypic. Allele frequency changes during the experiment will be measured by next generation sequencing of DNA pools (Pool-Seq) to identify targets of selection. RNA-Seq will be used to trace adaptation on the transcriptomic level during three developmental stages. Eight different phenotypes will be scored to measure the phenotypic consequences of adaptation. Combining the adaptive trajectories on these three levels will provide a picture of adaptation for a multicellular, outcrossing organism that is far more detailed than any previous results.
Furthermore, the proposal addresses the question of how adaptation on these three levels is reversible if the environment reverts to ancestral conditions. The third aspect of adaptation covered in the proposal is the question of repeatability of adaptation. Again, this question will be addressed on the three levels: genomic, transcriptomic and phenotypic. Using replicates with different degrees of genetic similarity, as well as closely related species, we will test how similar the adaptive response is.
This large-scale study will provide new insights into the importance of standing variation for the adaptation to novel environments. Hence, apart from providing significant evolutionary insights on the trajectories of adaptation, the results we will obtain will have important implications for conservation genetics and commercial breeding.
Max ERC Funding
2 452 084 €
Duration
Start date: 2012-07-01, End date: 2018-06-30
Project acronym ARIPHYHIMO
Project Arithmetic and physics of Higgs moduli spaces
Researcher (PI) Tamas Hausel
Host Institution (HI) INSTITUTE OF SCIENCE AND TECHNOLOGY AUSTRIA
Country Austria
Call Details Advanced Grant (AdG), PE1, ERC-2012-ADG_20120216
Summary The proposal studies problems concerning the geometry and topology of moduli spaces of Higgs bundles on a Riemann surface motivated by parallel considerations in number theory and mathematical physics. In this way the proposal bridges various duality theories in string theory with the Langlands program in number theory.
The heart of the proposal is a circle of precise conjectures relating to the topology of the moduli space of Higgs bundles. The formulation and motivations of the conjectures make direct contact with the Langlands program in number theory, various duality conjectures in string theory, algebraic combinatorics, knot theory and low dimensional topology and representation theory of quivers, finite groups and algebras of Lie type and Cherednik algebras.
Summary
The proposal studies problems concerning the geometry and topology of moduli spaces of Higgs bundles on a Riemann surface motivated by parallel considerations in number theory and mathematical physics. In this way the proposal bridges various duality theories in string theory with the Langlands program in number theory.
The heart of the proposal is a circle of precise conjectures relating to the topology of the moduli space of Higgs bundles. The formulation and motivations of the conjectures make direct contact with the Langlands program in number theory, various duality conjectures in string theory, algebraic combinatorics, knot theory and low dimensional topology and representation theory of quivers, finite groups and algebras of Lie type and Cherednik algebras.
Max ERC Funding
1 304 945 €
Duration
Start date: 2013-04-01, End date: 2018-08-31
Project acronym CARDIOEPIGEN
Project Epigenetics and microRNAs in Myocardial Function and Disease
Researcher (PI) Gianluigi Condorelli
Host Institution (HI) HUMANITAS MIRASOLE SPA
Country Italy
Call Details Advanced Grant (AdG), LS4, ERC-2011-ADG_20110310
Summary Heart failure (HF) is the ultimate outcome of many cardiovascular diseases. Re-expression of fetal genes in the adult heart contributes to development of HF. Two mechanisms involved in the control of gene expression are epigenetics and microRNAs (miRs). We propose a project on epigenetic and miR-mediated mechanisms leading to HF.
Epigenetics refers to heritable modification of DNA and histones that does not modify the genetic code. Depending on the type of modification and on the site affected, these chemical changes up- or down-regulate transcription of specific genes. Despite it being a major player in gene regulation, epigenetics has been only partly investigated in HF. miRs are regulatory RNAs that target mRNAs for inhibition. Dysregulation of the cardiac miR signature occurs in HF. miR expression may itself be under epigenetic control, constituting a miR-epigenetic regulatory network. To our knowledge, this possibility has not been studied yet.
Our specific hypothesis is that the profile of DNA/histone methylation and the cross-talk between epigenetic enzymes and miRs have fundamental roles in defining the characteristics of cells during cardiac development and that the dysregulation of these processes determines the deleterious nature of the stressed heart’s gene programme. We will test this first through a genome-wide study of DNA/histone methylation to generate maps of the main methylation modifications occurring in the genome of cardiac cells treated with a pro-hypertrophy regulator and of a HF model. We will then investigate the role of epigenetic enzymes deemed important in HF, through the generation and study of knockout mice models. Finally, we will test the possible therapeutic potential of modulating epigenetic genes.
We hope to further understand the pathological mechanisms leading to HF and to generate data instrumental to the development of diagnostic and therapeutic strategies for this disease.
Summary
Heart failure (HF) is the ultimate outcome of many cardiovascular diseases. Re-expression of fetal genes in the adult heart contributes to development of HF. Two mechanisms involved in the control of gene expression are epigenetics and microRNAs (miRs). We propose a project on epigenetic and miR-mediated mechanisms leading to HF.
Epigenetics refers to heritable modification of DNA and histones that does not modify the genetic code. Depending on the type of modification and on the site affected, these chemical changes up- or down-regulate transcription of specific genes. Despite it being a major player in gene regulation, epigenetics has been only partly investigated in HF. miRs are regulatory RNAs that target mRNAs for inhibition. Dysregulation of the cardiac miR signature occurs in HF. miR expression may itself be under epigenetic control, constituting a miR-epigenetic regulatory network. To our knowledge, this possibility has not been studied yet.
Our specific hypothesis is that the profile of DNA/histone methylation and the cross-talk between epigenetic enzymes and miRs have fundamental roles in defining the characteristics of cells during cardiac development and that the dysregulation of these processes determines the deleterious nature of the stressed heart’s gene programme. We will test this first through a genome-wide study of DNA/histone methylation to generate maps of the main methylation modifications occurring in the genome of cardiac cells treated with a pro-hypertrophy regulator and of a HF model. We will then investigate the role of epigenetic enzymes deemed important in HF, through the generation and study of knockout mice models. Finally, we will test the possible therapeutic potential of modulating epigenetic genes.
We hope to further understand the pathological mechanisms leading to HF and to generate data instrumental to the development of diagnostic and therapeutic strategies for this disease.
Max ERC Funding
2 500 000 €
Duration
Start date: 2012-10-01, End date: 2018-09-30
Project acronym CHALLENGE
Project Persistent bullying cases: towards tailored intervention approaches to maximize efficiency
Researcher (PI) Christina SALMIVALLI
Host Institution (HI) TURUN YLIOPISTO
Country Finland
Call Details Advanced Grant (AdG), SH3, ERC-2019-ADG
Summary Bullying in schools is widespread, with adverse effects on youth and high costs for societies. Research on bullying prevention has so far focused on average effects of anti-bullying programs and mainly concerned universal, preventive measures. While important, this has overshadowed attempts to uncover how exactly school personnel intervene in particular bullying cases and when and why that fails. CHALLENGE will open up new research horizons by shifting the focus from average program effects to the characteristics and conditions of youth who remain victimized or continue bullying despite targeted interventions. The next big questions in the field are tackled in four work packages:
WP1 uncovers the key features of persistent bullying, such as the extent to which it is due to school-level factors or rather varies across bullying cases (within schools).
WP2 elucidates the plight of persistent victims by testing why victimized youth are most maladjusted in contexts where the overall level of victimization is decreasing (healthy context paradox, Garandeau & Salmivalli, 2019).
WP3 tests the efficacy of different targeted interventions in real-life conditions, uncovering challenge factors that increase the risk of a bullying case remaining unresolved. Moreover, it tests how youth characteristics affect their cognitive, emotional and motivational responses to different interventions.
WP4 utilizes molecular genetics to test genetic susceptibility to intervention effects at the individual level.
CHALLENGE uses quantitative, qualitative, and DNA analyses, combines longitudinal and experimental designs, and harnesses novel tools to collect real-time intervention data and to register children’s responses to interventions. It bridges the perspectives of developmental and social psychology, child psychiatry, and genetics, builds theory on persistent bullying and enables the development of tailored measures for specific target groups where available interventions have failed
Summary
Bullying in schools is widespread, with adverse effects on youth and high costs for societies. Research on bullying prevention has so far focused on average effects of anti-bullying programs and mainly concerned universal, preventive measures. While important, this has overshadowed attempts to uncover how exactly school personnel intervene in particular bullying cases and when and why that fails. CHALLENGE will open up new research horizons by shifting the focus from average program effects to the characteristics and conditions of youth who remain victimized or continue bullying despite targeted interventions. The next big questions in the field are tackled in four work packages:
WP1 uncovers the key features of persistent bullying, such as the extent to which it is due to school-level factors or rather varies across bullying cases (within schools).
WP2 elucidates the plight of persistent victims by testing why victimized youth are most maladjusted in contexts where the overall level of victimization is decreasing (healthy context paradox, Garandeau & Salmivalli, 2019).
WP3 tests the efficacy of different targeted interventions in real-life conditions, uncovering challenge factors that increase the risk of a bullying case remaining unresolved. Moreover, it tests how youth characteristics affect their cognitive, emotional and motivational responses to different interventions.
WP4 utilizes molecular genetics to test genetic susceptibility to intervention effects at the individual level.
CHALLENGE uses quantitative, qualitative, and DNA analyses, combines longitudinal and experimental designs, and harnesses novel tools to collect real-time intervention data and to register children’s responses to interventions. It bridges the perspectives of developmental and social psychology, child psychiatry, and genetics, builds theory on persistent bullying and enables the development of tailored measures for specific target groups where available interventions have failed
Max ERC Funding
2 424 001 €
Duration
Start date: 2020-10-01, End date: 2025-09-30
Project acronym CoCEAL
Project The Common Core of European Administrative Law
Researcher (PI) Giacinto DELLA CANANEA
Host Institution (HI) UNIVERSITA COMMERCIALE LUIGI BOCCONI
Country Italy
Call Details Advanced Grant (AdG), SH2, ERC-2015-AdG
Summary The European dimension of administrative law is the focus of a flurry of initiatives aiming to investigate similarities and differences, and to shape common legal scenarios. A codification of the administrative procedures of the EU has been envisaged by the European Parliament in its resolution of February 2013. A broader proposal of codification, including rule-making and contractual procedures, has been elaborated by ReNEUAL and has been discussed in a series of workshops in 2015.
The issues that arise are both practical and theoretical:
- it is important to understand whether the method traditionally followed by the European Court of Justice in order to identify the principles that are general and common to national legal systems, only applies when all those systems recognize such principles;
- whether national systems of public law share the same idea of what an administrative procedure is is another question;
whether the specific principles governing administrative procedures, such as the right to be heard and the duty to give reasons, are the same is still another question;
- finally, if any commonality exists, the question that arises is whether it is limited to the level of general principles of law or it includes the which govern procedures.
The research project is innovative on grounds of method, because:
- it aims at ascertaining whether, and the extent to that, the well-established methodology developed under the ‘Common Core of European Private Law’ project can be applied to EU administrative law;
- it permits to distinguish between ‘operative rules’, ‘descriptive formants’, and ‘meta-legal formants’;
- it also allows to understand whether the specific nature of the interests recognized and protected by the rules of public law require legal methodologies that are distinct and distant from those of private law.
Summary
The European dimension of administrative law is the focus of a flurry of initiatives aiming to investigate similarities and differences, and to shape common legal scenarios. A codification of the administrative procedures of the EU has been envisaged by the European Parliament in its resolution of February 2013. A broader proposal of codification, including rule-making and contractual procedures, has been elaborated by ReNEUAL and has been discussed in a series of workshops in 2015.
The issues that arise are both practical and theoretical:
- it is important to understand whether the method traditionally followed by the European Court of Justice in order to identify the principles that are general and common to national legal systems, only applies when all those systems recognize such principles;
- whether national systems of public law share the same idea of what an administrative procedure is is another question;
whether the specific principles governing administrative procedures, such as the right to be heard and the duty to give reasons, are the same is still another question;
- finally, if any commonality exists, the question that arises is whether it is limited to the level of general principles of law or it includes the which govern procedures.
The research project is innovative on grounds of method, because:
- it aims at ascertaining whether, and the extent to that, the well-established methodology developed under the ‘Common Core of European Private Law’ project can be applied to EU administrative law;
- it permits to distinguish between ‘operative rules’, ‘descriptive formants’, and ‘meta-legal formants’;
- it also allows to understand whether the specific nature of the interests recognized and protected by the rules of public law require legal methodologies that are distinct and distant from those of private law.
Max ERC Funding
1 254 105 €
Duration
Start date: 2016-09-01, End date: 2022-08-31
Project acronym COMBINE
Project From flies to humans combining whole genome screens and tissue specific gene targeting to identify novel pathways involved in cancer and metastases
Researcher (PI) Josef Martin Penninger
Host Institution (HI) INSTITUT FUER MOLEKULARE BIOTECHNOLOGIE GMBH
Country Austria
Call Details Advanced Grant (AdG), LS4, ERC-2008-AdG
Summary Cancer care will be revolutionized over the next decade by the introduction of novel therapeutics that target the underlying molecular mechanisms of the disease. With the advent of human genetics, a plethora of genes have been correlated with human diseases such as cancer the SNP maps. Since the sequences are now available, the next big challenge is to determine the function of these genes in the context of the entire organism. Genetic animal models have proven to be extremely valuable to elucidate the essential functions of genes in normal physiology and the pathogenesis of disease. Using gene-targeted mice we have previously identified RANKL as a master gene of bone loss in arthritis, osteoporosis, and cancer cell migration and metastases and genes that control heart and kidney function; wound healing; diabetes; or lung injury Our primary goal is to use functional genomics in Drosophila and mice to understand cell transformation, invasion, and cancer metastases of epithelial tumors. The following projects are proposed: 1. Role of the key osteoclast differentiation factors RANKL-RANK and its downstream signalling cascade in the development of breast and prostate cancer. 2. Requirement of osteoclasts for bone metastases and stem cell niches using a new RANKfloxed allele; function of RANKL-RANK in local tumor cell invasion. 3. Role of RANKL-RANK in the central fever response to understand potential implications of future RANKL-RANK directed therapies. 4. Integration of gene targeting in mice with state-of-the art technologies in fly genetics; use of whole genome tissue-specific in vivo RNAi Drosophila libraries to identify essential and novel pathways for cancer pathogenesis using whole genome screens. 5. Role of TSPAN6, as a candidate lung metastasis gene. Identification of new cancer disease genes will allow us to design novel strategies for cancer treatment and will have ultimately impact on the basic understanding of cancer, metastases, and human health.
Summary
Cancer care will be revolutionized over the next decade by the introduction of novel therapeutics that target the underlying molecular mechanisms of the disease. With the advent of human genetics, a plethora of genes have been correlated with human diseases such as cancer the SNP maps. Since the sequences are now available, the next big challenge is to determine the function of these genes in the context of the entire organism. Genetic animal models have proven to be extremely valuable to elucidate the essential functions of genes in normal physiology and the pathogenesis of disease. Using gene-targeted mice we have previously identified RANKL as a master gene of bone loss in arthritis, osteoporosis, and cancer cell migration and metastases and genes that control heart and kidney function; wound healing; diabetes; or lung injury Our primary goal is to use functional genomics in Drosophila and mice to understand cell transformation, invasion, and cancer metastases of epithelial tumors. The following projects are proposed: 1. Role of the key osteoclast differentiation factors RANKL-RANK and its downstream signalling cascade in the development of breast and prostate cancer. 2. Requirement of osteoclasts for bone metastases and stem cell niches using a new RANKfloxed allele; function of RANKL-RANK in local tumor cell invasion. 3. Role of RANKL-RANK in the central fever response to understand potential implications of future RANKL-RANK directed therapies. 4. Integration of gene targeting in mice with state-of-the art technologies in fly genetics; use of whole genome tissue-specific in vivo RNAi Drosophila libraries to identify essential and novel pathways for cancer pathogenesis using whole genome screens. 5. Role of TSPAN6, as a candidate lung metastasis gene. Identification of new cancer disease genes will allow us to design novel strategies for cancer treatment and will have ultimately impact on the basic understanding of cancer, metastases, and human health.
Max ERC Funding
2 499 465 €
Duration
Start date: 2009-01-01, End date: 2013-12-31
