Project acronym AAMDDR
Project DNA damage response and genome stability: The role of ATM, ATR and the Mre11 complex
Researcher (PI) Vincenzo Costanzo
Host Institution (HI) CANCER RESEARCH UK LBG
Call Details Starting Grant (StG), LS1, ERC-2007-StG
Summary Chromosomal DNA is continuously subjected to exogenous and endogenous damaging insults. In the presence of DNA damage cells activate a multi-faceted checkpoint response that delays cell cycle progression and promotes DNA repair. Failures in this response lead to genomic instability, the main feature of cancer cells. Several cancer-prone human syndromes including the Ataxia teleangiectasia (A-T), the A-T Like Disorder (ATLD) and the Seckel Syndrome reflect defects in the specific genes of the DNA damage response such as ATM, MRE11 and ATR. DNA damage response pathways are poorly understood at biochemical level in vertebrate organisms. We have established a cell-free system based on Xenopus laevis egg extract to study molecular events underlying DNA damage response. This is the first in vitro system that recapitulates different aspects of the DNA damage response in vertebrates. Using this system we propose to study the biochemistry of the ATM, ATR and the Mre11 complex dependent DNA damage response. In particular we will: 1) Dissect the signal transduction pathway that senses DNA damage and promotes cell cycle arrest and DNA damage repair; 2) Analyze at molecular level the role of ATM, ATR, Mre11 in chromosomal DNA replication and mitosis during normal and stressful conditions; 3) Identify substrates of the ATM and ATR dependent DNA damage response using an innovative screening procedure.
Summary
Chromosomal DNA is continuously subjected to exogenous and endogenous damaging insults. In the presence of DNA damage cells activate a multi-faceted checkpoint response that delays cell cycle progression and promotes DNA repair. Failures in this response lead to genomic instability, the main feature of cancer cells. Several cancer-prone human syndromes including the Ataxia teleangiectasia (A-T), the A-T Like Disorder (ATLD) and the Seckel Syndrome reflect defects in the specific genes of the DNA damage response such as ATM, MRE11 and ATR. DNA damage response pathways are poorly understood at biochemical level in vertebrate organisms. We have established a cell-free system based on Xenopus laevis egg extract to study molecular events underlying DNA damage response. This is the first in vitro system that recapitulates different aspects of the DNA damage response in vertebrates. Using this system we propose to study the biochemistry of the ATM, ATR and the Mre11 complex dependent DNA damage response. In particular we will: 1) Dissect the signal transduction pathway that senses DNA damage and promotes cell cycle arrest and DNA damage repair; 2) Analyze at molecular level the role of ATM, ATR, Mre11 in chromosomal DNA replication and mitosis during normal and stressful conditions; 3) Identify substrates of the ATM and ATR dependent DNA damage response using an innovative screening procedure.
Max ERC Funding
1 000 000 €
Duration
Start date: 2008-07-01, End date: 2013-06-30
Project acronym ACrossWire
Project A Cross-Correlated Approach to Engineering Nitride Nanowires
Researcher (PI) Hannah Jane JOYCE
Host Institution (HI) THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE
Call Details Starting Grant (StG), PE7, ERC-2016-STG
Summary Nanowires based on group III–nitride semiconductors exhibit outstanding potential for emerging applications in energy-efficient lighting, optoelectronics and solar energy harvesting. Nitride nanowires, tailored at the nanoscale, should overcome many of the challenges facing conventional planar nitride materials, and also add extraordinary new functionality to these materials. However, progress towards III–nitride nanowire devices has been hampered by the challenges in quantifying nanowire electrical properties using conventional contact-based measurements. Without reliable electrical transport data, it is extremely difficult to optimise nanowire growth and device design. This project aims to overcome this problem through an unconventional approach: advanced contact-free electrical measurements. Contact-free measurements, growth studies, and device studies will be cross-correlated to provide unprecedented insight into the growth mechanisms that govern nanowire electronic properties and ultimately dictate device performance. A key contact-free technique at the heart of this proposal is ultrafast terahertz conductivity spectroscopy: an advanced technique ideal for probing nanowire electrical properties. We will develop new methods to enable the full suite of contact-free (including terahertz, photoluminescence and cathodoluminescence measurements) and contact-based measurements to be performed with high spatial resolution on the same nanowires. This will provide accurate, comprehensive and cross-correlated feedback to guide growth studies and expedite the targeted development of nanowires with specified functionality. We will apply this powerful approach to tailor nanowires as photoelectrodes for solar photoelectrochemical water splitting. This is an application for which nitride nanowires have outstanding, yet unfulfilled, potential. This project will thus harness the true potential of nitride nanowires and bring them to the forefront of 21st century technology.
Summary
Nanowires based on group III–nitride semiconductors exhibit outstanding potential for emerging applications in energy-efficient lighting, optoelectronics and solar energy harvesting. Nitride nanowires, tailored at the nanoscale, should overcome many of the challenges facing conventional planar nitride materials, and also add extraordinary new functionality to these materials. However, progress towards III–nitride nanowire devices has been hampered by the challenges in quantifying nanowire electrical properties using conventional contact-based measurements. Without reliable electrical transport data, it is extremely difficult to optimise nanowire growth and device design. This project aims to overcome this problem through an unconventional approach: advanced contact-free electrical measurements. Contact-free measurements, growth studies, and device studies will be cross-correlated to provide unprecedented insight into the growth mechanisms that govern nanowire electronic properties and ultimately dictate device performance. A key contact-free technique at the heart of this proposal is ultrafast terahertz conductivity spectroscopy: an advanced technique ideal for probing nanowire electrical properties. We will develop new methods to enable the full suite of contact-free (including terahertz, photoluminescence and cathodoluminescence measurements) and contact-based measurements to be performed with high spatial resolution on the same nanowires. This will provide accurate, comprehensive and cross-correlated feedback to guide growth studies and expedite the targeted development of nanowires with specified functionality. We will apply this powerful approach to tailor nanowires as photoelectrodes for solar photoelectrochemical water splitting. This is an application for which nitride nanowires have outstanding, yet unfulfilled, potential. This project will thus harness the true potential of nitride nanowires and bring them to the forefront of 21st century technology.
Max ERC Funding
1 499 195 €
Duration
Start date: 2017-04-01, End date: 2022-03-31
Project acronym AISMA
Project An anthropological investigation of muscular politics in South Asia
Researcher (PI) Lucia Michelutti
Host Institution (HI) UNIVERSITY COLLEGE LONDON
Call Details Starting Grant (StG), SH2, ERC-2011-StG_20101124
Summary Over the past decade, the media, international organisations, as well as policy-making bodies have voiced increasing concern about a growing overlap between the criminal and political spheres in South Asia. Many 'criminal politicians' are accused not simply of embezzlement, but of burglary, kidnapping and murder, so that the observed political landscape emerges not only as a 'corrupt', but also a highly violent sphere. This project is a collaborative and cross-national ethnographic study of the criminalisation of politics in India, Pakistan and Bangladesh. Bringing together local-level investigation, surveys and historical analysis, the project will produce comprehensive political ethnographies in sixteen sites across the subcontinent, providing empirical material and theoretical directives for further charting of the virtually unexplored terrain of extra-legal muscular politics in the region. Central to the proposed programme of research are the following interrelated objectives: 1) To further develop the method of collaborative political ethnography by designing, collecting and producing case studies which will allow us to write thematically across sites; 2) To generate policy relevant research in the fields of security, conflict, democracy and development; 3) To produce capability by forging an international network of scholars on issues related to democratisation, violence, crime and support the work and careers of the project's 4 Post-docs. The study capitalises on previous research and skills of the PI in the cross-cultural study of democracy and muscular politics in the global South. All members of the research team have expertise in ethnographic research in the difficult spheres of criminal politics, informal economies, and political violence and are hence well and sometimes uniquely equipped to pursue this challenging research thematic.
Summary
Over the past decade, the media, international organisations, as well as policy-making bodies have voiced increasing concern about a growing overlap between the criminal and political spheres in South Asia. Many 'criminal politicians' are accused not simply of embezzlement, but of burglary, kidnapping and murder, so that the observed political landscape emerges not only as a 'corrupt', but also a highly violent sphere. This project is a collaborative and cross-national ethnographic study of the criminalisation of politics in India, Pakistan and Bangladesh. Bringing together local-level investigation, surveys and historical analysis, the project will produce comprehensive political ethnographies in sixteen sites across the subcontinent, providing empirical material and theoretical directives for further charting of the virtually unexplored terrain of extra-legal muscular politics in the region. Central to the proposed programme of research are the following interrelated objectives: 1) To further develop the method of collaborative political ethnography by designing, collecting and producing case studies which will allow us to write thematically across sites; 2) To generate policy relevant research in the fields of security, conflict, democracy and development; 3) To produce capability by forging an international network of scholars on issues related to democratisation, violence, crime and support the work and careers of the project's 4 Post-docs. The study capitalises on previous research and skills of the PI in the cross-cultural study of democracy and muscular politics in the global South. All members of the research team have expertise in ethnographic research in the difficult spheres of criminal politics, informal economies, and political violence and are hence well and sometimes uniquely equipped to pursue this challenging research thematic.
Max ERC Funding
1 200 000 €
Duration
Start date: 2012-03-01, End date: 2016-02-29
Project acronym ATMINDDR
Project ATMINistrating ATM signalling: exploring the significance of ATM regulation by ATMIN
Researcher (PI) Axel Behrens
Host Institution (HI) THE FRANCIS CRICK INSTITUTE LIMITED
Call Details Starting Grant (StG), LS1, ERC-2011-StG_20101109
Summary ATM is the protein kinase that is mutated in the hereditary autosomal recessive disease ataxia telangiectasia (A-T). A-T patients display immune deficiencies, cancer predisposition and radiosensitivity. The molecular role of ATM is to respond to DNA damage by phosphorylating its substrates, thereby promoting repair of damage or arresting the cell cycle. Following the induction of double-strand breaks (DSBs), the NBS1 protein is required for activation of ATM. But ATM can also be activated in the absence of DNA damage. Treatment of cultured cells with hypotonic stress leads to the activation of ATM, presumably due to changes in chromatin structure. We have recently described a second ATM cofactor, ATMIN (ATM INteractor). ATMIN is dispensable for DSBs-induced ATM signalling, but ATM activation following hypotonic stress is mediated by ATMIN. While the biological role of ATM activation by DSBs and NBS1 is well established, the significance, if any, of ATM activation by ATMIN and changes in chromatin was up to now completely enigmatic.
ATM is required for class switch recombination (CSR) and the suppression of translocations in B cells. In order to determine whether ATMIN is required for any of the physiological functions of ATM, we generated a conditional knock-out mouse model for ATMIN. ATM signaling was dramatically reduced following osmotic stress in ATMIN-mutant B cells. ATMIN deficiency led to impaired CSR, and consequently ATMIN-mutant mice developed B cell lymphomas. Thus ablation of ATMIN resulted in a severe defect in ATM function. Our data strongly argue for the existence of a second NBS1-independent mode of ATM activation that is physiologically relevant. While a large amount of scientific effort has gone into characterising ATM signaling triggered by DSBs, essentially nothing is known about NBS1-independent ATM signaling. The experiments outlined in this proposal have the aim to identify and understand the molecular pathway of ATMIN-dependent ATM signaling.
Summary
ATM is the protein kinase that is mutated in the hereditary autosomal recessive disease ataxia telangiectasia (A-T). A-T patients display immune deficiencies, cancer predisposition and radiosensitivity. The molecular role of ATM is to respond to DNA damage by phosphorylating its substrates, thereby promoting repair of damage or arresting the cell cycle. Following the induction of double-strand breaks (DSBs), the NBS1 protein is required for activation of ATM. But ATM can also be activated in the absence of DNA damage. Treatment of cultured cells with hypotonic stress leads to the activation of ATM, presumably due to changes in chromatin structure. We have recently described a second ATM cofactor, ATMIN (ATM INteractor). ATMIN is dispensable for DSBs-induced ATM signalling, but ATM activation following hypotonic stress is mediated by ATMIN. While the biological role of ATM activation by DSBs and NBS1 is well established, the significance, if any, of ATM activation by ATMIN and changes in chromatin was up to now completely enigmatic.
ATM is required for class switch recombination (CSR) and the suppression of translocations in B cells. In order to determine whether ATMIN is required for any of the physiological functions of ATM, we generated a conditional knock-out mouse model for ATMIN. ATM signaling was dramatically reduced following osmotic stress in ATMIN-mutant B cells. ATMIN deficiency led to impaired CSR, and consequently ATMIN-mutant mice developed B cell lymphomas. Thus ablation of ATMIN resulted in a severe defect in ATM function. Our data strongly argue for the existence of a second NBS1-independent mode of ATM activation that is physiologically relevant. While a large amount of scientific effort has gone into characterising ATM signaling triggered by DSBs, essentially nothing is known about NBS1-independent ATM signaling. The experiments outlined in this proposal have the aim to identify and understand the molecular pathway of ATMIN-dependent ATM signaling.
Max ERC Funding
1 499 881 €
Duration
Start date: 2012-02-01, End date: 2018-01-31
Project acronym BBSG
Project Bosnian Bones, Spanish Ghosts: 'Transitional Justice' and the Legal Shaping of Memory after Two Modern Conflicts
Researcher (PI) Sarah Lynn Wastell (Born Haller)
Host Institution (HI) GOLDSMITHS' COLLEGE
Call Details Starting Grant (StG), SH2, ERC-2009-StG
Summary The proposed research entails an ethnographic study of two contemporary cases of post-conflict reconciliation: one, the Bosnian case, where international intervention ended conflict in a stalemate and went on to instigate a decade-long process of transition; and the other, the Spanish case, where a nationally-contrived pact of silence introduced an overnight transition after Franco's death a pact now being broken nearly seventy years after the country's civil war concluded. Both societies witnessed massive violations of international humanitarian law. Both societies are presently exhuming, identifying and re-burying their dead. But their trajectories of transitional justice could not have been more different. This project will investigate how Law shapes cultural memories of wartime atrocity in these contrasting scenarios. How do criminal prosecutions, constitutional reforms, and international rights mechanisms, provide or obfuscate the scales into which histories of violent conflict are framed? Does the systematic re-structuring of legislative and judicial infrastructure stifle recognition of past abuses or does it create the conditions through which such pasts can be confronted? How does Law shape or inflect the cultural politics of memory and memorialisation? And most importantly, how should legal activity be weighted, prioritised and sequenced with other, extra-legal components of peace-building initiatives? The ultimate goal of this project will be to mobilise the findings from the two field-sites to suggest a more nuanced assessment of Law s place in transitional justice. Arguing that disparate historical, cultural and legal contexts require equally distinct approaches towards social healing, the research aims to produce a Post-Conflict Action Framework an architecture of questions and concerns, which, once answered, would point towards context-specific designs for transitional justice programmes in the future.
Summary
The proposed research entails an ethnographic study of two contemporary cases of post-conflict reconciliation: one, the Bosnian case, where international intervention ended conflict in a stalemate and went on to instigate a decade-long process of transition; and the other, the Spanish case, where a nationally-contrived pact of silence introduced an overnight transition after Franco's death a pact now being broken nearly seventy years after the country's civil war concluded. Both societies witnessed massive violations of international humanitarian law. Both societies are presently exhuming, identifying and re-burying their dead. But their trajectories of transitional justice could not have been more different. This project will investigate how Law shapes cultural memories of wartime atrocity in these contrasting scenarios. How do criminal prosecutions, constitutional reforms, and international rights mechanisms, provide or obfuscate the scales into which histories of violent conflict are framed? Does the systematic re-structuring of legislative and judicial infrastructure stifle recognition of past abuses or does it create the conditions through which such pasts can be confronted? How does Law shape or inflect the cultural politics of memory and memorialisation? And most importantly, how should legal activity be weighted, prioritised and sequenced with other, extra-legal components of peace-building initiatives? The ultimate goal of this project will be to mobilise the findings from the two field-sites to suggest a more nuanced assessment of Law s place in transitional justice. Arguing that disparate historical, cultural and legal contexts require equally distinct approaches towards social healing, the research aims to produce a Post-Conflict Action Framework an architecture of questions and concerns, which, once answered, would point towards context-specific designs for transitional justice programmes in the future.
Max ERC Funding
1 420 000 €
Duration
Start date: 2009-09-01, End date: 2013-08-31
Project acronym BEACON
Project Hybrid Digital-Analog Networking under Extreme Energy and Latency Constraints
Researcher (PI) Deniz Gunduz
Host Institution (HI) IMPERIAL COLLEGE OF SCIENCE TECHNOLOGY AND MEDICINE
Call Details Starting Grant (StG), PE7, ERC-2015-STG
Summary The objective of the BEACON project is to (re-)introduce analog communications into the design of modern wireless networks. We argue that the extreme energy and latency constraints imposed by the emerging Internet of Everything (IoE) paradigm can only be met within a hybrid digital-analog communications framework. Current network architectures separate source and channel coding, orthogonalize users, and employ long block-length digital source and channel codes, which are either suboptimal or not applicable under the aforementioned constraints. BEACON questions these well-established design principles, and proposes to replace them with a hybrid digital-analog communications framework, which will meet the required energy and latency constraints while simplifying the encoding and decoding processes. BEACON pushes the performance of the IoE to its theoretical limits by i) exploiting signal correlations that are abundant in IoE applications, given the foreseen density of deployed sensing devices, ii) taking into account the limited and stochastic nature of energy availability due to, for example, energy harvesting capabilities, iii) using feedback resources to improve the end-to-end signal distortion, and iv) deriving novel converse results to identify fundamental performance benchmarks.
The results of BEACON will not only shed light on the fundamental limits on the performance any coding scheme can achieve, but will also lead to the development of unconventional codes and communication protocols that can approach these limits, combining digital and analog communication techniques. The ultimate challenge for this project is to exploit the developed hybrid digital-analog networking theory for a complete overhaul of the physical layer design for emerging IoE applications, such as smart grids, tele-robotics and smart homes. For this purpose, a proof-of-concept implementation test-bed will also be built using software defined radios and sensor nodes.
Summary
The objective of the BEACON project is to (re-)introduce analog communications into the design of modern wireless networks. We argue that the extreme energy and latency constraints imposed by the emerging Internet of Everything (IoE) paradigm can only be met within a hybrid digital-analog communications framework. Current network architectures separate source and channel coding, orthogonalize users, and employ long block-length digital source and channel codes, which are either suboptimal or not applicable under the aforementioned constraints. BEACON questions these well-established design principles, and proposes to replace them with a hybrid digital-analog communications framework, which will meet the required energy and latency constraints while simplifying the encoding and decoding processes. BEACON pushes the performance of the IoE to its theoretical limits by i) exploiting signal correlations that are abundant in IoE applications, given the foreseen density of deployed sensing devices, ii) taking into account the limited and stochastic nature of energy availability due to, for example, energy harvesting capabilities, iii) using feedback resources to improve the end-to-end signal distortion, and iv) deriving novel converse results to identify fundamental performance benchmarks.
The results of BEACON will not only shed light on the fundamental limits on the performance any coding scheme can achieve, but will also lead to the development of unconventional codes and communication protocols that can approach these limits, combining digital and analog communication techniques. The ultimate challenge for this project is to exploit the developed hybrid digital-analog networking theory for a complete overhaul of the physical layer design for emerging IoE applications, such as smart grids, tele-robotics and smart homes. For this purpose, a proof-of-concept implementation test-bed will also be built using software defined radios and sensor nodes.
Max ERC Funding
1 496 350 €
Duration
Start date: 2016-10-01, End date: 2021-09-30
Project acronym BENELEX
Project Benefit-sharing for an equitable transition to the green economy - the role of law
Researcher (PI) Elisa Morgera
Host Institution (HI) UNIVERSITY OF STRATHCLYDE
Call Details Starting Grant (StG), SH2, ERC-2013-StG
Summary Can benefit-sharing address the equity deficit within the green economy? This project aims to investigate benefit-sharing as an under-theorised and little-implemented regulatory approach to the equity concerns (disregard for the special circumstances of developing countries and of indigenous peoples and local communities) in transitioning to the green economy.
Although benefit-sharing is increasingly deployed in a variety of international environmental agreements and also in human rights and corporate accountability instruments, no comprehensive account exists of its conceptual and practical relevance to equitably address global environmental challenges. This project will be the first systematic evaluation of the conceptualisations and operationalisations of benefit-sharing as a tool for equitable change through the allocation among different stakeholders of economic and also socio-cultural and environmental advantages arising from natural resource use.
The project will combine a comparative study of international law with empirical legal research, and include an inter-disciplinary study integrating political sociology in a legal enquiry on the role of “biocultural community protocols” that articulate and implement benefit-sharing at the intersection of international, transnational, national and indigenous communities’ customary law (global environmental law).
The project aims to: 1. develop a comprehensive understanding of benefit-sharing in international law; 2. clarify whether and how benefit-sharing supports equity and the protection of human rights across key sectors of international environmental regulation (biodiversity, climate change, oceans, food and agriculture) that are seen as inter-related in the transition to the green economy; 3. understand the development of benefit-sharing in the context of global environmental law; and
4. clarify the role of transnational legal advisors (NGOs and bilateral cooperation partners) in the green economy.
Summary
Can benefit-sharing address the equity deficit within the green economy? This project aims to investigate benefit-sharing as an under-theorised and little-implemented regulatory approach to the equity concerns (disregard for the special circumstances of developing countries and of indigenous peoples and local communities) in transitioning to the green economy.
Although benefit-sharing is increasingly deployed in a variety of international environmental agreements and also in human rights and corporate accountability instruments, no comprehensive account exists of its conceptual and practical relevance to equitably address global environmental challenges. This project will be the first systematic evaluation of the conceptualisations and operationalisations of benefit-sharing as a tool for equitable change through the allocation among different stakeholders of economic and also socio-cultural and environmental advantages arising from natural resource use.
The project will combine a comparative study of international law with empirical legal research, and include an inter-disciplinary study integrating political sociology in a legal enquiry on the role of “biocultural community protocols” that articulate and implement benefit-sharing at the intersection of international, transnational, national and indigenous communities’ customary law (global environmental law).
The project aims to: 1. develop a comprehensive understanding of benefit-sharing in international law; 2. clarify whether and how benefit-sharing supports equity and the protection of human rights across key sectors of international environmental regulation (biodiversity, climate change, oceans, food and agriculture) that are seen as inter-related in the transition to the green economy; 3. understand the development of benefit-sharing in the context of global environmental law; and
4. clarify the role of transnational legal advisors (NGOs and bilateral cooperation partners) in the green economy.
Max ERC Funding
1 481 708 €
Duration
Start date: 2013-11-01, End date: 2018-10-31
Project acronym Bionetworking
Project Bionetworking in Asia – A social science approach to international collaboration, informal exchanges, and responsible innovation in the life sciences
Researcher (PI) Margaret Elizabeth Sleeboom-Faulkner
Host Institution (HI) THE UNIVERSITY OF SUSSEX
Call Details Starting Grant (StG), SH2, ERC-2011-StG_20101124
Summary Bio-medical innovation makes a substantial contribution to Western societies and economies. But leading research organisations in the West are increasingly reliant on clinical research conducted beyond the West. Such initiatives are challenged by uncertainties about research quality and therapeutic practices in Asian countries. These only partly justified uncertainties are augmented by unfamiliar conditions. This study examines how to create responsible innovation in the life sciences by looking for ways to overcome existing obstacles to safe, just and ethical international science collaborations.
Building on observations of scientists, managers and patients and supported by Asian language expertise, biology background, and experience with science and technology policy-making, we examine the roles of regional differences and inequalities in the networks used for patient recruitment and international research agreements. Profit-motivated networks in the life sciences also occur underground and at an informal, unregulated level, which we call bionetworking. Bionetworking is a social entrepreneurial activity involving biomedical research, healthcare and patient networks that are maintained by taking advantage of regionally differences in levels of science and technology, healthcare, education and regulatory regimes.
Using novel social-science methods, the project studies two main themes. Theme 1 examines patient recruitment networks for experimental stem cell therapies and cooperation between research and health institutions involving exchanges of patients against other resources. Theme 2 maps and analyses exchanges of biomaterials of human derivation, and forms of ‘ownership’ rights, benefits and burdens associated with their donation, possession, maintenance, and application. Integral analysis of the project nodes incorporates an analysis of public health policy and patient preference in relation to Responsible innovation, Good governance and Global assemblages.
Summary
Bio-medical innovation makes a substantial contribution to Western societies and economies. But leading research organisations in the West are increasingly reliant on clinical research conducted beyond the West. Such initiatives are challenged by uncertainties about research quality and therapeutic practices in Asian countries. These only partly justified uncertainties are augmented by unfamiliar conditions. This study examines how to create responsible innovation in the life sciences by looking for ways to overcome existing obstacles to safe, just and ethical international science collaborations.
Building on observations of scientists, managers and patients and supported by Asian language expertise, biology background, and experience with science and technology policy-making, we examine the roles of regional differences and inequalities in the networks used for patient recruitment and international research agreements. Profit-motivated networks in the life sciences also occur underground and at an informal, unregulated level, which we call bionetworking. Bionetworking is a social entrepreneurial activity involving biomedical research, healthcare and patient networks that are maintained by taking advantage of regionally differences in levels of science and technology, healthcare, education and regulatory regimes.
Using novel social-science methods, the project studies two main themes. Theme 1 examines patient recruitment networks for experimental stem cell therapies and cooperation between research and health institutions involving exchanges of patients against other resources. Theme 2 maps and analyses exchanges of biomaterials of human derivation, and forms of ‘ownership’ rights, benefits and burdens associated with their donation, possession, maintenance, and application. Integral analysis of the project nodes incorporates an analysis of public health policy and patient preference in relation to Responsible innovation, Good governance and Global assemblages.
Max ERC Funding
1 497 711 €
Duration
Start date: 2012-02-01, End date: 2017-01-31
Project acronym BIOPROPERTY
Project Biomedical Research and the Future of Property Rights
Researcher (PI) Javier Lezaun Barreras
Host Institution (HI) THE CHANCELLOR, MASTERS AND SCHOLARS OF THE UNIVERSITY OF OXFORD
Call Details Starting Grant (StG), SH2, ERC-2010-StG_20091209
Summary This research project investigates the dynamics of private and public property in contemporary biomedical research. It will develop an analytical framework combining insights from science and technology studies, economic sociology, and legal and political philosophy, and pursues a social scientific investigation of the evolution of intellectual property rights in three fields of bioscientific research: 1) the use of transgenic research mice; 2) the legal status of totipotent and pluripotent stem cell lines; and 3) modes of collaboration for research and development on neglected diseases. These three domains, and their attendant modes of appropriation, will be compared across three general research themes: a) the production of public scientific goods; b) categories of appropriation; and c) the moral economy of research. The project rests on close observation of research practices in these three domains. The BioProperty research programme will track the trajectories of property rights and property objects in each of the three fields of biomedical research.
Summary
This research project investigates the dynamics of private and public property in contemporary biomedical research. It will develop an analytical framework combining insights from science and technology studies, economic sociology, and legal and political philosophy, and pursues a social scientific investigation of the evolution of intellectual property rights in three fields of bioscientific research: 1) the use of transgenic research mice; 2) the legal status of totipotent and pluripotent stem cell lines; and 3) modes of collaboration for research and development on neglected diseases. These three domains, and their attendant modes of appropriation, will be compared across three general research themes: a) the production of public scientific goods; b) categories of appropriation; and c) the moral economy of research. The project rests on close observation of research practices in these three domains. The BioProperty research programme will track the trajectories of property rights and property objects in each of the three fields of biomedical research.
Max ERC Funding
887 602 €
Duration
Start date: 2011-03-01, End date: 2014-12-31
Project acronym BIOSYNCEN
Project Dissection of centromeric chromatin and components: A biosynthetic approach
Researcher (PI) Patrick Heun
Host Institution (HI) THE UNIVERSITY OF EDINBURGH
Call Details Starting Grant (StG), LS2, ERC-2012-StG_20111109
Summary The centromere is one of the most important chromosomal elements. It is required for proper chromosome segregation in mitosis and meiosis and readily recognizable as the primary constriction of mitotic chromosomes. Proper centromere function is essential to ensure genome stability; therefore understanding centromere identity is directly relevant to cancer biology and gene therapy. How centromeres are established and maintained is however still an open question in the field. In most organisms this appears to be regulated by an epigenetic mechanism. The key candidate for such an epigenetic mark is CENH3 (CENP-A in mammals, CID in Drosophila), a centromere-specific histone H3 variant that is essential for centromere function and exclusively found in the nucleosomes of centromeric chromatin. Using a biosynthetic approach of force-targeting CENH3 in Drosophila to non-centromeric DNA, we were able to induce centromere function and demonstrate that CENH3 is sufficient to determine centromere identity. Here we propose to move this experimental setup across evolutionary boundaries into human cells to develop improved human artificial chromosomes (HACs). We will make further use of this unique setup to dissect the function of targeted CENH3 both in Drosophila and human cells. Contributing centromeric components and histone modifications of centromeric chromatin will be characterized in detail by mass spectroscopy in Drosophila. Finally we are proposing to develop a technique that allows high-resolution mapping of proteins on repetitive DNA to help further characterizing known and novel centromere components. This will be achieved by combining two independently established techniques: DNA methylation and DNA fiber combing. This ambitious proposal will significantly advance our understanding of how centromeres are determined and help the development of improved HACs for therapeutic applications in the future.
Summary
The centromere is one of the most important chromosomal elements. It is required for proper chromosome segregation in mitosis and meiosis and readily recognizable as the primary constriction of mitotic chromosomes. Proper centromere function is essential to ensure genome stability; therefore understanding centromere identity is directly relevant to cancer biology and gene therapy. How centromeres are established and maintained is however still an open question in the field. In most organisms this appears to be regulated by an epigenetic mechanism. The key candidate for such an epigenetic mark is CENH3 (CENP-A in mammals, CID in Drosophila), a centromere-specific histone H3 variant that is essential for centromere function and exclusively found in the nucleosomes of centromeric chromatin. Using a biosynthetic approach of force-targeting CENH3 in Drosophila to non-centromeric DNA, we were able to induce centromere function and demonstrate that CENH3 is sufficient to determine centromere identity. Here we propose to move this experimental setup across evolutionary boundaries into human cells to develop improved human artificial chromosomes (HACs). We will make further use of this unique setup to dissect the function of targeted CENH3 both in Drosophila and human cells. Contributing centromeric components and histone modifications of centromeric chromatin will be characterized in detail by mass spectroscopy in Drosophila. Finally we are proposing to develop a technique that allows high-resolution mapping of proteins on repetitive DNA to help further characterizing known and novel centromere components. This will be achieved by combining two independently established techniques: DNA methylation and DNA fiber combing. This ambitious proposal will significantly advance our understanding of how centromeres are determined and help the development of improved HACs for therapeutic applications in the future.
Max ERC Funding
1 755 960 €
Duration
Start date: 2013-02-01, End date: 2019-01-31
