Project acronym AGRISCENTS
Project Scents and sensibility in agriculture: exploiting specificity in herbivore- and pathogen-induced plant volatiles for real-time crop monitoring
Researcher (PI) Theodoor Turlings
Host Institution (HI) UNIVERSITE DE NEUCHATEL
Country Switzerland
Call Details Advanced Grant (AdG), LS9, ERC-2017-ADG
Summary Plants typically release large quantities of volatiles in response to attack by herbivores or pathogens. I may claim to have contributed to various breakthroughs in this research field, including the discovery that the volatile blends induced by different attackers are astonishingly specific, resulting in characteristic, readily distinguishable odour blends. Using maize as our model plant, I wish to take several leaps forward in our understanding of this signal specificity and use this knowledge to develop sensors for the real-time detection of crop pests and diseases. For this, three interconnected work-packages will aim to:
• Develop chemical analytical techniques and statistical models to decipher the odorous vocabulary of plants, and to create a complete inventory of “odour-prints” for a wide range of herbivore-plant and pathogen-plant combinations, including simultaneous infestations.
• Develop and optimize nano-mechanical sensors for the detection of specific plant volatile mixtures. For this, we will initially adapt a prototype sensor that has been successfully developed for the detection of cancer-related volatiles in human breath.
• Genetically manipulate maize plants to release a unique blend of root-produced volatiles upon herbivory. For this, we will engineer gene cassettes that combine recently identified P450 (CYP) genes from poplar with inducible, root-specific promoters from maize. This will result in maize plants that, in response to pest attack, release easy-to-detect aldoximes and nitriles from their roots.
In short, by investigating and manipulating the specificity of inducible odour blends we will generate the necessary knowhow to develop a novel odour-detection device. The envisioned sensor technology will permit real-time monitoring of the pests and enable farmers to apply crop protection treatments at the right time and in the right place.
Summary
Plants typically release large quantities of volatiles in response to attack by herbivores or pathogens. I may claim to have contributed to various breakthroughs in this research field, including the discovery that the volatile blends induced by different attackers are astonishingly specific, resulting in characteristic, readily distinguishable odour blends. Using maize as our model plant, I wish to take several leaps forward in our understanding of this signal specificity and use this knowledge to develop sensors for the real-time detection of crop pests and diseases. For this, three interconnected work-packages will aim to:
• Develop chemical analytical techniques and statistical models to decipher the odorous vocabulary of plants, and to create a complete inventory of “odour-prints” for a wide range of herbivore-plant and pathogen-plant combinations, including simultaneous infestations.
• Develop and optimize nano-mechanical sensors for the detection of specific plant volatile mixtures. For this, we will initially adapt a prototype sensor that has been successfully developed for the detection of cancer-related volatiles in human breath.
• Genetically manipulate maize plants to release a unique blend of root-produced volatiles upon herbivory. For this, we will engineer gene cassettes that combine recently identified P450 (CYP) genes from poplar with inducible, root-specific promoters from maize. This will result in maize plants that, in response to pest attack, release easy-to-detect aldoximes and nitriles from their roots.
In short, by investigating and manipulating the specificity of inducible odour blends we will generate the necessary knowhow to develop a novel odour-detection device. The envisioned sensor technology will permit real-time monitoring of the pests and enable farmers to apply crop protection treatments at the right time and in the right place.
Max ERC Funding
2 498 086 €
Duration
Start date: 2018-09-01, End date: 2023-08-31
Project acronym AMIMOS
Project Agile MIMO Systems for Communications, Biomedicine, and Defense
Researcher (PI) Bjorn Ottersten
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Country Sweden
Call Details Advanced Grant (AdG), PE7, ERC-2008-AdG
Summary This proposal targets the emerging frontier research field of multiple-input multiple-output (MIMO) systems along with several innovative and somewhat unconventional applications of such systems. The use of arrays of transmitters and receivers will have a profound impact on future medical imaging/therapy systems, radar systems, and radio communication networks. Multiple transmitters provide a tremendous versatility and allow waveforms to be adapted temporally and spatially to environmental conditions. This is useful for individually tailored illumination of human tissue in biomedical imaging or ultrasound therapy. In radar systems, multiple transmit beams can be formed simultaneously via separate waveform designs allowing accurate target classification. In a wireless communication system, multiple communication signals can be directed to one or more users at the same time on the same frequency carrier. In addition, multiple receivers can be used in the above applications to provide increased detection performance, interference rejection, and improved estimation accuracy. The joint modelling, analysis, and design of these multidimensional transmit and receive schemes form the core of this research proposal. Ultimately, our research aims at developing the fundamental tools that will allow the design of wireless communication systems with an order-of-magnitude higher capacity at a lower cost than today; of ultrasound therapy systems maximizing delivered power while reducing treatment duration and unwanted illumination; and of distributed aperture multi-beam radars allowing more effective target location, identification, and classification. Europe has several successful industries that are active in biomedical imaging/therapy, radar systems, and wireless communications. The future success of these sectors critically depends on the ability to innovate and integrate new technology.
Summary
This proposal targets the emerging frontier research field of multiple-input multiple-output (MIMO) systems along with several innovative and somewhat unconventional applications of such systems. The use of arrays of transmitters and receivers will have a profound impact on future medical imaging/therapy systems, radar systems, and radio communication networks. Multiple transmitters provide a tremendous versatility and allow waveforms to be adapted temporally and spatially to environmental conditions. This is useful for individually tailored illumination of human tissue in biomedical imaging or ultrasound therapy. In radar systems, multiple transmit beams can be formed simultaneously via separate waveform designs allowing accurate target classification. In a wireless communication system, multiple communication signals can be directed to one or more users at the same time on the same frequency carrier. In addition, multiple receivers can be used in the above applications to provide increased detection performance, interference rejection, and improved estimation accuracy. The joint modelling, analysis, and design of these multidimensional transmit and receive schemes form the core of this research proposal. Ultimately, our research aims at developing the fundamental tools that will allow the design of wireless communication systems with an order-of-magnitude higher capacity at a lower cost than today; of ultrasound therapy systems maximizing delivered power while reducing treatment duration and unwanted illumination; and of distributed aperture multi-beam radars allowing more effective target location, identification, and classification. Europe has several successful industries that are active in biomedical imaging/therapy, radar systems, and wireless communications. The future success of these sectors critically depends on the ability to innovate and integrate new technology.
Max ERC Funding
1 872 720 €
Duration
Start date: 2009-01-01, End date: 2013-12-31
Project acronym ANALYTICAL SOCIOLOGY
Project Analytical Sociology: Theoretical Developments and Empirical Research
Researcher (PI) Mats Peter Hedstroem
Host Institution (HI) LINKOPINGS UNIVERSITET
Country Sweden
Call Details Advanced Grant (AdG), SH2, ERC-2012-ADG_20120411
Summary This proposal outlines a highly ambitious and path-breaking research program. Through a tightly integrated package of basic theoretical work, strategic empirical research projects, international workshops, and a large number of publications in leading journals, the research program seeks to move sociology in a more analytical direction.
One part of the research program focuses on the epistemological and methodological foundations of analytical sociology, an approach to sociological theory and research that currently receives considerable attention in the international scholarly community. This work will be organized around two core themes: (1) the principles of mechanism-based explanations and (2) the micro-macro link.
The empirical research analyzes in great detail the ethnic, gender, and socio-economic segregation of key interaction domains in Sweden using the approach of analytical sociology. The interaction domains focused upon are schools, workplaces and neighborhoods; domains where people spend a considerable part of their time, where much of the social interaction between people takes place, where identities are formed, and where important resources are distributed.
Large-scale longitudinal micro data on the entire Swedish population, unique longitudinal data on social networks within school classes, and various agent-based simulation techniques, are used to better understand the processes through which schools, workplaces and neighborhoods become segregated along various dimensions, how the domains interact with one another, and how the structure and extent of segregation affects diverse social and economic outcomes.
Summary
This proposal outlines a highly ambitious and path-breaking research program. Through a tightly integrated package of basic theoretical work, strategic empirical research projects, international workshops, and a large number of publications in leading journals, the research program seeks to move sociology in a more analytical direction.
One part of the research program focuses on the epistemological and methodological foundations of analytical sociology, an approach to sociological theory and research that currently receives considerable attention in the international scholarly community. This work will be organized around two core themes: (1) the principles of mechanism-based explanations and (2) the micro-macro link.
The empirical research analyzes in great detail the ethnic, gender, and socio-economic segregation of key interaction domains in Sweden using the approach of analytical sociology. The interaction domains focused upon are schools, workplaces and neighborhoods; domains where people spend a considerable part of their time, where much of the social interaction between people takes place, where identities are formed, and where important resources are distributed.
Large-scale longitudinal micro data on the entire Swedish population, unique longitudinal data on social networks within school classes, and various agent-based simulation techniques, are used to better understand the processes through which schools, workplaces and neighborhoods become segregated along various dimensions, how the domains interact with one another, and how the structure and extent of segregation affects diverse social and economic outcomes.
Max ERC Funding
1 745 098 €
Duration
Start date: 2013-03-01, End date: 2018-02-28
Project acronym BIRD
Project Bimanual Manipulation of Rigid and Deformable Objects
Researcher (PI) Danica KRAGIC JENSFELT
Host Institution (HI) KUNGLIGA TEKNISKA HOEGSKOLAN
Country Sweden
Call Details Advanced Grant (AdG), PE7, ERC-2019-ADG
Summary All day long, our fingers touch, grasp and move objects in various media such as air, water, oil. We do this almost effortlessly - it feels like we do not spend time planning and reflecting over what our hands and fingers do or how the continuous integration of various sensory modalities such as vision, touch, proprioception, hearing help us to outperform any other biological system in the variety of the interaction tasks that we can execute. Largely overlooked, and perhaps most fascinating is the ease with which we perform these interactions resulting in a belief that these are also easy to accomplish in artificial systems such as robots. However, there are still no robots that can easily hand-wash dishes, button a shirt or peel a potato. Our claim is that this is fundamentally a problem of appropriate representation or parameterization. When interacting with objects, the robot needs to consider geometric, topological, and physical properties of objects. This can be done either explicitly, by modeling and representing these properties, or implicitly, by learning them from data. The main scientific objective of this project is to create new informative and compact representations of deformable objects that incorporate both analytical and learning-based approaches and encode geometric, topological, and physical information about the robot, the object, and the environment. We will do this in the context of challenging multimodal, bimanual object interaction tasks. The focus will be on physical interaction with deformable objects using multimodal feedback. To meet these objectives, we will use theoretical and computational methods together with rigorous experimental evaluation to model skilled sensorimotor behavior in bimanual robot systems.
Summary
All day long, our fingers touch, grasp and move objects in various media such as air, water, oil. We do this almost effortlessly - it feels like we do not spend time planning and reflecting over what our hands and fingers do or how the continuous integration of various sensory modalities such as vision, touch, proprioception, hearing help us to outperform any other biological system in the variety of the interaction tasks that we can execute. Largely overlooked, and perhaps most fascinating is the ease with which we perform these interactions resulting in a belief that these are also easy to accomplish in artificial systems such as robots. However, there are still no robots that can easily hand-wash dishes, button a shirt or peel a potato. Our claim is that this is fundamentally a problem of appropriate representation or parameterization. When interacting with objects, the robot needs to consider geometric, topological, and physical properties of objects. This can be done either explicitly, by modeling and representing these properties, or implicitly, by learning them from data. The main scientific objective of this project is to create new informative and compact representations of deformable objects that incorporate both analytical and learning-based approaches and encode geometric, topological, and physical information about the robot, the object, and the environment. We will do this in the context of challenging multimodal, bimanual object interaction tasks. The focus will be on physical interaction with deformable objects using multimodal feedback. To meet these objectives, we will use theoretical and computational methods together with rigorous experimental evaluation to model skilled sensorimotor behavior in bimanual robot systems.
Max ERC Funding
2 424 186 €
Duration
Start date: 2020-09-01, End date: 2025-08-31
Project acronym BONE SCAN
Project Traces in the bones: reconstructing the lost soft anatomy of the earliest vertebrates through ultra-high resolution synchrotron scanning
Researcher (PI) Per Erik Ahlberg
Host Institution (HI) UPPSALA UNIVERSITET
Country Sweden
Call Details Advanced Grant (AdG), LS8, ERC-2008-AdG
Summary Early vertebrate evolution involved a series of drastic structural reorganisations as new features were added and elaborated. The fossil record illuminates this evolutionary history more directly than inferences from the diversity of living forms, but the fossils usually consist only of bones whereas many of the most important and interesting changes occurred in the soft anatomy. Traditional approaches to reconstructing the musculature and other soft tissues of fossil vertebrates rely on subjective tools, like the visual identification of rough bone textures thought to indicate muscle attachments, and generally leave a lot to be desired. Here I propose a wholly novel and radically more objective approach to the identification of soft-tissue contacts, using holotomographic synchrotron CT at sub-micron resolutions to identify these contacts by the three-dimensional micro-architecture of the bone. A pilot study has already shown that such scans (performed at the ESRF synchrotron facility in Grenoble) are capable of imaging key features such as arrested growth surfaces and probable Sharpey s fibres in 380 million year old fossils. We will undertake a systematic review of the three-dimensional bone micro-architectures associated with different soft-tissue contacts in living vertebrates, and the use this as a key to reconstruct the soft-tissue contacts on fossil bones with unprecedented accuracy. This will permit us to produce far more reliable reconstructions of the soft anatomy than has hitherto been possible. Our findings will inform other areas of palaentology, particularly functional morphology, and will also be of great importance to evolutionary developmental biology.
Summary
Early vertebrate evolution involved a series of drastic structural reorganisations as new features were added and elaborated. The fossil record illuminates this evolutionary history more directly than inferences from the diversity of living forms, but the fossils usually consist only of bones whereas many of the most important and interesting changes occurred in the soft anatomy. Traditional approaches to reconstructing the musculature and other soft tissues of fossil vertebrates rely on subjective tools, like the visual identification of rough bone textures thought to indicate muscle attachments, and generally leave a lot to be desired. Here I propose a wholly novel and radically more objective approach to the identification of soft-tissue contacts, using holotomographic synchrotron CT at sub-micron resolutions to identify these contacts by the three-dimensional micro-architecture of the bone. A pilot study has already shown that such scans (performed at the ESRF synchrotron facility in Grenoble) are capable of imaging key features such as arrested growth surfaces and probable Sharpey s fibres in 380 million year old fossils. We will undertake a systematic review of the three-dimensional bone micro-architectures associated with different soft-tissue contacts in living vertebrates, and the use this as a key to reconstruct the soft-tissue contacts on fossil bones with unprecedented accuracy. This will permit us to produce far more reliable reconstructions of the soft anatomy than has hitherto been possible. Our findings will inform other areas of palaentology, particularly functional morphology, and will also be of great importance to evolutionary developmental biology.
Max ERC Funding
1 046 782 €
Duration
Start date: 2009-04-01, End date: 2014-03-31
Project acronym BOTMED
Project Microrobotics and Nanomedicine
Researcher (PI) Bradley James Nelson
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Country Switzerland
Call Details Advanced Grant (AdG), PE7, ERC-2010-AdG_20100224
Summary The introduction of minimally invasive surgery in the 1980’s created a paradigm shift in surgical procedures. Health care is now in a position to make a more dramatic leap by integrating newly developed wireless microrobotic technologies with nanomedicine to perform precisely targeted, localized endoluminal techniques. Devices capable of entering the human body through natural orifices or small incisions to deliver drugs, perform diagnostic procedures, and excise and repair tissue will be used. These new procedures will result in less trauma to the patient and faster recovery times, and will enable new therapies that have not yet been conceived. In order to realize this, many new technologies must be developed and synergistically integrated, and medical therapies for which the technology will prove successful must be aggressively pursued.
This proposed project will result in the realization of animal trials in which wireless microrobotic devices will be used to investigate a variety of extremely delicate ophthalmic therapies. The therapies to be pursued include the delivery of tissue plasminogen activator (t-PA) to blocked retinal veins, the peeling of epiretinal membranes from the retina, and the development of diagnostic procedures based on mapping oxygen concentration at the vitreous-retina interface. With successful animal trials, a path to human trials and commercialization will follow. Clearly, many systems in the body have the potential to benefit from the endoluminal technologies that this project considers, including the digestive system, the circulatory system, the urinary system, the central nervous system, the respiratory system, the female reproductive system and even the fetus. Microrobotic retinal therapies will greatly illuminate the potential that the integration of microrobotics and nanomedicine holds for society, and greatly accelerate this trend in Europe.
Summary
The introduction of minimally invasive surgery in the 1980’s created a paradigm shift in surgical procedures. Health care is now in a position to make a more dramatic leap by integrating newly developed wireless microrobotic technologies with nanomedicine to perform precisely targeted, localized endoluminal techniques. Devices capable of entering the human body through natural orifices or small incisions to deliver drugs, perform diagnostic procedures, and excise and repair tissue will be used. These new procedures will result in less trauma to the patient and faster recovery times, and will enable new therapies that have not yet been conceived. In order to realize this, many new technologies must be developed and synergistically integrated, and medical therapies for which the technology will prove successful must be aggressively pursued.
This proposed project will result in the realization of animal trials in which wireless microrobotic devices will be used to investigate a variety of extremely delicate ophthalmic therapies. The therapies to be pursued include the delivery of tissue plasminogen activator (t-PA) to blocked retinal veins, the peeling of epiretinal membranes from the retina, and the development of diagnostic procedures based on mapping oxygen concentration at the vitreous-retina interface. With successful animal trials, a path to human trials and commercialization will follow. Clearly, many systems in the body have the potential to benefit from the endoluminal technologies that this project considers, including the digestive system, the circulatory system, the urinary system, the central nervous system, the respiratory system, the female reproductive system and even the fetus. Microrobotic retinal therapies will greatly illuminate the potential that the integration of microrobotics and nanomedicine holds for society, and greatly accelerate this trend in Europe.
Max ERC Funding
2 498 044 €
Duration
Start date: 2011-04-01, End date: 2016-03-31
Project acronym CoCi
Project Co-Evolving City Life
Researcher (PI) Dirk HELBING
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Country Switzerland
Call Details Advanced Grant (AdG), SH2, ERC-2018-ADG
Summary How could networks of innovative cities contribute to the solution of humanity’s existential problems? Given the on-going digital revolution and our present-day sustainability challenges, we have to reinvent the way cities are operated. We propose that the requirement of organizing cities in a more resilient way implies the need for more decentralized solutions, based on digitally assisted self-organization, and that this concept is also compatible with sustainability requirements and stronger democratic participation. The CoCi proposal will investigate, whether such a decentralized, participatory approach could compete with a fully centralized approach in terms of efficiency and sustainability, or perform even better than that. This requires in particular to figure out, how distributed co-creation processes can be coordinated and lifted to a professional level in a scalable way. The main questions of the CoCi proposal are: How could more participatory smart cities work, and how can they meet the requirements of being more efficient, sustainable and resilient? What are their risks and benefits compared with centralized approaches? How could digital societies fitting our culture, for example, based on values such as freedom, equality and solidarity (liberté, égalité, fraternité) look like, and what performance can be expected from them? The CoCi proposal brings together two research directions: first, the automation of mobility solutions based on the Internet of Things and Machine Learning approaches, as they have been pursued within the “smart cities” paradigm and, second, novel collaborative approaches as they have been recently discussed under labels such as participatory resilience, digital democracy, City Olympics, open source urbanism, and the “socio-ecological finance system”.
Summary
How could networks of innovative cities contribute to the solution of humanity’s existential problems? Given the on-going digital revolution and our present-day sustainability challenges, we have to reinvent the way cities are operated. We propose that the requirement of organizing cities in a more resilient way implies the need for more decentralized solutions, based on digitally assisted self-organization, and that this concept is also compatible with sustainability requirements and stronger democratic participation. The CoCi proposal will investigate, whether such a decentralized, participatory approach could compete with a fully centralized approach in terms of efficiency and sustainability, or perform even better than that. This requires in particular to figure out, how distributed co-creation processes can be coordinated and lifted to a professional level in a scalable way. The main questions of the CoCi proposal are: How could more participatory smart cities work, and how can they meet the requirements of being more efficient, sustainable and resilient? What are their risks and benefits compared with centralized approaches? How could digital societies fitting our culture, for example, based on values such as freedom, equality and solidarity (liberté, égalité, fraternité) look like, and what performance can be expected from them? The CoCi proposal brings together two research directions: first, the automation of mobility solutions based on the Internet of Things and Machine Learning approaches, as they have been pursued within the “smart cities” paradigm and, second, novel collaborative approaches as they have been recently discussed under labels such as participatory resilience, digital democracy, City Olympics, open source urbanism, and the “socio-ecological finance system”.
Max ERC Funding
2 499 500 €
Duration
Start date: 2020-10-01, End date: 2025-09-30
Project acronym CyberGenetics
Project Cybergenetics: Theory and Design Tools for Biomolecular Control Systems
Researcher (PI) Mustafa KHAMMASH
Host Institution (HI) EIDGENOESSISCHE TECHNISCHE HOCHSCHULE ZUERICH
Country Switzerland
Call Details Advanced Grant (AdG), PE7, ERC-2016-ADG
Summary We propose to develop a new theory and design tools for the estimation and real-time control of living cells. The control systems designed using these tools will precisely and robustly steer the dynamic behavior of living cells in real time to achieve desired objectives. Cells would be controlled either collectively at the population level, or individually as single cells. The control systems achieving this regulation will be realized either on a digital computer that is interfaced with living cells, or using de novo genetic circuits that are introduced into the cells where they are designed to function as molecular control systems. Our methods will explicitly confront the numerous challenges brought about by the special environment of the cell including nonlinearity, stochasticity, cell-to-cell variability, metabolic burden, etc. The theory and methods developed in this project will thus enable the systematic, rational, and effective feedback control of living cells at the gene level, and will lay the foundation for a new corresponding body of knowledge which we call ``Cybergenetics''. It will also open new research directions in the areas of control theory and estimation.
We also propose to design three cybergenetic control systems, each addressing an important application in biotechnology or therapeutics. In the first, the controller will use light and nutrient supply to precisely regulate gene expression and cell growth in E. coli to achieve high protein and low biomass production rates. The second involves multiple feedback controllers regulating in parallel a large number of single stem cells, and leading to their differentiation to desired fates, e.g. beta cells, with potential for therapeutic applications. Finally, we will engineer into living cells dynamic molecular control systems. Such controllers can be used to monitor physiological variables and secrete biological effectors in a feedback fashion for the treatment of diseases like Type 1 diabetes.
Summary
We propose to develop a new theory and design tools for the estimation and real-time control of living cells. The control systems designed using these tools will precisely and robustly steer the dynamic behavior of living cells in real time to achieve desired objectives. Cells would be controlled either collectively at the population level, or individually as single cells. The control systems achieving this regulation will be realized either on a digital computer that is interfaced with living cells, or using de novo genetic circuits that are introduced into the cells where they are designed to function as molecular control systems. Our methods will explicitly confront the numerous challenges brought about by the special environment of the cell including nonlinearity, stochasticity, cell-to-cell variability, metabolic burden, etc. The theory and methods developed in this project will thus enable the systematic, rational, and effective feedback control of living cells at the gene level, and will lay the foundation for a new corresponding body of knowledge which we call ``Cybergenetics''. It will also open new research directions in the areas of control theory and estimation.
We also propose to design three cybergenetic control systems, each addressing an important application in biotechnology or therapeutics. In the first, the controller will use light and nutrient supply to precisely regulate gene expression and cell growth in E. coli to achieve high protein and low biomass production rates. The second involves multiple feedback controllers regulating in parallel a large number of single stem cells, and leading to their differentiation to desired fates, e.g. beta cells, with potential for therapeutic applications. Finally, we will engineer into living cells dynamic molecular control systems. Such controllers can be used to monitor physiological variables and secrete biological effectors in a feedback fashion for the treatment of diseases like Type 1 diabetes.
Max ERC Funding
2 499 887 €
Duration
Start date: 2017-08-01, End date: 2022-07-31
Project acronym DIVLAW
Project How God Became a Lawgiver: The Place of the Torah in Ancient Near Eastern Legal History
Researcher (PI) Konrad Schmid
Host Institution (HI) UNIVERSITAT ZURICH
Country Switzerland
Call Details Advanced Grant (AdG), SH6, ERC-2018-ADG
Summary The Torah’s notion of divine law fundamentally transforms the nature of law found in its ancient Near Eastern context. Typically kings—not gods—took on the role of the promulgation of laws. The Torah’s conception of God as lawgiver emerged gradually through historical processes, rather than constituting the bedrock of the Bible’s literary and legal history. And, while scholars have long recognized the uniqueness of the Torah’s conception, its early historical development has received little attention. Only tangential analysis exists on the forces surrounding the genesis of the Torah’s notion of divine laws within ancient Near Eastern legal history or its impact on religion and politics in the early historical contexts of ancient Israel and Judah.
This project therefore aims: 1) to explicate the anchoring of law in the religious ether of the Ancient Near East; 2) to elucidate for the first time the intellectual processes in ancient Israel and Judah that led to the notion of divine laws and God as lawgiver, drawing comparisons with other legal understandings and practices from the ancient Near East; 3) to assess the socio-political and religious impact of this notion with ancient Judaism through the Hellenistic Period; and 4) to contextualize this development in the ancient world in comparison to parallel developments in Greek polities.
The project’s innovative potential lies in: 1) the evaluation of the divine laws as a historical phenomenon; 2) the neglected effort to understand their intellectual genesis and early development in a reciprocal relation to their socio-political context; 3) the cross-cultural analysis of ancient Israel and Judah and its neighbouring cultures in this regard; and 4) the application of a longue durée and realgeschichtliche perspective to largely literary and philological disciplines. These investigations offer a new paradigm for elucidating the webs connecting divinity, law, and socio-political developments in the first millennium BCE.
Summary
The Torah’s notion of divine law fundamentally transforms the nature of law found in its ancient Near Eastern context. Typically kings—not gods—took on the role of the promulgation of laws. The Torah’s conception of God as lawgiver emerged gradually through historical processes, rather than constituting the bedrock of the Bible’s literary and legal history. And, while scholars have long recognized the uniqueness of the Torah’s conception, its early historical development has received little attention. Only tangential analysis exists on the forces surrounding the genesis of the Torah’s notion of divine laws within ancient Near Eastern legal history or its impact on religion and politics in the early historical contexts of ancient Israel and Judah.
This project therefore aims: 1) to explicate the anchoring of law in the religious ether of the Ancient Near East; 2) to elucidate for the first time the intellectual processes in ancient Israel and Judah that led to the notion of divine laws and God as lawgiver, drawing comparisons with other legal understandings and practices from the ancient Near East; 3) to assess the socio-political and religious impact of this notion with ancient Judaism through the Hellenistic Period; and 4) to contextualize this development in the ancient world in comparison to parallel developments in Greek polities.
The project’s innovative potential lies in: 1) the evaluation of the divine laws as a historical phenomenon; 2) the neglected effort to understand their intellectual genesis and early development in a reciprocal relation to their socio-political context; 3) the cross-cultural analysis of ancient Israel and Judah and its neighbouring cultures in this regard; and 4) the application of a longue durée and realgeschichtliche perspective to largely literary and philological disciplines. These investigations offer a new paradigm for elucidating the webs connecting divinity, law, and socio-political developments in the first millennium BCE.
Max ERC Funding
2 500 000 €
Duration
Start date: 2020-01-01, End date: 2024-12-31
Project acronym DrosoSpiro
Project The Drosophila-Spiroplasma interaction as a model to dissect the molecular mechanisms underlying insect endosymbiosis
Researcher (PI) Bruno Lemaitre
Host Institution (HI) ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE
Country Switzerland
Call Details Advanced Grant (AdG), LS8, ERC-2013-ADG
Summary Virtually every species of insect harbors facultative bacterial endosymbionts that are transmitted from females to their offspring, often in the egg cytoplasm. These symbionts play crucial roles in the biology of their hosts. Many manipulate host reproduction in order to spread within host populations. Others increase the fitness of their hosts under certain conditions. For example, increasing tolerance to heat or protecting their hosts against natural enemies. Over the past decade, our understanding of insect endosymbionts has shifted from seeing them as fascinating oddities to being ubiquitous and central to the biology of their hosts, including many of high economic and medical importance. However, in spite of growing interest in endosymbionts, very little is known about the molecular mechanisms underlying most endosymbiont-insect interactions. For instance, the basis of the main phenotypes caused by endosymbionts, including diverse reproductive manipulations or symbiont-protective immunity, remains largely enigmatic. The goal of the present application is to fill this gap by dissecting the interaction between Drosophila and its native endosymbiont Spiroplasma poulsonii. This project will use a broad range of approaches ranging from molecular genetic to genomics to dissect the molecular mechanisms underlying key features of the symbiosis, including vertical transmission, male killing, regulation of symbiont growth, and symbiont-mediated protection against parasitic wasps. We believe that the fundamental knowledge generated on the Drosophila-Spiroplasma interaction will serve as a paradigm for other endosymbiont-insect interactions that are less amenable to genetic studies.
Summary
Virtually every species of insect harbors facultative bacterial endosymbionts that are transmitted from females to their offspring, often in the egg cytoplasm. These symbionts play crucial roles in the biology of their hosts. Many manipulate host reproduction in order to spread within host populations. Others increase the fitness of their hosts under certain conditions. For example, increasing tolerance to heat or protecting their hosts against natural enemies. Over the past decade, our understanding of insect endosymbionts has shifted from seeing them as fascinating oddities to being ubiquitous and central to the biology of their hosts, including many of high economic and medical importance. However, in spite of growing interest in endosymbionts, very little is known about the molecular mechanisms underlying most endosymbiont-insect interactions. For instance, the basis of the main phenotypes caused by endosymbionts, including diverse reproductive manipulations or symbiont-protective immunity, remains largely enigmatic. The goal of the present application is to fill this gap by dissecting the interaction between Drosophila and its native endosymbiont Spiroplasma poulsonii. This project will use a broad range of approaches ranging from molecular genetic to genomics to dissect the molecular mechanisms underlying key features of the symbiosis, including vertical transmission, male killing, regulation of symbiont growth, and symbiont-mediated protection against parasitic wasps. We believe that the fundamental knowledge generated on the Drosophila-Spiroplasma interaction will serve as a paradigm for other endosymbiont-insect interactions that are less amenable to genetic studies.
Max ERC Funding
1 963 926 €
Duration
Start date: 2014-05-01, End date: 2019-04-30
