Project acronym aCROBAT
Project Circadian Regulation Of Brown Adipose Thermogenesis
Researcher (PI) Zachary Philip Gerhart-Hines
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Starting Grant (StG), LS4, ERC-2014-STG
Summary Obesity and diabetes have reached pandemic proportions and new therapeutic strategies are critically needed. Brown adipose tissue (BAT), a major source of heat production, possesses significant energy-dissipating capacity and therefore represents a promising target to use in combating these diseases. Recently, I discovered a novel link between circadian rhythm and thermogenic stress in the control of the conserved, calorie-burning functions of BAT. Circadian and thermogenic signaling to BAT incorporates blood-borne hormonal and nutrient cues with direct neuronal input. Yet how these responses coordinately shape BAT energy-expending potential through the regulation of cell surface receptors, metabolic enzymes, and transcriptional effectors is still not understood. My primary goal is to investigate this previously unappreciated network of crosstalk that allows mammals to effectively orchestrate daily rhythms in BAT metabolism, while maintaining their ability to adapt to abrupt changes in energy demand. My group will address this question using gain and loss-of-function in vitro and in vivo studies, newly-generated mouse models, customized physiological phenotyping, and cutting-edge advances in next generation RNA sequencing and mass spectrometry. Preliminary, small-scale validations of our methodologies have already yielded a number of novel candidates that may drive key facets of BAT metabolism. Additionally, we will extend our circadian and thermogenic studies into humans to evaluate the translational potential. Our results will advance the fundamental understanding of how daily oscillations in bioenergetic networks establish a framework for the anticipation of and adaptation to environmental challenges. Importantly, we expect that these mechanistic insights will reveal pharmacological targets through which we can unlock evolutionary constraints and harness the energy-expending potential of BAT for the prevention and treatment of obesity and diabetes.
Summary
Obesity and diabetes have reached pandemic proportions and new therapeutic strategies are critically needed. Brown adipose tissue (BAT), a major source of heat production, possesses significant energy-dissipating capacity and therefore represents a promising target to use in combating these diseases. Recently, I discovered a novel link between circadian rhythm and thermogenic stress in the control of the conserved, calorie-burning functions of BAT. Circadian and thermogenic signaling to BAT incorporates blood-borne hormonal and nutrient cues with direct neuronal input. Yet how these responses coordinately shape BAT energy-expending potential through the regulation of cell surface receptors, metabolic enzymes, and transcriptional effectors is still not understood. My primary goal is to investigate this previously unappreciated network of crosstalk that allows mammals to effectively orchestrate daily rhythms in BAT metabolism, while maintaining their ability to adapt to abrupt changes in energy demand. My group will address this question using gain and loss-of-function in vitro and in vivo studies, newly-generated mouse models, customized physiological phenotyping, and cutting-edge advances in next generation RNA sequencing and mass spectrometry. Preliminary, small-scale validations of our methodologies have already yielded a number of novel candidates that may drive key facets of BAT metabolism. Additionally, we will extend our circadian and thermogenic studies into humans to evaluate the translational potential. Our results will advance the fundamental understanding of how daily oscillations in bioenergetic networks establish a framework for the anticipation of and adaptation to environmental challenges. Importantly, we expect that these mechanistic insights will reveal pharmacological targets through which we can unlock evolutionary constraints and harness the energy-expending potential of BAT for the prevention and treatment of obesity and diabetes.
Max ERC Funding
1 497 008 €
Duration
Start date: 2015-05-01, End date: 2020-04-30
Project acronym AlgoFinance
Project Algorithmic Finance: Inquiring into the Reshaping of Financial Markets
Researcher (PI) Christian BORCH
Host Institution (HI) COPENHAGEN BUSINESS SCHOOL
Call Details Consolidator Grant (CoG), SH3, ERC-2016-COG
Summary Present-day financial markets are turning algorithmic, as market orders are increasingly being executed by fully automated computer algorithms, without any direct human intervention. Although algorithmic finance seems to fundamentally reshape the central dynamics in financial markets, and even though it prompts core sociological questions, it has not yet received any systematic attention. In a pioneering contribution to economic sociology and social studies of finance, ALGOFINANCE aims to understand how and with what consequences the turn to algorithms is changing financial markets. The overall concept and central contributions of ALGOFINANCE are the following: (1) on an intra-firm level, the project examines how the shift to algorithmic finance reshapes the ways in which trading firms operate, and does so by systematically and empirically investigating the reconfiguration of organizational structures and employee subjectivity; (2) on an inter-algorithmic level, it offers a ground-breaking methodology (agent-based modelling informed by qualitative data) to grasp how trading algorithms interact with one another in a fully digital space; and (3) on the level of market sociality, it proposes a novel theorization of how intra-firm and inter-algorithmic dynamics can be conceived of as introducing a particular form of sociality that is characteristic to algorithmic finance: a form of sociality-as-association heuristically analyzed as imitation. None of these three levels have received systematic attention in the state-of-the-art literature. Addressing them will significantly advance the understanding of present-day algorithmic finance in economic sociology. By contributing novel empirical, methodological, and theoretical understandings of the functioning and consequences of algorithms, ALGOFINANCE will pave the way for other research into digital sociology and the broader algorithmization of society.
Summary
Present-day financial markets are turning algorithmic, as market orders are increasingly being executed by fully automated computer algorithms, without any direct human intervention. Although algorithmic finance seems to fundamentally reshape the central dynamics in financial markets, and even though it prompts core sociological questions, it has not yet received any systematic attention. In a pioneering contribution to economic sociology and social studies of finance, ALGOFINANCE aims to understand how and with what consequences the turn to algorithms is changing financial markets. The overall concept and central contributions of ALGOFINANCE are the following: (1) on an intra-firm level, the project examines how the shift to algorithmic finance reshapes the ways in which trading firms operate, and does so by systematically and empirically investigating the reconfiguration of organizational structures and employee subjectivity; (2) on an inter-algorithmic level, it offers a ground-breaking methodology (agent-based modelling informed by qualitative data) to grasp how trading algorithms interact with one another in a fully digital space; and (3) on the level of market sociality, it proposes a novel theorization of how intra-firm and inter-algorithmic dynamics can be conceived of as introducing a particular form of sociality that is characteristic to algorithmic finance: a form of sociality-as-association heuristically analyzed as imitation. None of these three levels have received systematic attention in the state-of-the-art literature. Addressing them will significantly advance the understanding of present-day algorithmic finance in economic sociology. By contributing novel empirical, methodological, and theoretical understandings of the functioning and consequences of algorithms, ALGOFINANCE will pave the way for other research into digital sociology and the broader algorithmization of society.
Max ERC Funding
1 590 036 €
Duration
Start date: 2017-05-01, End date: 2021-04-30
Project acronym B2C
Project Beasts to Craft: BioCodicology as a new approach to the study of parchment manuscripts
Researcher (PI) Matthew COLLINS
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Advanced Grant (AdG), SH6, ERC-2017-ADG
Summary The intention of Beasts to Craft (B2C) is to document the biological and craft records in parchment in order to reveal the entangled histories of animal improvement and parchment production in Europe from 500-1900 AD.
B2C will lay the foundations for a new approach to the the study of parchment manuscripts —biocodicology— which draws evidence from the overlooked first stages in production, the raising of livestock and the preparation of the skins.
1. Parchment is an extraordinary but overlooked high resolution zooarchaeological record and a molecular archive. Livestock genetics is revealing breed diversity and markers of character traits such as fleece quality. B2C will exploit this new-found knowledge, using progressively older dated archival (sheep) parchments to study the history of improvement 1300 - 1900. Visual examination of the skins will search for direct evidence of disease and fleece quality.
2. Craft skills can be read from parchment and, when combined with chemical data and comparison with modern analogues, will produce the first European wide record of the craft from 500-1900. The size and scope of this the parchment archive means it is one of the largest and most highly resolved records of a specialist medieval craft. We will explore how these skills develop and when and where regional patterns appear and decline.
These two remarkable records requires a large interdisciplinary team. However biocodicology draws from and informs upon a wide and diverse spectrum of existing scholarship in conservation, the arts and sciences. A third strand of the project will (i) furnish manuscript scholars with some of the information available to the scribe at time of production (ii) inform and shape attitudes to parchment conservation (iii) provide high resolution biological data on animal management, movement and health and (iv) explore methods to link datasets and promote data reuse.
Summary
The intention of Beasts to Craft (B2C) is to document the biological and craft records in parchment in order to reveal the entangled histories of animal improvement and parchment production in Europe from 500-1900 AD.
B2C will lay the foundations for a new approach to the the study of parchment manuscripts —biocodicology— which draws evidence from the overlooked first stages in production, the raising of livestock and the preparation of the skins.
1. Parchment is an extraordinary but overlooked high resolution zooarchaeological record and a molecular archive. Livestock genetics is revealing breed diversity and markers of character traits such as fleece quality. B2C will exploit this new-found knowledge, using progressively older dated archival (sheep) parchments to study the history of improvement 1300 - 1900. Visual examination of the skins will search for direct evidence of disease and fleece quality.
2. Craft skills can be read from parchment and, when combined with chemical data and comparison with modern analogues, will produce the first European wide record of the craft from 500-1900. The size and scope of this the parchment archive means it is one of the largest and most highly resolved records of a specialist medieval craft. We will explore how these skills develop and when and where regional patterns appear and decline.
These two remarkable records requires a large interdisciplinary team. However biocodicology draws from and informs upon a wide and diverse spectrum of existing scholarship in conservation, the arts and sciences. A third strand of the project will (i) furnish manuscript scholars with some of the information available to the scribe at time of production (ii) inform and shape attitudes to parchment conservation (iii) provide high resolution biological data on animal management, movement and health and (iv) explore methods to link datasets and promote data reuse.
Max ERC Funding
2 499 462 €
Duration
Start date: 2018-12-01, End date: 2023-11-30
Project acronym BYPASSWITHOUTSURGERY
Project Reaching the effects of gastric bypass on diabetes and obesity without surgery
Researcher (PI) Jens Juul Holst
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Advanced Grant (AdG), LS4, ERC-2015-AdG
Summary Gastric bypass surgery results in massive weight loss and diabetes remission. The effect is superior to intensive medical treatment, showing that there are mechanisms within the body that can cure diabetes and obesity. Revealing the nature of these mechanisms could lead to new, cost-efficient, similarly effective, non-invasive treatments of these conditions. The hypothesis is that hyper-secretion of a number of gut hormones mediates the effect of surgery, as indicated by a series of our recent studies, demonstrating that hypersecretion of GLP-1, a hormone discovered in my laboratory and basis for the antidiabetic medication of millions of patients, is essential for the improved insulin secretion and glucose tolerance. But what are the mechanisms behind the up to 30-fold elevations in secretion of these hormones following surgery? Constantly with a translational scope, all elements involved in these responses will be addressed in this project, from detailed analysis of food items responsible for hormone secretion, to identification of the responsible regions of the gut, and to the molecular mechanisms leading to hypersecretion. Novel approaches for studies of human gut hormone secreting cells, including specific expression analysis, are combined with our advanced and unique isolated perfused gut preparations, the only tool that can provide physiologically relevant results with a translational potential regarding regulation of hormone secretion in the gut. This will lead to further groundbreaking experimental attempts to mimic and engage the identified mechanisms, creating similar hypersecretion and obtaining similar improvements as the operations in patients with obesity and diabetes. Based on our profound knowledge of gut hormone biology accumulated through decades of intensive and successful research and our successful elucidation of the antidiabetic actions of gastric bypass surgery, we are in a unique position to reach this ambitious goal.
Summary
Gastric bypass surgery results in massive weight loss and diabetes remission. The effect is superior to intensive medical treatment, showing that there are mechanisms within the body that can cure diabetes and obesity. Revealing the nature of these mechanisms could lead to new, cost-efficient, similarly effective, non-invasive treatments of these conditions. The hypothesis is that hyper-secretion of a number of gut hormones mediates the effect of surgery, as indicated by a series of our recent studies, demonstrating that hypersecretion of GLP-1, a hormone discovered in my laboratory and basis for the antidiabetic medication of millions of patients, is essential for the improved insulin secretion and glucose tolerance. But what are the mechanisms behind the up to 30-fold elevations in secretion of these hormones following surgery? Constantly with a translational scope, all elements involved in these responses will be addressed in this project, from detailed analysis of food items responsible for hormone secretion, to identification of the responsible regions of the gut, and to the molecular mechanisms leading to hypersecretion. Novel approaches for studies of human gut hormone secreting cells, including specific expression analysis, are combined with our advanced and unique isolated perfused gut preparations, the only tool that can provide physiologically relevant results with a translational potential regarding regulation of hormone secretion in the gut. This will lead to further groundbreaking experimental attempts to mimic and engage the identified mechanisms, creating similar hypersecretion and obtaining similar improvements as the operations in patients with obesity and diabetes. Based on our profound knowledge of gut hormone biology accumulated through decades of intensive and successful research and our successful elucidation of the antidiabetic actions of gastric bypass surgery, we are in a unique position to reach this ambitious goal.
Max ERC Funding
2 500 000 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
Project acronym C-MORPH
Project Noninvasive cell specific morphometry in neuroinflammation and degeneration
Researcher (PI) Henrik LUNDELL
Host Institution (HI) REGION HOVEDSTADEN
Call Details Starting Grant (StG), LS7, ERC-2018-STG
Summary Brain structure determines function. Disentangling regional microstructural properties and understanding how these properties constitute brain function is a central goal of neuroimaging of the human brain and a key prerequisite for a mechanistic understanding of brain diseases and their treatment. Using magnetic resonance (MR) imaging, previous research has established links between regional brain microstructure and inter-individual variation in brain function, but this line of research has been limited by the non-specificity of MR-derived markers. This hampers the application of MR imaging as a tool to identify specific fingerprints of the underlying disease process.
Exploiting state-of-the-art ultra-high field MR imaging techniques, I have recently developed two independent spectroscopic MR methods that have the potential to tackle this challenge: Powder averaged diffusion weighted spectroscopy (PADWS) can provide an unbiased marker for cell specific structural degeneration, and Spectrally tuned gradient trajectories (STGT) can isolate cell shape and size. In this project, I will harness these innovations for MR-based precision medicine. I will advance PADWS and STGT methodology on state-of-the-art MR hardware and harvest the synergy of these methods to realize Cell-specific in-vivo MORPHOMETRY (C-MORPH) of the intact human brain. I will establish novel MR read-outs and analyses to derive cell-type specific tissue properties in the healthy and diseased brain and validate them with the help of a strong translational experimental framework, including histological validation. Once validated, the experimental methods and analyses will be simplified and adapted to provide clinically applicable tools. This will push the frontiers of MR-based personalized medicine, guiding therapeutic decisions by providing sensitive probes of cell-specific microstructural changes caused by inflammation, neurodegeneration or treatment response.
Summary
Brain structure determines function. Disentangling regional microstructural properties and understanding how these properties constitute brain function is a central goal of neuroimaging of the human brain and a key prerequisite for a mechanistic understanding of brain diseases and their treatment. Using magnetic resonance (MR) imaging, previous research has established links between regional brain microstructure and inter-individual variation in brain function, but this line of research has been limited by the non-specificity of MR-derived markers. This hampers the application of MR imaging as a tool to identify specific fingerprints of the underlying disease process.
Exploiting state-of-the-art ultra-high field MR imaging techniques, I have recently developed two independent spectroscopic MR methods that have the potential to tackle this challenge: Powder averaged diffusion weighted spectroscopy (PADWS) can provide an unbiased marker for cell specific structural degeneration, and Spectrally tuned gradient trajectories (STGT) can isolate cell shape and size. In this project, I will harness these innovations for MR-based precision medicine. I will advance PADWS and STGT methodology on state-of-the-art MR hardware and harvest the synergy of these methods to realize Cell-specific in-vivo MORPHOMETRY (C-MORPH) of the intact human brain. I will establish novel MR read-outs and analyses to derive cell-type specific tissue properties in the healthy and diseased brain and validate them with the help of a strong translational experimental framework, including histological validation. Once validated, the experimental methods and analyses will be simplified and adapted to provide clinically applicable tools. This will push the frontiers of MR-based personalized medicine, guiding therapeutic decisions by providing sensitive probes of cell-specific microstructural changes caused by inflammation, neurodegeneration or treatment response.
Max ERC Funding
1 498 811 €
Duration
Start date: 2018-12-01, End date: 2023-11-30
Project acronym CFS modelling
Project Chromosomal Common Fragile Sites: Unravelling their biological functions and the basis of their instability
Researcher (PI) Andres Joaquin Lopez-Contreras
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Starting Grant (StG), LS4, ERC-2015-STG
Summary Cancer and other diseases are driven by genomic alterations initiated by DNA breaks. Within our genomes, some regions are particularly prone to breakage, and these are known as common fragile sites (CFSs). CFSs are present in every person and are frequently sites of oncogenic chromosomal rearrangements. Intriguingly, despite their fragility, many CFSs are well conserved through evolution, suggesting that these regions have important physiological functions that remain elusive. My previous background in genome editing, proteomics and replication-born DNA damage has given me the tools to propose an ambitious and comprehensive plan that tackles fundamental questions on the biology of CFSs. First, we will perform a systematic analysis of the function of CFSs. Most of the CFSs contain very large genes, which has made technically difficult to dissect whether the CFS role is due to the locus itself or to the encoded gene product. However, the emergence of the CRISPR/Cas9 technology now enables the study of CFSs on a more systematic basis. We will pioneer the engineering of mammalian models harbouring large deletions at CFS loci to investigate their physiological functions at the cellular and organism levels. For those CFSs that contain genes, the cDNAs will be re-introduced at a distal locus. Using this strategy, we will be able to achieve the first comprehensive characterization of CFS roles. Second, we will develop novel targeted approaches to interrogate the chromatin-bound proteome of CFSs and its dynamics during DNA replication. Finally, and given that CFS fragility is influenced both by cell cycle checkpoints and dNTP availability, we will use mouse models to study the impact of ATR/CHK1 pathway and dNTP levels on CFS instability and cancer. Taken together, I propose an ambitious, yet feasible, project to functionally annotate and characterise these poorly understood regions of the human genome, with important potential implications for improving human health.
Summary
Cancer and other diseases are driven by genomic alterations initiated by DNA breaks. Within our genomes, some regions are particularly prone to breakage, and these are known as common fragile sites (CFSs). CFSs are present in every person and are frequently sites of oncogenic chromosomal rearrangements. Intriguingly, despite their fragility, many CFSs are well conserved through evolution, suggesting that these regions have important physiological functions that remain elusive. My previous background in genome editing, proteomics and replication-born DNA damage has given me the tools to propose an ambitious and comprehensive plan that tackles fundamental questions on the biology of CFSs. First, we will perform a systematic analysis of the function of CFSs. Most of the CFSs contain very large genes, which has made technically difficult to dissect whether the CFS role is due to the locus itself or to the encoded gene product. However, the emergence of the CRISPR/Cas9 technology now enables the study of CFSs on a more systematic basis. We will pioneer the engineering of mammalian models harbouring large deletions at CFS loci to investigate their physiological functions at the cellular and organism levels. For those CFSs that contain genes, the cDNAs will be re-introduced at a distal locus. Using this strategy, we will be able to achieve the first comprehensive characterization of CFS roles. Second, we will develop novel targeted approaches to interrogate the chromatin-bound proteome of CFSs and its dynamics during DNA replication. Finally, and given that CFS fragility is influenced both by cell cycle checkpoints and dNTP availability, we will use mouse models to study the impact of ATR/CHK1 pathway and dNTP levels on CFS instability and cancer. Taken together, I propose an ambitious, yet feasible, project to functionally annotate and characterise these poorly understood regions of the human genome, with important potential implications for improving human health.
Max ERC Funding
1 499 711 €
Duration
Start date: 2016-05-01, End date: 2021-04-30
Project acronym CHILDGROWTH2CANCER
Project Childhood body size, growth and pubertal timing and the risk of cancer in adulthood
Researcher (PI) Jennifer Lyn Baker
Host Institution (HI) REGION HOVEDSTADEN
Call Details Starting Grant (StG), LS7, ERC-2011-StG_20101109
Summary The goal of the proposed research is to examine how the independent and combined effects of childhood adiposity (assessed by body mass index [BMI]; kg/m2) height, change in BMI and height, and pubertal timing from the ages of 7 to 13 years are associated with the risk of cancer incidence in adulthood. Greater body size (adipose tissue and different types of lean tissue) reflecting past or ongoing growth may increase the risk of cancer in individuals as greater numbers of proliferating cells increase the risk that mutations leading to the subsequent development of cancer occur. As childhood is a period of growth, it is plausible that it is of particular relevance for the early establishment of the risk of cancer.
Data from the Copenhagen School Health Records Register, which is based on a population of schoolchildren born between 1930-1983 and contains computerised weight and height measurements on >350.000 boys and girls in the capital city of Denmark, as well as data from other cohorts will be used. Survival analysis techniques and the newly developed Dynamic Path Analysis model will be used to examine how body size (BMI and height) at each age from 7 to 13 years as well as change in body size during this period is associated with the risk of multiple forms of cancer in adulthood with a simultaneous exploration of the effects of birth weight and pubertal timing. Additionally, potential effects of childhood and adult health and social circumstances will be investigated in sub-cohorts with this information available.
Results from this research will demonstrate if childhood is a critical period for the establishment of the risk for cancer in adulthood and will lead into mechanistic explorations of the associations at the biological level, investigations into associations between childhood body size and mortality and contribute to developing improved definitions of childhood overweight and obesity that are based upon long-term health outcomes.
Summary
The goal of the proposed research is to examine how the independent and combined effects of childhood adiposity (assessed by body mass index [BMI]; kg/m2) height, change in BMI and height, and pubertal timing from the ages of 7 to 13 years are associated with the risk of cancer incidence in adulthood. Greater body size (adipose tissue and different types of lean tissue) reflecting past or ongoing growth may increase the risk of cancer in individuals as greater numbers of proliferating cells increase the risk that mutations leading to the subsequent development of cancer occur. As childhood is a period of growth, it is plausible that it is of particular relevance for the early establishment of the risk of cancer.
Data from the Copenhagen School Health Records Register, which is based on a population of schoolchildren born between 1930-1983 and contains computerised weight and height measurements on >350.000 boys and girls in the capital city of Denmark, as well as data from other cohorts will be used. Survival analysis techniques and the newly developed Dynamic Path Analysis model will be used to examine how body size (BMI and height) at each age from 7 to 13 years as well as change in body size during this period is associated with the risk of multiple forms of cancer in adulthood with a simultaneous exploration of the effects of birth weight and pubertal timing. Additionally, potential effects of childhood and adult health and social circumstances will be investigated in sub-cohorts with this information available.
Results from this research will demonstrate if childhood is a critical period for the establishment of the risk for cancer in adulthood and will lead into mechanistic explorations of the associations at the biological level, investigations into associations between childhood body size and mortality and contribute to developing improved definitions of childhood overweight and obesity that are based upon long-term health outcomes.
Max ERC Funding
1 199 998 €
Duration
Start date: 2012-02-01, End date: 2017-01-31
Project acronym CHILIC
Project Child health intervention interactions in low-income countries
Researcher (PI) Christine Benn
Host Institution (HI) STATENS SERUM INSTITUT
Call Details Starting Grant (StG), LS7, ERC-2009-StG
Summary Vitamin A supplementation (VAS) and vaccines are the most powerful tools to reduce child mortality in low-income countries. However, we may not use these interventions optimally because we disregard that the interventions may have immunomodulatory effects which differ for boys and girls and which may interact with the effects of other interventions. I have proposed the hypothesis that VAS and vaccines interact. This hypothesis is supported by randomised and observational studies showing that the combination of VAS and DTP may be harmful. I have furthermore proposed that VAS has sex-differential effects. VAS seems beneficial for boys but may not carry any benefits for girls. These findings challenge the current understanding that VAS and vaccines have only targeted effects and can be given together without considering interactions. This is of outmost importance for policy makers. The global trend is to combine health interventions for logistic reasons. My research suggests that this may not always be a good idea. Furthermore, the concept of sex-differential response to our common health interventions opens up for a completely new understanding of the immunology of the two sexes and may imply that we need to treat the two sexes differently in order to treat them optimally possibly also in high-income countries. In the present proposal I outline a series of inter-disciplinary epidemiological and immunological studies, which will serve to determine the overall and sex-differential effects of VAS and vaccines, the mechanisms behind these effects, and the basis for the immunological difference between boys and girls. If my hypotheses are true we can use the existing tools in a more optimal way to reduce child mortality without increasing costs. Thus, the results could lead to shifts in policy as well as paradigms.
Summary
Vitamin A supplementation (VAS) and vaccines are the most powerful tools to reduce child mortality in low-income countries. However, we may not use these interventions optimally because we disregard that the interventions may have immunomodulatory effects which differ for boys and girls and which may interact with the effects of other interventions. I have proposed the hypothesis that VAS and vaccines interact. This hypothesis is supported by randomised and observational studies showing that the combination of VAS and DTP may be harmful. I have furthermore proposed that VAS has sex-differential effects. VAS seems beneficial for boys but may not carry any benefits for girls. These findings challenge the current understanding that VAS and vaccines have only targeted effects and can be given together without considering interactions. This is of outmost importance for policy makers. The global trend is to combine health interventions for logistic reasons. My research suggests that this may not always be a good idea. Furthermore, the concept of sex-differential response to our common health interventions opens up for a completely new understanding of the immunology of the two sexes and may imply that we need to treat the two sexes differently in order to treat them optimally possibly also in high-income countries. In the present proposal I outline a series of inter-disciplinary epidemiological and immunological studies, which will serve to determine the overall and sex-differential effects of VAS and vaccines, the mechanisms behind these effects, and the basis for the immunological difference between boys and girls. If my hypotheses are true we can use the existing tools in a more optimal way to reduce child mortality without increasing costs. Thus, the results could lead to shifts in policy as well as paradigms.
Max ERC Funding
1 686 043 €
Duration
Start date: 2010-01-01, End date: 2014-12-31
Project acronym CHIPS
Project Effects of Prenatal Exposure to Acrylamide on Health: Prospective Biomarker-Based Studies
Researcher (PI) Marie Pedersen
Host Institution (HI) KOBENHAVNS UNIVERSITET
Call Details Starting Grant (StG), LS7, ERC-2017-STG
Summary Background: Acrylamide is a chemical formed in many commonly consumed foods and beverages. It is neurotoxic, crosses the placenta and has been associated with restriction of fetal growth in humans. In animals, acrylamide causes heritable mutations, tumors, developmental toxicity, reduced fertility and impaired growth. Therefore, the discovery of acrylamide in food in 2002 raised concern about human health effects worldwide. Still, epidemiological studies are limited and effects on health of prenatal exposure have never been evaluated.
Research gaps: Epidemiological studies have mostly addressed exposure during adulthood, focused on cancer risk in adults, and relied on questionnaires entailing a high degree of exposure misclassification. Biomarker studies on prenatal exposure to acrylamide from diet are critically needed to improve exposure assessment and to determine whether acrylamide leads to major diseases later in life.
Own results: I have first authored a prospective European study showing that prenatal exposure to acrylamide, estimated by measuring hemoglobin adducts in cord blood, was associated with fetal growth restriction, for the first time.
Objectives: To determine the effects of prenatal exposure to acrylamide alone and in combination with other potentially toxic adduct-forming exposures on the health of children and young adults.
Methods: Both well-established and innovative biomarker methods will be used for characterization of prenatal exposure to acrylamide and related toxicants in blood from pregnant women and their offspring in prospective cohort studies with long-term follow-up. Risk of neurological disorders, impaired cognition, disturbed reproductive function and metabolic outcomes such as obesity and diabetes will be evaluated.
Perspectives: CHIPS project will provide a better understanding of the impact of prenatal exposure to acrylamide from diet on human health urgently needed for targeted strategies for the protection of the health.
Summary
Background: Acrylamide is a chemical formed in many commonly consumed foods and beverages. It is neurotoxic, crosses the placenta and has been associated with restriction of fetal growth in humans. In animals, acrylamide causes heritable mutations, tumors, developmental toxicity, reduced fertility and impaired growth. Therefore, the discovery of acrylamide in food in 2002 raised concern about human health effects worldwide. Still, epidemiological studies are limited and effects on health of prenatal exposure have never been evaluated.
Research gaps: Epidemiological studies have mostly addressed exposure during adulthood, focused on cancer risk in adults, and relied on questionnaires entailing a high degree of exposure misclassification. Biomarker studies on prenatal exposure to acrylamide from diet are critically needed to improve exposure assessment and to determine whether acrylamide leads to major diseases later in life.
Own results: I have first authored a prospective European study showing that prenatal exposure to acrylamide, estimated by measuring hemoglobin adducts in cord blood, was associated with fetal growth restriction, for the first time.
Objectives: To determine the effects of prenatal exposure to acrylamide alone and in combination with other potentially toxic adduct-forming exposures on the health of children and young adults.
Methods: Both well-established and innovative biomarker methods will be used for characterization of prenatal exposure to acrylamide and related toxicants in blood from pregnant women and their offspring in prospective cohort studies with long-term follow-up. Risk of neurological disorders, impaired cognition, disturbed reproductive function and metabolic outcomes such as obesity and diabetes will be evaluated.
Perspectives: CHIPS project will provide a better understanding of the impact of prenatal exposure to acrylamide from diet on human health urgently needed for targeted strategies for the protection of the health.
Max ERC Funding
1 499 531 €
Duration
Start date: 2018-07-01, End date: 2023-06-30
Project acronym CLIC
Project Classical Influences and Irish Culture
Researcher (PI) Isabelle Torrance
Host Institution (HI) AARHUS UNIVERSITET
Call Details Consolidator Grant (CoG), SH5, ERC-2018-COG
Summary The hypothesis of this project is that Ireland has a unique and hitherto underexplored history of cultural engagement with models from ancient Greece and Rome. Unlike Britain and mainland Europe, Ireland was never part of the Roman Empire. Yet the island has an extraordinarily vibrant tradition of classical learning that dates back to its earliest recorded literature, and is unparalleled in other northern European countries. Research for this project will address why this is the case, by examining sources through nine significant diachronic themes identified by the PI: language; land; travel and exile; Troy; satire; Neoplatonism; female voices; material culture; and global influence. This multi-thematic approach will enable analysis of what is remarkable about classical reception in Ireland. It will also provide a heuristic framework that generates dialogue between normally disparate fields, such as classical reception studies, Irish and British history, English-language literature, Irish-language literature, medieval studies, postcolonial studies, philosophy, material culture, women's studies, and global studies. The project will engage with contemporary preoccupations surrounding the politics and history of the divided island of Ireland, such as the current decade of centenary commemorations for the foundation of an independent Irish state (1912-1922, 2012-2022), and the on-going violence and political divisions in Northern Ireland. These issues will serve as a springboard for opening new avenues of investigation that look far beyond the past 100 years, but are linked to them. The project will thus shed new light on the role of classical culture in shaping literary, social, and political discourse across the island of Ireland, and throughout its history.
Summary
The hypothesis of this project is that Ireland has a unique and hitherto underexplored history of cultural engagement with models from ancient Greece and Rome. Unlike Britain and mainland Europe, Ireland was never part of the Roman Empire. Yet the island has an extraordinarily vibrant tradition of classical learning that dates back to its earliest recorded literature, and is unparalleled in other northern European countries. Research for this project will address why this is the case, by examining sources through nine significant diachronic themes identified by the PI: language; land; travel and exile; Troy; satire; Neoplatonism; female voices; material culture; and global influence. This multi-thematic approach will enable analysis of what is remarkable about classical reception in Ireland. It will also provide a heuristic framework that generates dialogue between normally disparate fields, such as classical reception studies, Irish and British history, English-language literature, Irish-language literature, medieval studies, postcolonial studies, philosophy, material culture, women's studies, and global studies. The project will engage with contemporary preoccupations surrounding the politics and history of the divided island of Ireland, such as the current decade of centenary commemorations for the foundation of an independent Irish state (1912-1922, 2012-2022), and the on-going violence and political divisions in Northern Ireland. These issues will serve as a springboard for opening new avenues of investigation that look far beyond the past 100 years, but are linked to them. The project will thus shed new light on the role of classical culture in shaping literary, social, and political discourse across the island of Ireland, and throughout its history.
Max ERC Funding
1 888 592 €
Duration
Start date: 2019-10-01, End date: 2024-09-30
