Project acronym ALK7
Project Metabolic control by the TGF-² superfamily receptor ALK7: A novel regulator of insulin secretion, fat accumulation and energy balance
Researcher (PI) Carlos Ibanez
Host Institution (HI) KAROLINSKA INSTITUTET
Country Sweden
Call Details Advanced Grant (AdG), LS4, ERC-2008-AdG
Summary The aim of this proposal is to understand a novel regulatory signaling network controlling insulin secretion, fat accumulation and energy balance centered around selected components of the TGF-² signaling system, including Activins A and B, GDF-3 and their receptors ALK7 and ALK4. Recent results from my laboratory indicate that these molecules are part of paracrine signaling networks that control important functions in pancreatic islets and adipose tissue through feedback inhibition and feed-forward regulation. These discoveries have open up a new research area with important implications for the understanding of metabolic networks and the treatment of human metabolic syndromes, such as diabetes and obesity.
To drive progress in this new research area beyond the state-of-the-art it is proposed to: i) Elucidate the molecular mechanisms by which Activins regulate Ca2+ influx and insulin secretion in pancreatic ²-cells; ii) Elucidate the molecular mechanisms underlying the effects of GDF-3 on adipocyte metabolism, turnover and fat accumulation; iii) Investigate the interplay between insulin levels and fat deposition in the development of insulin resistance using mutant mice lacking Activin B and GDF-3; iv) Investigate tissue-specific contributions of ALK7 and ALK4 signaling to metabolic control by generating and characterizing conditional mutant mice; v) Investigate the effects of specific and reversible inactivation of ALK7 and ALK4 on metabolic regulation using a novel chemical-genetic approach based on analog-sensitive alleles.
This is research of a high-gain/high-risk nature. It is posed to open unique opportunities for further exploration of complex metabolic networks. The development of drugs capable of enhancing insulin secretion, limiting fat accumulation and ameliorating diet-induced obesity by targeting components of the ALK7 signaling network will find a strong rationale in the results of the proposed work.
Summary
The aim of this proposal is to understand a novel regulatory signaling network controlling insulin secretion, fat accumulation and energy balance centered around selected components of the TGF-² signaling system, including Activins A and B, GDF-3 and their receptors ALK7 and ALK4. Recent results from my laboratory indicate that these molecules are part of paracrine signaling networks that control important functions in pancreatic islets and adipose tissue through feedback inhibition and feed-forward regulation. These discoveries have open up a new research area with important implications for the understanding of metabolic networks and the treatment of human metabolic syndromes, such as diabetes and obesity.
To drive progress in this new research area beyond the state-of-the-art it is proposed to: i) Elucidate the molecular mechanisms by which Activins regulate Ca2+ influx and insulin secretion in pancreatic ²-cells; ii) Elucidate the molecular mechanisms underlying the effects of GDF-3 on adipocyte metabolism, turnover and fat accumulation; iii) Investigate the interplay between insulin levels and fat deposition in the development of insulin resistance using mutant mice lacking Activin B and GDF-3; iv) Investigate tissue-specific contributions of ALK7 and ALK4 signaling to metabolic control by generating and characterizing conditional mutant mice; v) Investigate the effects of specific and reversible inactivation of ALK7 and ALK4 on metabolic regulation using a novel chemical-genetic approach based on analog-sensitive alleles.
This is research of a high-gain/high-risk nature. It is posed to open unique opportunities for further exploration of complex metabolic networks. The development of drugs capable of enhancing insulin secretion, limiting fat accumulation and ameliorating diet-induced obesity by targeting components of the ALK7 signaling network will find a strong rationale in the results of the proposed work.
Max ERC Funding
2 462 154 €
Duration
Start date: 2009-04-01, End date: 2014-03-31
Project acronym GLIOMA
Project Molecular Mechanisms of Glioma Genesis and Progression
Researcher (PI) Joan Seoane
Host Institution (HI) FUNDACIO PRIVADA INSTITUT D'INVESTIGACIO ONCOLOGICA DE VALL-HEBRON (VHIO)
Country Spain
Call Details Starting Grant (StG), LS6, ERC-2007-StG
Summary Glioma is the most common and aggressive tumour of the brain and its most malignant form, glioblastoma multiforme, is nowadays virtually not curable. Very little is known about glioma genesis and progression at the molecular level and not much progress has been achieved in the treatment of this disease during the last years. The understanding of the molecular mechanisms involved in the biology of glioma is essential for the development of successful and rational therapeutic strategies. Our project aims to: 1- Study the role of the TGF-beta, Shh, Notch, and Wnt signal transduction pathways in glioma. These pathways have been implicated in glioma but still not much is known about their specific mechanisms of action. 2- Study of a cell population within the tumour mass that has stem-cell-like characteristics, the glioma stem cells, and how the four mentioned pathways regulate their biology. 3- Study the role of a transcription factor, FoxG1, that has an important oncogenic role in some gliomas and that it is regulated by the four mentioned pathways interconnecting some of them. Our approach will be based on a tight collaboration with clinical researchers of our hospital and the study of patient-derived tumours. We will analyse human biopsies, generate primary cultures of human tumour cells, isolate the stem-cell-like population of patient-derived gliomas and generate mouse models for glioma based on the orthotopical inoculation of human glioma stem cells in the mouse brain to generate tumours with the same characteristics as the original human tumour. In addition, we will also study genetically modified mouse models and established cell lines. We expect that our results will help understand the biology of glioma and cancer, and we aspire to translate our discoveries to a more clinical ambit identifying molecular markers of diagnosis and prognosis, markers of response to therapies, and unveil new therapeutic targets against this deadly disease.
Summary
Glioma is the most common and aggressive tumour of the brain and its most malignant form, glioblastoma multiforme, is nowadays virtually not curable. Very little is known about glioma genesis and progression at the molecular level and not much progress has been achieved in the treatment of this disease during the last years. The understanding of the molecular mechanisms involved in the biology of glioma is essential for the development of successful and rational therapeutic strategies. Our project aims to: 1- Study the role of the TGF-beta, Shh, Notch, and Wnt signal transduction pathways in glioma. These pathways have been implicated in glioma but still not much is known about their specific mechanisms of action. 2- Study of a cell population within the tumour mass that has stem-cell-like characteristics, the glioma stem cells, and how the four mentioned pathways regulate their biology. 3- Study the role of a transcription factor, FoxG1, that has an important oncogenic role in some gliomas and that it is regulated by the four mentioned pathways interconnecting some of them. Our approach will be based on a tight collaboration with clinical researchers of our hospital and the study of patient-derived tumours. We will analyse human biopsies, generate primary cultures of human tumour cells, isolate the stem-cell-like population of patient-derived gliomas and generate mouse models for glioma based on the orthotopical inoculation of human glioma stem cells in the mouse brain to generate tumours with the same characteristics as the original human tumour. In addition, we will also study genetically modified mouse models and established cell lines. We expect that our results will help understand the biology of glioma and cancer, and we aspire to translate our discoveries to a more clinical ambit identifying molecular markers of diagnosis and prognosis, markers of response to therapies, and unveil new therapeutic targets against this deadly disease.
Max ERC Funding
1 566 000 €
Duration
Start date: 2008-08-01, End date: 2014-07-31
