Project Details
Multidimensional interrogation of microvascular matrisome abnormalities in cerebral small vessel diseases
Applicant
Professor Dr. Martin Dichgans
Subject Area
Molecular and Cellular Neurology and Neuropathology
Term
since 2023
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 522469906
Brain weighs only 2% of the body weight but consumes almost one fourth of all body’s energy delivered into brain via blood vessels. In the case of a lack of blood supply into brain, its own energy reserve lasts only for couple of minutes and therefore a proper functioning of brain vessels is crucial for brain health. It is well known that defective functioning of small blood vessels in the brain causes stroke and dementia. In fact, one quarter of ischemic stroke, the vast majority of spontaneous intracerebral hemorrhage and about one third of dementia cases world-wide are caused by diseases affecting these small brain vessels, also called cerebral small vessel diseases (cSVDs). cSVD is an heterogeneous group of diseases and currently there is no understanding of what goes wrong and therefore these diseases lack an effective treatment. Cells that make up the vessel wall are embedded in a complex mesh of proteins called the matrisome. Altered levels of matrisome proteins can lead to small vessel lesions, the underpinning of cSVDs. Our hypothesis is that matrisome changes in small brain vessels take center stage in cSVDs. This project aims at addressing the 3 following questions: 1) What drive these matrisome changes in cSVDs? 2) How do changes in the levels/activity of HTRA1, a matrisome protein and key player in cSVDs, contribute to disease manifestations and death of contractile vascular cells and 3) conversely, can some matrisome modifications have a protective role, preventing the occurrence of disease manifestations? Altogether, the information obtained from our study can be used to get an inspiration for future studies to develop therapeutics – either directly to interfere or correct the disease pathway or to stimulate existing protective pathways.
DFG Programme
Research Grants
International Connection
France, Switzerland
Cooperation Partners
Anne Joutel, Ph.D.; Annika Keller, Ph.D.; Aniket Mishra, Ph.D.