CARDIOSPLICE

CARDIOSPLICE - A systems and targeted approach to alternative splicing in the developing and diseased heart: Translating basic cell biology to improved cardiac function 

Activity Code: ERC-StG-LS4
Principal Investigator: Dr. Michael Gotthardt
Host institution: Max Delbrück Center for Molecular Medicine (MDC)

Description:

Cardiovascular disease keeps the top spot in mortality statistics in Europe with 2 million deaths annually and although prevention and therapy have continuously been improved, the prevalence of heart failure continues to rise. While contractile (systolic) dysfunction is readily accessible to pharmacological treatment, there is a lack of therapeutic options for reduced ventricular filling (diastolic dysfunction). The diastolic properties of the heart are largely determined by the giant sarcomeric protein titin, which is alternatively spliced to adjust the elastic properties of the cardiomyocyte. We have recently identified a titin splice factor that plays a parallel role in cardiac disease and postnatal development. It targets a subset of genes that concertedly affect biomechanics, electrical activity, and signal transduction and suggests alternative splicing as a novel therapeutic target in heart disease. Here we will build on the titin splice factor to identify regulatory principles and cofactors that adjust cardiac isoform expression. In a complementary approach we will investigate titin mRNA binding proteins to provide a comprehensive analysis of factors governing titins differential splicing in cardiac development, health, and disease. Based on its distinctive role in ventricular filling we will evaluate titin splicing as a therapeutic target in diastolic heart failure and use a titin based reporter assay to identify small molecules to interfere with titin isoform expression. Finally, we will evaluate the effects of altered alternative splicing on diastolic dysfunction in vivo utilizing the splice deficient mutant and our available animal models for diastolic dysfunction. 

The overall scientific goal of the proposed work is to investigate the regulation of cardiac alternative splicing in development and disease and to evaluate if splice directed therapy can be used to improve diastolic function and specifically the elastic properties of the heart.

Project details:

Start date: 01-01-2012 
End date: 31-12-2016 
Duration: 60 months 
Project Reference:  282078 
Project cost: 1499191 Euro 
Project Funding: 1499191 Euro

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Contact

    • Dr. Angela Richter
    • Delegate for the research area Earth and Environment
      Helmholtz Association