Our proteome is much bigger than our genome because one gene produces several variants of proteins called protein isoforms, whose disbalance is implicated in many diseases. c
Helmholtz Zentrum München - German Research Center for Environmental Health
Proteins are the key players in our cellular processes. Their generation follows principles called transcription and translation. First, DNA copies its genetic information to messenger RNA (mRNA), which then determines the sequence in a chain of amino acids, which finally fold into a protein. The reality, however, is more complex: More than 90 per cent of our genes do not result in only one mRNA and then one protein, but a process called alternative splicing produces several mRNA variants, only some of which are then translated into a specific protein isoform in a specific cell at a given time. Conventional techniques to detect alternative splicing are mostly single time-point measurements that are work-intense and cannot reliably monitor over time which protein isoforms are actually translated in the cell.