Discovery of cell memory mechanism

AUG 22, 2013- The cells in our bodies can divide as often as once every 24 hours, creating a new, identical copy. DNA binding proteins called transcription factors are required for maintaining cell identity. They ensure that daughter cells have the same function as their mother cell, so that for example muscle cells can contract or pancreatic cells can produce insulin. However, each time a cell divides the specific binding pattern of the transcription factors is erased and has to be restored in both mother and daughter cells. Previously it was unknown how this process works, but now scientists at Karolinska Institute have discovered the importance of particular protein rings encircling the DNA and how these function as the cell's memory.

The DNA in human cells is translated into a multitude of proteins required for a cell to function. When, where and how proteins are expressed is determined by regulatory DNA sequences and a group of proteins, known as transcription factors, that bind to these DNA sequences. Each cell type can be distinguished based on its transcription factors, and a cell can in certain cases be directly converted from one type to another, simply by changing the expression of one or more transcription factors. It is critical that the pattern of transcription factor binding in the genome be maintained. During each cell division, the transcription factors are removed from DNA and must find their way back to the right spot after the cell has divided. Despite many years of intense research, no general mechanism has been discovered which would explain how this is achieved.

 Jussi Taipale, professor at Karolinska Institute and the University of Helsinki,is behind the discovery.

 The scientist found that a large protein complex called cohesin is positioned as a ring around the two DNA strands that are formed when a cell divides, marking virtually all the places on the DNA where transcription factors were bound. Cohesin encircles the DNA strand as a ring does around a piece of string, and the protein complexes that replicate DNA can pass through the ring without displacing it. Since the two new DNA strands are caught in the ring, only one cohesin is needed to mark the two, thereby helping the transcription factors to find their original binding region on both DNA strands.                                                                                                                                                                  

Transcription factors play a pivotal role in many illnesses, including cancer as well as many hereditary diseases. The discovery that virtually all regulatory DNA sequences bind to cohesin may also end up having more direct consequences for patients with cancer or hereditary diseases. Cohesin would function as an indicator of which DNA sequences might contain disease-causing mutations.