The blueprint of our life is the DNA that stores all the information needed to build cells and organisms. Because of the sheer amount of information, DNA molecules are exceedingly long. At the time when human cells divide, they contain 4 metres of DNA, packed into micrometre-sized chromosomes. We are addressing how so much DNA can be arranged in such a small space. DNA does not come alone, it is bound by proteins. One of the prominent proteins on mitotic DNA is the chromosomal 'cohesin' complex. These are ring-shaped proteins that bind to DNA by topological embrace. We think that cohesin can bind to more than one DNA, such that it can establish interactions between distant parts of the genome. It also establishes interactions between the two copies of the genome that are replicated during S-phase and holds them together as what we call 'sister chromatids' until the time for the segregation towards daughter cells during cell division.
Because of their fundamental contribution to DNA organisation within the cell nucleus and within chromosomes, cohesin impinges on almost all processes that happen on DNA. These include gene transcription, DNA repair, chromosome compaction and chromosome segregation. Also, because of this, mutations in cohesin or its regulators are responsible for a large range of human illnesses. These range from severe developmental disorders to tumourigensis.
Our aim is to provide molecular insight into the function of the cohesin complex, so that we understand how cells work with their genomes, both in health and disease.