UC San Diego Scientists Show
UC San Diego Scientists Show
|UC San Diego researchers have shown for the first time how a genome - the most essential part of the cell for storing and accessing genetic information - is organized in three-dimensional space. This 3D rendering is an immunoglobulin locus in B cells, showing the relative positions of various portions of immunoglobulin genes. The grey band indicates constant regions; blue defines proximal variable regions; and green are distal variable regions. The red band indicates the linker connecting the proximal variable and joining regions. Research was conducted by Cornelis Murre, professor of biology at UC San Diego; and Steve Cutchin, senior scientist for visualization services at (SDSC). The image was developed by Amit Chourasia of SDSC. Results are published in the April 18 issue of the journal Cell.
Credit: C. Murre, UC San Diego;
S. Cutchin, A. Chourasia SDSC/UC San Diego
Source: San Diego Supercomputer Center
UC San Diego
Researchers led by Cornelis Murre, a professor of biology at UC San Diego, and Steve Cutchin, senior scientist for visualization services at the San Diego Supercomputer Center (SDSC), used the gene encoding the immunoglobulin heavy chain locus — responsible for generating diverse kinds of antibodies — to demonstrate the structure of the genome.
The observations, the researchers say, permit an insight into the structure of the human genome, which until now has remained elusive.
Their results, “The 3-D Structure of the Immunoglobulin Heavy Chain Locus: Implications for Long-Range Genomic Interactions,” are published in the April 18 issue of the journal Cell.
Because the genome is the most essential part of the cell for storing and accessing genetic information, the complete DNA sequence of a wide variety of genomes has been revealed in studies performed in a large number of laboratories — “a tremendous success that has provided insight into mechanisms that underpin the development of a wide variety of diseases,” the authors say.
However, Murre said, “it has remained unclear as to how the genome is organized in three-dimensional space. This is an important issue since the regulation of gene expression is controlled by interactions of genomic elements that are separated by large genomic distances. Thus, our team wanted to determine how the genome is structured within the nucleus.”
The experiments described in the Cell paper, he said, provide a first glimpse into this question. “As a model system, we used the gene encoding for the immunoglobulin heavy chain locus, because it is responsible for generating the wide diversity of antibodies.”
Having measured the distances that separate the various parts of the gene, Murre said, the researchers, in collaboration with Cutchin at the SDSC, then used geometry to resolve the first structure of a genetic locus.
His work, said Cutchin, involved computational geometry, scientific visualization, computational methods and numerical methods.
“The resulting structure shows that the antibody gene is organized into ‘flower-like’ structures that are connected by linkers,” said Murre. “These flowers contain the various parts that ultimately generate the wide variety of antibodies. This is the first time that geometry has been used to determine the structure of a genetic locus. Ultimately, the same approach should be used to elucidate the structure of the entire human genome.”
Contributing equally to the work were Suchit Jhunjhunwala, Mandy M. Peak, and Menno C. van Zelm, all with the Division of Biological Sciences at UC San Diego; Roy Riblet of the Torrey Pines Institute for Molecular Studies; Jacques J.M. van Dongen and Frank G. Grosveld of Erasmus MC in Rotterdam, The Netherlands; and Tobias A. Knoch of Heidelberg University, Germany.
Funding for the research was provided by the National Institutes of Health.
Paul K. Mueller, 858-534-8564