New! Sign up for our free email newsletter.
Science News
from research organizations

Imaging the genome: Cataloguing fundamental processes of life

October 27, 2014
University of Cambridge
A new study has allowed researchers to peer into unexplored regions of the genome and understand for the first time the role played by more than 250 genes key to cell growth and development.

The team of researchers, led by Dr Rafael Carazo Salas from the Department of Genetics, combined high-resolution 3D confocal microscopy and computer-automated analysis of the images to survey the fission yeast genome with respect to three key cellular processes simultaneously: cell shape, microtubule organization and cell cycle progression. Microtubules are small, tube-like structures which help cells divide and give them their structure.

Of the 262 genes whose functions the team report in a study published today in the journal Developmental Cell, two-thirds are linked to these processes for the first time and a third are implicated in multiple processes.

"More than ten years since the publication of the human genome, the so-called 'Book of Life', we still have no direct evidence of the function played by half the genes across all species whose genomes have been sequenced," explains Dr Carazo Salas. "We have no 'catalogue' of genes involved in cellular processes and their functions, yet these processes are fundamental to life. Understanding them better could eventually open up new avenues of research for medicines which target these processes, such as chemotherapy drugs."

Using a multi-disciplinary strategy that took the team over four years to develop, the researchers were able to manipulate a single gene at a time in the fission yeast genome and see simultaneously how this affected the three cellular processes. Fission yeast is used as a model organism as it is a unicellular organism -- in other words, it consists of just one cell -- whereas most organisms are multicellular, yet many of its most fundamental genes carry out the same function in humans, for example in cell development.

The technique enabled the researchers not only to identify the functions of hundreds of genes across the genome, but also, for the first time, to systematically ask how the processes might be linked. For example, they found in the yeast -- and, importantly, validated in human cells -- a previously unknown link between control of microtubule stability and the machinery that repairs damage to DNA. Many conventional cancer therapies target microtubular stability or DNA damage, and whilst there is evidence in the scientific literature that drugs targeting both processes might interact, the reason why has been unclear.

"Both the technique and the data it produces are likely to be a very valuable resource to the scientific community in the future," adds Dr Carazo Salas. "It allows us to shine a light into the black box of the genome and learn exciting new information about the basic building blocks of life and the complex ways in which they interact."

Story Source:

Materials provided by University of Cambridge. The original story is licensed under a Creative Commons Licence. Note: Content may be edited for style and length.

Journal Reference:

  1. Veronika Graml, Xenia Studera, Jonathan L.D. Lawson, Anatole Chessel, Marco Geymonat, Miriam Bortfeld-Miller, Thomas Walter, Laura Wagstaff, Eugenia Piddini, Rafael E. Carazo-Salas. A Genomic Multiprocess Survey of Machineries that Control and Link Cell Shape, Microtubule Organization, and Cell-Cycle Progression. Developmental Cell, 2014; 31 (2): 227 DOI: 10.1016/j.devcel.2014.09.005

Cite This Page:

University of Cambridge. "Imaging the genome: Cataloguing fundamental processes of life." ScienceDaily. ScienceDaily, 27 October 2014. <>.
University of Cambridge. (2014, October 27). Imaging the genome: Cataloguing fundamental processes of life. ScienceDaily. Retrieved July 14, 2024 from
University of Cambridge. "Imaging the genome: Cataloguing fundamental processes of life." ScienceDaily. (accessed July 14, 2024).

Explore More

from ScienceDaily