Iain Cheeseman, PhD

Member, Whitehead Institute Assistant Professor of Biology, MIT 617.324.2503 phone icheese@wi.mit.edu

“Cell division is one of the most fundamental aspects of biology, the process that makes life,” says Whitehead Member Iain Cheeseman. “And it has an intrinsic beauty.”

Captivated by this process while a graduate student in biology, Cheeseman began focusing on the kinetochore, a key structure that helps to divvy up DNA molecules shortly before cells divide, ensuring that each daughter cell receives a proper set of chromosomes and the genetic material they contain.

Early during cell division, each chromosome is duplicated and split into two identical copies known as chromatids, which must be sorted and organized to ensure that new cells receive a single copy of each chromosome. Enter the kinetochore—a network of proteins that forms at a single site on each chromatid. The kinetochore physically connects the chromatids to an array of tiny proteins that make up the so called "mitotic spindle" and ensures that chromatids are positioned and split correctly as the spindle pulls them apart.

Working in yeast, the Caenorhabditis elegans worm and human cells, Cheeseman has helped to identify dozens of the kinetochore’s molecular components and their specific roles. He is also defining how the attachments between kinetochores and spindle microtubules are regulated throughout cell division. He is tackling these challenges in human cells with a broad array of biochemical and cell biological research techniques.

Because many cancers may be driven by errors in chromosome segregation, it is hoped that Cheeseman’s studies will provide payoffs in cancer research. Certain cancer drugs target the connection between chromosomes and spindle microtubules, and some of the major proteins in the kinetochore complex have been implicated in leukemia and other diseases.

Selected Publications

Welburn, J.P., and I.M. Cheeseman (2008). "Toward a Molecular Structure of the Eukaryotic Kinetochore". Dev Cell. Nov;15(5):645-55.

Hori, T., Amano, M., Suzuki, A., Backer, C.B., Welburn, J.P., Dong, Y., McEwen, B.F., Shang, W.H., Suzuki, E., Okawa, K., Cheeseman, I.M., and T. Fukagawa (2008). "CCAN Makes Multiple Contacts with Centromeric DNA to Provide Distinct Pathways to the Outer Kinetochore". Cell Dec 12;135(6):1039-52.

Cheeseman, I. M., J. S. Chappie, E. M. Wilson-Kubalek, and A. Desai (2006). “The Conserved KMN Network Constitutes the Core Microtubule Binding Site of the Kinetochore”. Cell 127 (5): 983:997.

Okada, M., I. M. Cheeseman, T. Hori, K. Ohkawa, I. X. McLeod, J. R. Yates, A. Desai, and T. Fukagawa (2006). “The CENP-H/I complex is required for the efficient incorporation of newly synthesized CENP-A into centromeres”. Nature Cell Biology 8 (5): 446-457.

Kline-Smith, S.*, I.M. Cheeseman*, T. Hori, T. Fukagawa, and A. Desai (2006). “The Human Mis12 Complex is Required for Kinetochore Assembly and Proper Chromosome Segregation”. Journal of Cell Biology 173 (1): 9-17. (*Joint first authors.)

Cheeseman, I. M. and A. Desai (2005). “A Combined Approach for the Localization and Tandem Affinity Purification of Protein Complexes from Metazoans”. Science SKTE 2005 (266): l1.

Cheeseman, I. M., S. Niessen, S. Anderson, F. Hyndman, J. R. Yates, K. Oegema, and A. Desai (2004). “A Conserved Protein Network Controls Assembly of the Outer Kinetochore and Its Ability to Sustain Tension.” Genes & Development 18 (18): 2255-2268.

Cheeseman, I. M., S. Anderson, M. Jwa, E. Green, J. Kang, J. R. Yates, C. S. M. Chan, D. G. Drubin, and G. Barnes (2002). “Phospho-regulation of Kinetochore-Microtubule Attachments by the Aurora Kinase Ipl1p.” Cell 111 (2): 163-172.

Cheeseman, I. M., C. Brew, M. Wolyniak, A. Desai, S. Anderson, N. Muster, J. R. Yates, T. C. Huffaker, D. G. Drubin, and G. Barnes (2001). “Implication of a Novel Multi-protein Dam1p Complex in Outer Kinetochore Function.” Journal of Cell Biology 155 (7): 1137-1145.

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