UCL Cancer Institute


Chromosome Maintenance Research Group

Group Leader: Dr Kazunori Tomita


Why can cancer cells propagate indefinitely? A clue can be found at chromosome ends, the telomeres. Telomeres are indispensable for chromosome stability in propagating cells, and the length of the telomeres defines the number of times a cell can divide. Elucidating the homeostatic systems and functions of telomeres are therefore essential for understanding cancer cell immortality as well as cellular ageing.

Our Research

Our cells harbour all the information required for the construction of our body and life cycle. These data are ‘encoded’ by long linear DNA molecules, called chromosomes. The physical end-regions of the chromosome, called telomeres, play critical roles in the maintenance of chromosomes.

Stresses from both outside and inside cells can cause breaks in chromosomes, but these broken DNA sites are usually mended by DNA damage surveillance and repair systems. Although chromosome ends harbour a similar structure to the DNA ends at break sites, telomeres protect against these surveillance systems to avoid inappropriate repair, which if left un-checked, would cause end-to-end fusions of the chromosomes. Despite the essential function of telomeres in chromosome maintenance, chromosomes lose telomeric DNA progressively with each round of cell division. In order to protect the chromosomes, shortened telomeres elicit a checkpoint dependent arrest of cell propagation, resulting in cellular ageing (senescence). [Fig 1]


Figure 1. Model of telomere shortening and the checkpoint.
Telomeres (green bars) shorten progressively with cell divisions. Shortened telomeres are recognised by checkpoint machinery, and induce cellular senescence. However, if telomerase is expressed, telomeres are replenished, allowing further cell divisions.

Cancer cells escape this programmed cell scenesence by activating a protein called telomerase. Telomerase counteracts the DNA loss at short telomeres by replenishing telomeric DNA [Fig. 2]. Using this protein, cancer cells are able to maintain chromosome ends, and therefore continue dividing [Fig. 1]. However, cancer cells somehow maintain short telomeres compared to normal cells. Such short telomeres or unprogrammed telomere maintenance can lead to uneven chromosome segregation [Fig. 3], which causes malignant progression. We aim to understand how telomeres are maintained and how they act to guide chromosomes through cell divisions.


Figure 2. Model for telomerase interaction and activation.
Dynamic interactions of the telomeric protein complex (Pot1-Tpz1-Ccq1) with telomerase (Trt1-TER1-Est1).

  1. A telomere with marked Ccq1 becomes a target of the telomerase subunit Est1.
  2. Interaction of Est1 with Ccq1 releases Ccq1 and Est1 from the telomere and telomerase, respectively.
  3. Interaction of Tpz1 with telomerase and re-association of Ccq1 are required for telomere maintenance.


Figure 3. Telomeres and chromosome segregation.
A series of frames taken from films of live yeast undergoing chromosome segregation. Time progresses towards the right. Chromosomes are shown in cyan. Red dots (spindle pole body) represent the marker for chromosome segregation.
Chromosomes condense and migrate towards the poles in the control. In the ccq1 mutant cell, chromosomes stretch between the two poles, presumably caused by chromosome end-to-end fusions or entanglements [shown in arrow].

To address these issues, we primarily employ fission yeast as a model system. Fission yeast telomeres have a similar structure and function to human telomeres and are also maintained by telomerase. This model organism allows an intricate genetic approach to be used to unravel mechanisms at the molecular level. Studies from fission yeast will greatly contribute to the understanding of telomerase action in normal and cancer cells in humans. We hope this will lead to the development of advanced cancer treatments and techniques to aid with diagnosis. 

We are interested in the alterations in telomere components and structure that occur during the cell cycle or telomere erosion. This telomere plasticity may contribute to multiple functions of telomeres in various conditions. The following aims are currently being investigated. 

1. Molecular mechanisms underlying telomerase activation

To extend telomeric DNA, telomerase (Trt1-TER1-Est1) first needs to contact the telomere complex [Fig. 2]. This recruitment process itself dose not engage telomerase activity, rather it promotes an alternative interaction between the telomere proteins and telomerase. Ccq1 was found to be a telomerase recruiter that connects the main telomere protection proteins, Pot1 and Tpz1, with telomerase (Tomita & Cooper 2008). After recruitment, Tpz1 seems to interact directly with telomerase to control its activity (Armstrong et al. 2014). Reassembly of the Tpz1-Ccq1 complex with telomerase is crucial for telomere maintenance. We are investigating the molecular links between the telomeric proteins and telomerase components, and exploring how these connections are regulated.

2. Regulation of telomerase activity at telomeres and telomere length homeostasis

The extent of telomere lengthening is controlled via a number of processes including the expression level and assembly of telomerase, accessibility of telomerase to telomeres and telomerase processivity. Telomerase is not expressed in most mammalian somatic cells. However, mild expression of telomerase, as seen in some pluripotent stem cells, can delay telomere shortening. Reproductive germ cells and unicellular organisms highly express telomerase, enabling telomeres to be maintenaned at a certain length (telomere length homeostasis). Since many cancer cells cannot maintain long telomeres despite highly active telomerase, we predict that telomerase regulation at the telomere is altered in these cells. 

3. Telomere function and regulation in meiotic prophase

Telomeres function not only in maintaining intact chromosome ends but are also directly involved in meiotic progression. Organisms diversify and propagate their genetic information throughout successive generations through the process of meiosis. Understanding the process of meiosis is important, as meiotic defects are a major reason for miscarriage in humans. During early meiotic prophase, telomeres gather near the microtubule organizing-center (MTOC) to form the so-called ‘bouquet’ structure [Fig. 4]. Failure to form the chromosomal bouquet results in aberrant spindle pole formation and meiotic spindle defects in fission yeast (Tomita & Cooper 2007). The telomeric proteins accumulate modifications as meiotic prophase progresses (Amelina et al. 2015), and completion of meiotic recombination triggers termination of the bouquet stage [Fig. 5], which in turn promotes functional spindle formation in meiosis. Currently, we are investigating what telomeres monitor during meiotic prophase and how telomeres signal to the meiotic spindle. Intriguingly, some cancer cells can utilize meiotic telomeres to maintain chromosome ends. Thus, we aim to understand the structural and functional changes occurring at telomeres throughout meiotic progression, permitting a greater understanding of a central function of telomeres.


Figure 4. Chromosomal Bouquet.
All chromosome ends move to near the MTOC (red). The resulting chromosomal structure resembles a bunch of flowers. The bouquet has been observed in diverse organisms including yeast and human.


Figure 5. Telomere fireworks. Series of frames taken from films of live yeast undergoing chromosome segregation. Time progresses toward the right. Telomeres are shown in Green. Red dots represent the MTOC (spindle pole body).
Telomeres disperse in an orchestrated manner, followed by meiosis I entry in fission yeast. Note: Fission yeast skips pachytine stage, thus entering meiosis right after the recombination phase.

Selected publications

Telomere protein Rap1 is a charge resistant scaffolding protein in chromosomal bouquet formation.
Amelina H, Subramaniam S, Moiseeva V, Armstrong CA, Pearson SR and Tomita K. BMC biology, 2015 Jun 10; 13 (1), 37. doi:10.1186/s12915-015-0149-x

Telomeres and centromeres have interchangeable roles in promoting meiotic spindle formation.
Fennell A, Fernández-álvarez A, Tomita K and Cooper JP. Journal of Cell Biology, 2015 Feb 16; 208 (4): 415-428. doi:10.1083/jcb.201409058

Telomerase activation after recruitment in fission yeast.
Armstrong CA, Pearson SR, Amelina H, Moiseeva V and Tomita K. Current biology, 2014 Sep 8; 24(17): 2006–2011. doi:10.1016/j.cub.2014.07.035

Chemical genetic analyses of quantitative changes in Cdk1 activity during the human cell cycle.
Gravells P, Tomita K, Booth A, Poznansky J and Porter ACG. Human Molecular Genetics, 2013 Jul 15; 22(14): 2842-5. doi: 10.1093/hmg/ddt133

A single internal telomere tract ensures meiotic spindle formation.
Tomita K*†, Bez C†, Fennell A and Cooper JP*. EMBO Report, 2013 Jan 8; 14(3): 252-60. doi: 10.1038/embor.2012.218 *co-corresponding authors †equal contribution

Fission yeast Ccq1 is telomerase recruiter and local checkpoint controller.
Tomita K and Cooper JP. Genes & Development, 2008 Dec 15; 22(24): 3461–3474. doi: 10.1101/gad.

The telomere bouquet controls the meiotic spindle.
Tomita K and Cooper JP. Cell, 2007 Jul 13; 130(1): 113-26. doi:10.1016/j.cell.2007.05.024

Full list of publications