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Telomere Terminal Transferase and its Role in Cancer Brian R. Keppler February 27, 2003.

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Presentation on theme: "Telomere Terminal Transferase and its Role in Cancer Brian R. Keppler February 27, 2003."— Presentation transcript:

1 Telomere Terminal Transferase and its Role in Cancer Brian R. Keppler February 27, 2003

2 The Telomere  Found on the ends of eukaryotic chromosomes.  Characterized by a 3’-overhang of single-stranded DNA.  Forms a T-loop with the help of specialized proteins to protect itself from exonuclease activity.  Shortening of telomeres results in the loss of genetic information and ultimately cell death.

3 DNA Replication  Semi-conservative  Bi-directional  Occurs in the 5’ to 3’ direction only  Leading strand is synthesized continuously  Lagging strand is synthesized discontinuously - Can’t replicate to entirety - Gradually shortens Lodish, H. et al., Molecular Cell Biolgy, 4th Ed., Freeman Publishing, 2000, p.461.

4 Telomerase  A specialized form of reverse transcriptase that carries its own internal RNA template to direct DNA synthesis.  Elongates the lagging strand template from its 3’-OH end.  Adds short, repeated, guanosine-rich sequences to the ends of chromosomes. OrganismTelomeric DNA sequence RNA template sequence ______________________________________________ H. sapien 5’-T 2 AG 3 3’-UCCCAAUC T. thermophila 5’-T 2 G 4 3’-AACCCCAA O. bifaria 5’-T 4 G 4 3’-CCAAAACCCC A. thaliana 5’-T 3 AG 3 unidentified E. aediculatus 5’-T 4 G 4 3’-CCAAAACCCCAAAAC S. cerevisiae 5’-T 1-6 GTG 2-3 3’-CACACACCCACACCAC

5 Proposed “Rough” Model of Telomerase Alberts, B. et al., Molecular Biology of the Cell, 4th Ed., Garland Science, 2002, p. 264.

6 Mechanism of Telomerase Action Lodish, H. et al., Molecular Cell Biolgy, 4th Ed., Freeman Publishing, 2000, p.466.

7 Telomerase and Cancer  Telomerase is active in the germ line and in renewable cells (e.g. bone marrow).  Most human somatic cells lack telomerase activity. -Telomere shortening - Senescence - End-to-end chromosome fusion and cell death  Most tumors regain the ability to produce telomerase. - Cells become immortal  Telomerase is up-regulated in the vast majority of human cancers and serves to halt the progressive telomere shortening that ultimately blocks would-be cancer cells from achieving a full malignant phenotype. Artandi, SE et al., Proc Natl Acad Sci U S A 2002 May 28

8 How Do Cancer Cells Activate Telomerase Activity?  Some cancer cells with telomerase activity arise from mutant precursor cells that have avoided telomere shortening. - These cells have never encountered a telomeric limit to cell division.  Telomerase can be activated after a genetic catastrophe (e.g. p53 loss). - Loss of checkpoint controls, uncontrolled proliferation, accumulation of mutations, chromosomal instability...But, telomeres are also shortening with each successive generation of cells. - The cell up-regulates telomerase expression in order to regain stability and survive. Alberts, B. et al., Molecular Biology of the Cell, 4th Ed., Garland Science, 2002, p. 1348.

9 Targeting Telomerase as an Anticancer Drug Approach  Targeting the protein/RNA subunit  Mouse models  Specificity?

10 Alberts, B. et al., Molecular Biology of the Cell, 4th Ed., Garland Science, 2002, p. 264.

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