INSTITUT LADY DAVIS DE RECHERCHES MÉDICALES / LADY DAVIS INSTITUTE FOR MEDICAL RESEARCH Full colour Bilingual_Horizontal.jpg Logo-Horizontal-Red.tif Cancer and Aging: Two Faces of the Same Coin (3) Telomere Biology and Cancer-Part 1 Centre Bloomfield de recherche sur le vieillissement The Bloomfield Centre for Research in Aging What is Cancer? “Cancer is a group of diseases characterized by uncontrolled growth and spread of abnormal cells. If the spread is not controlled, it can result in death.” The American Cancer Society Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University How does Cancer Arise? - Through the accumulation of numerous genetic or epigenetic changes within a cell, which together, impart a growth advantage - Currently, two models of cancer formation are considered - 1) clonal evolution model 2) cancer stem cell hypothesis Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Clonal Evolution Model * * ** ** ** * ** ** * * Normal somatic cell within a tissue Over time, cell accumulates enough mutations to become cancerous Increased proliferation of tumor leads to the clonal expansion of cancer cells that harbor unique mutations – which confer unique phenotypes onto the cells that carry them. This accounts for the heterogeneity that is characteristic of many cancers. At some point, a certain population within the tumor could acquire the ability for self-renewal – these cells would be able to form a new tumor if transplanted into a new host. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Stem Cell Hypothesis for Cancer Accumulation of multiple mutations over time – Cancer Stem Cell/Tumor Initiating Cell (considered a small proportion of the tumor mass – these are the only cells capable of forming a new tumor or giving rise to metastases) * * * * Normal stem cell – gives rise to various cell types within a tissue: Capacity for Self-Renewal The majority of the tumor is composed of cancer cells that do not possess stem cell/tumor initiating cell properties. They may acquire additional mutations beyond those originally found in the CSC that gave rise to them. However, none of these cells can form a new tumor if transplanted into another host. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Phenotypic Characteristics of Cancer Cells Image Most cancers must acquire several “functions” in order to progress from their normal cellular origins to invasive carcinoma The molecular events (mutation, chromosome loss/gain, translocations) that underlie these functions can be different between different types of cancer The acquisition of these alterations within a “prospective” cancer cell are sequential and may account for the fact that many cancers arise later in life * Hanahan and Weinberg (2000). Cell 100(1), 57-70. Critical Role for Telomere Maintenance Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Emerging Hallmarks and Enabling Characteristics Hanahan and Weinberg (2011). Cell. 144, 646-674. Therapeutic targeting of the hallmarks of cancer Hanahan and Weinberg (2011). Cell. 144, 646-674. Critical Role of Telomere Maintenance How Does Telomere Maintenance Affect Replication Potential? * ~ 8 ~ 5 Cell Doublings ~ 1-3 0 0 ~30-70 ~70-90 Normal growth Cellular Aging Senescence check-point Crisis Immortalized Cell Cancer Modified from Harley (2008). Nat Rev Cancer 8: 167-179 Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University cellcycle E2F pRb Checkpoints Controlling Cell Growth DNA damage signal - critically short telomere Activate DNA damage response Kinase (ATM/ATR) Activate downstream substrates Eg. p53 Cell Cycle Control Transient Growth Arrest or Senescence p21 Apoptosis PUMA Bax Noxa FAS Elimination of cells that are beyond repair Cyclin/Cdk E2F pRb P P Cyclin D/ Cdk4/6 Cyclin A/ Cdk2 Cyclin A/B Cdc2 p15 p16 p18 p19 p21 p27 p57 Cdk Inhibitors Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University How Can Checkpoints be By-passed? cellcycle E2F pRb Cell Cycle Control p21 Cyclin/Cdk E2F pRb P P Cyclin D/ Cdk4/6 Cyclin A/ Cdk2 Cyclin A/B Cdc2 p15 p16 p18 p19 p21 p27 p57 p53 1) Loss of p53, pRb (tumor suppressor genes) X 2) Loss of Cdk inhibitors X 3) Overexpression of cyclin/Cdk complexes 4) Expression of Oncogenes (Ras, Myc) Apoptosis PUMA Bax Noxa FAS X X X Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Crisis ~ 8 ~ 5 Cell Doublings ~ 1-3 0 0 ~30-70 ~70-90 Crisis Acquisition of mutations that by-pass checkpoint Abnormal Growth Tumorigenesis Cells can continue to proliferate until their telomeres reach a critical length, at which time chromosomal instability can occur. The majority of cells undergoing crisis due to critically short telomeres will undergo apoptosis due to the fact that the chromosomal rearrangements are incompatible with cell viability. Cells must stabilize their telomeres in order to survive crisis. The period of genomic instability can promote the emergence of malignant cells due to the accumulation of mutations, gene amplifications, gene fusions or gene deletions Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University * ~ 8 ~ 5 Cell Doublings ~ 1-3 0 0 ~30-70 ~70-90 Crisis Immortalized Cell Cancer Activation of telomere maintenance strategies Telomere stability/Telomerase reactivation is a Key Characteristic of Cancer Cells Dying Cells Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com Strategies for Telomere Length Maintenance ALT Mechanism ALT- Alternative Lengthening of Telomeres Characterized by heterogeneous telomere lengths, presence of PML-bodies (regions in the nucleus that contain telomeric DNA, proteins involved in DNA repair and recombination.) Mechanism based on inter-chromosomal recombination Results in telomeres that are very different in length Cancers and cancer derived cell lines that display an ALT phenotype are typically derived from mesenchymal tissues Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Strategies for Telomere Length Maintenance Telomerase Activation telomerase Telomerase mediated Telomere Maintenance Activity of the Telomerase Complex – minimally composed of TERT (the telomerase reverse transcriptase) and the telomerase RNA template (TR, TER, TERC) Upon activation, extends telomeric repeats at chromosomal ends (telomere lengths are more homogeneous) Telomerase activation is typically observed in epithelial cancers – represents the most common cancer type in humans Approximately 80-90% of human cancers display activation of telomerase compared to the remaining 10-20% that display features of ALT Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Hahn 1999 Hahn et al., (1999). Nature Med 5, 1164-1170. Mutations in the reverse transcriptase domain – can function as a dominant-negative Inhibition of Telomerase (expression/function) in cancer cells using dominant-negative hTERT or inhibitors pharmacological inhibitors can induce telomere shortening in cancer cells Suggests that telomerase activity/telomere integrity is required for the transformed phenotype Is Telomerase Activity Required for Transformation? Evidence from Cell Based Models Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Is Telomerase Activity Sufficient for Transformation? Evidence from Cell Based Models Transformation of primary human epithelial cells can be accomplished by the introduction of hTERT, SV40 Large T/small t, and Ras hTERT expression alone is not sufficient for transformation Telomerase should not be considered an oncogene! Elenbaas et al., (2001). Genes Dev 15, 50-65. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Insights from Mouse Models Lacking Telomerase Function Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Fig 1 full size Telomerase Deficient-Mice (Late Generation) are Resistant to Carcinogen-Induced Skin Tumorigenesis These mice are in a wild-type genetic background – intact p53 Gonzalez-Suarez et al., (2000). Nature Genetics 26, 114-117. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 weeks 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 weeks Wild-type 10 20 30 40 50 60 70 80 90 100 110 120 130 140 10 20 30 40 50 60 70 80 90 100 110 120 130 140 G1 Terc -/- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 weeks 10 20 30 40 50 60 70 80 90 100 110 120 130 140 G5 Terc -/- Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Telomerase-Deficiency (Late Generation) in the Context of p53 loss Enhances Tumorigenesis 406641aa Majority of these tumors had lost the remaining p53 allele Majority Sarcomas, Lymphomas No adenocarcinomas Majority Sarcomas, Lymphomas Emergence of Adenocarcinomas (9%) Sarcomas, Lymphomas No adenocarcinomas Majority Adenocarcinomas (55%) Remaining Sarcomas, Lymphomas (45%) Artandi et al., (2000). Nature 406, 641-645. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University nrc2393-t1 Intact checkpoint: Loss of telomerase results in impaired tumorigenesis Defective checkpoint: Loss of telomerase results in enhanced tumorigenesis Deng et al., (2008). Nat Rev Cancer; 8(6):450-458. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Potential Telomerase Functions? Active Telomerase Complex Apoptosis Stimulate Cell Proliferation Promote Glucose Metabolism ? ? DNA Damage Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Telomerase Functions in Apoptosis Telomere Erosion Critically Short Telomere Activation of DNA Damage Checkpoints – p53 Cell Death However, numerous studies point to a role for hTERT in protecting cells from apoptosis that is independent of its catalytic activity and telomere maintenance… Cao et al., (2002). Oncogene 21:3130–3138. Dudognon et al., (2004). Oncogene 23:7469–7474. Rahman et al., (2005). Oncogene 24:1320–1327. Xi et al., (2006). Apoptosis 11:789–798. Del Bufalo et al., (2007). Cell Death Diff 12:1429–1438. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, or to obtain a text description, please contact npg@nature.com hTERT Induces Expression of Genes that Promote Cell Proliferation Smith et al., (2003). Nature Cell Biology 5, 474 - 479 (2003) - EGFR and bFGF where among the genes upregulated by hTERT expression – these receptor tyrosine kinases have established roles in promoting cell proliferation Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Millar, S.E. Nature 460, 44-45, 2009 Image Multiple Roles for Telomerase in Cancer Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Therapeutic Opportunities Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Why do Telomerase/Telomere Maintenance Represent Good Targets? Universal Target – estimated that 80-90% of all tumors are telomerase positive Critical Target – we have seen that Telomerase activity/Telomere maintenance is required for the transformed phenotype Specificity – most normal human somatic cells have absent or very low telomerase whereas cancer cells upregulate telomerase expression Cancer Stem Cells – could afford the ability to target telomerase positive cancer stem cells Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Telomerase and cancer therapeutics Harley C (2008). Nat Rev Cancer 8: 167-179 Intense Interest in Telomeres/Telomerase as a Clinical Target Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Telomerase RNA template antagonists: These agents serve as competitive inhibitors that prevent the RNA component from binding to telomeres (eg. GRN163L) in clinical trials for chronic lymphocytic leukemia (CLL), multiple myeloma, lung cancer Strategies for Targeting Telomerase Activity Telomerase RNA template antagonists Telomerase and cancer therapeutics Harley C (2008). Nat Rev Cancer 8: 167-179 Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Strategies for Targeting Telomerase Activity Immunotherapy i) Development of cytotoxic T cell (CTLs) responses against specific hTERT peptides expressed on the surface of cancer cells. Phase I/II trials underway to assess toxicity following immunization with hTERT - derived peptides Furthest developed: GV1001 – 16mer hTERT peptide (NSCLC, melanoma and pancreatic cancer trials) ii) Stimulation of dendritic cells ex vivo (transfecting these cells with hTERT mRNA) Dendritic cells process hTERT protein into multiple peptides – present multiple epitopes Re-introduce the primed antigen presenting cells into the patient facilitates CD8/CD4 T cell activation and anti-tumor immunity Furthest developed: GRNVAC1 (mixture of mature autologous dendritic cells) (renal cancer, advanced prostate cancer, AML) Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Strategies for Targeting Telomerase Activity Gene Therapy Unfortunately we are unable to provide accessible alternative text for this. If you require assistance to access this image, please contact help@nature.com or the author Shay and Keith. British Journal of Cancer (2008). 98: 677-683 Delivery of anti-sense RNA, siRNA, etc. against Telomerase Target Telomerase expression hTERT promoter drives the expression of a suicide gene (NTR-nitroreductase) Converts an inert drug into a cytotoxic drug hTERT promoter drives the expression of a gene that is essential for replication of an adenovirus (E1A and E1B) Eg. OBP-301 Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University List of ongoing human clinical trials using a variety of approaches to targeting telomerase Buseman, C.M. et al. 2012. Is telomerase a viable target in cancer? Mutation Research 730, 90-97. “Uncapping” reagents that disrupt the structure of telomere ends G-quadruplex reagents BRACO19 RHPS4 Telomestatin Advantages – do not require telomere erosion, no lag period Strategies for Targeting Telomeres “Telomere Uncapping” Figure 1 Kelland. Clin Cancer Res (2007). 13:4960-4963 Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Telomerase therapeutics for cancer: challenges and new directions Shay and Wright. Nat Rev Drug Discov. 2006 5(7):577-584. Anticipating outcomes of Telomerase inhibitors on Cancer Response Telomerase inhibition as a single agent may be ineffective – lag time allows cancer cells to adapt. Leads to recurrence. Chemotherapy – de-bulk majority of tumor cells – not effective against tumor stem cells? Leads to recurrence. Combination – Conventional chemotherapy kills majority of tumor cells. Telomerase inhibition can also target cancer stem cells? In this way, reduce recurrence. Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University Issues to Consider When Targeting Telomerase Function 1)Although most normal tissues are telomerase negative – certain cell types do express active telomerase (hematopoetic progenitor cells, stem cells, cells in tissues that are subject to high turnover (epidermis, mammary epithelium, colonic epithelium). Telomerase activity is low in these cells – and expression could be intermittent – thus, this may not be a large concern 2)Many telomerase therapies (used in isolation) will be associated with a significant lag while telomeres erode. Could be alleviated by using combination therapies. Strategies that result in telomere uncapping could be useful – does not require telomere erosion to occur. 3) Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University 3) The genotype of the tumor being treated – in the context of p53 positive tumors, inhibiting telomerase could be beneficial. However, in, p53-/- tumors – is there a danger in the induction of further genetic instability (could this lead to a more aggressively metastatic tumor than the one initially treated?) The observation that fewer genetic changes are observed going from DCIS to invasive cancer (breast) may argue against this concern 4) Drugs targeting telomerase may result in the evolution of cancer cells that are telomerase independent (drug resistance) through the upregulation of the ALT pathway However, some evidence exists that tumor cells using the ALT pathway are not as aggressive as telomerase positive cancer cells Issues to Consider When Targeting Telomerase Function Peter Siegel, ANAT541B Molecular and Cellular Biology of Aging, McGill University