Cell Reports (Jun 2017)

Extensive Proliferation of Human Cancer Cells with Ever-Shorter Telomeres

  • Rebecca A. Dagg,
  • Hilda A. Pickett,
  • Axel A. Neumann,
  • Christine E. Napier,
  • Jeremy D. Henson,
  • Erdahl T. Teber,
  • Jonathan W. Arthur,
  • C. Patrick Reynolds,
  • Jayne Murray,
  • Michelle Haber,
  • Alexander P. Sobinoff,
  • Loretta M.S. Lau,
  • Roger R. Reddel

Journal volume & issue
Vol. 19, no. 12
pp. 2544 – 2556

Abstract

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Summary: Acquisition of replicative immortality is currently regarded as essential for malignant transformation. This is achieved by activating a telomere lengthening mechanism (TLM), either telomerase or alternative lengthening of telomeres, to counter normal telomere attrition. However, a substantial proportion of some cancer types, including glioblastomas, liposarcomas, retinoblastomas, and osteosarcomas, are reportedly TLM-negative. As serial samples of human tumors cannot usually be obtained to monitor telomere length changes, it has previously been impossible to determine whether tumors are truly TLM-deficient, there is a previously unrecognized TLM, or the assay results are false-negative. Here, we show that a subset of high-risk neuroblastomas (with ∼50% 5-year mortality) lacked significant TLM activity. Cancer cells derived from these highly aggressive tumors initially had long telomeres and proliferated for >200 population doublings with ever-shorter telomeres. This indicates that prevention of telomere shortening is not always required for oncogenesis, which has implications for inhibiting TLMs for cancer therapy. : Dagg et al. find that a subset of highly malignant neuroblastomas (survival ∼50% despite intensive treatment) lack an effective telomere length maintenance mechanism. Their cells undergo continuous telomere shortening throughout >200 population doublings, challenging the concept that activation of a mechanism to prevent telomere shortening is essential for oncogenesis. Keywords: telomeres, ever-shorter telomeres, telomerase, alternative lengthening of telomeres, neuroblastoma