OBJECTIVES: Peptide nucleic acids (PNAs) are DNA mimics that have been demonstrated to be efficient antisense/antigene tools in cell-free systems. However, their potential as in vivo regulators of gene expression has been hampered by their poor uptake by living cells, and strategies need to be developed for their intracellular delivery. This study has aimed to demonstrate the possibility (i) of efficiently delivering a PNA, which targets mRNA of the catalytic component of human telomerase reverse transcriptase (hTERT), into DU145 prostate cancer cells through a combined approach based on conjugation of the PNA to Tat internalizing peptide (hTERT-PNA-Tat) and subsequent photochemical internalization, and (ii) to interfere with telomerase function. MATERIALS AND METHODS: Treated cells were analysed for telomerase activity, hTERT expression, growth rate, ability to undergo apoptosis and telomere status. RESULTS: After exposure to light, DU145 cells treated with hTERT-PNA-Tat and the photosensitiser TPPS2a showed dose-dependent inhibition of telomerase activity, which was accompanied by marked reduction of hTERT protein expression. A dose-dependent decline in DU145 cell population growth and induction of caspase-dependent apoptosis were also observed from 48 h after treatment. Such an antiproliferative effect was associated with the presence of telomeric dysfunction, as revealed by cytogenetic analysis, in the absence of telomere shrinkage, and with induction of DNA damage response as suggested by the increased expression of gamma-H2AX. CONCLUSIONS: Our results (i) indicate photochemical internalization as an efficient approach for intracellular delivery of chimaeric PNAs, and (ii) corroborate earlier evidence suggesting pro-survival and anti-apoptotic roles of hTERT, which are independent of its ability to maintain telomere length.
OBJECTIVES: Peptide nucleic acids (PNAs) are DNA mimics that have been demonstrated to be efficient antisense/antigene tools in cell-free systems. However, their potential as in vivo regulators of gene expression has been hampered by their poor uptake by living cells, and strategies need to be developed for their intracellular delivery. This study has aimed to demonstrate the possibility (i) of efficiently delivering a PNA, which targets mRNA of the catalytic component of humantelomerase reverse transcriptase (hTERT), into DU145 prostate cancer cells through a combined approach based on conjugation of the PNA to Tat internalizing peptide (hTERT-PNA-Tat) and subsequent photochemical internalization, and (ii) to interfere with telomerase function. MATERIALS AND METHODS: Treated cells were analysed for telomerase activity, hTERT expression, growth rate, ability to undergo apoptosis and telomere status. RESULTS: After exposure to light, DU145 cells treated with hTERT-PNA-Tat and the photosensitiser TPPS2a showed dose-dependent inhibition of telomerase activity, which was accompanied by marked reduction of hTERT protein expression. A dose-dependent decline in DU145 cell population growth and induction of caspase-dependent apoptosis were also observed from 48 h after treatment. Such an antiproliferative effect was associated with the presence of telomeric dysfunction, as revealed by cytogenetic analysis, in the absence of telomere shrinkage, and with induction of DNA damage response as suggested by the increased expression of gamma-H2AX. CONCLUSIONS: Our results (i) indicate photochemical internalization as an efficient approach for intracellular delivery of chimaeric PNAs, and (ii) corroborate earlier evidence suggesting pro-survival and anti-apoptotic roles of hTERT, which are independent of its ability to maintain telomere length.
Authors: Marco Folini; Cinzia Brambilla; Raffaella Villa; Paolo Gandellini; Sara Vignati; Francesco Paduano; Maria Grazia Daidone; Nadia Zaffaroni Journal: Eur J Cancer Date: 2005-01-20 Impact factor: 9.162
Authors: Girdhar G Sharma; Arun Gupta; Huichen Wang; Harry Scherthan; Sonu Dhar; Varsha Gandhi; George Iliakis; Jerry W Shay; Charles S H Young; Tej K Pandita Journal: Oncogene Date: 2003-01-09 Impact factor: 9.867
Authors: Alejandra Martinez de Pinillos Bayona; Josephine H Woodhams; Hayley Pye; Rifat A Hamoudi; Caroline M Moore; Alexander J MacRobert Journal: Cancer Lett Date: 2017-02-20 Impact factor: 8.679
Authors: R Bertorelle; M Briarava; E Rampazzo; L Biasini; M Agostini; I Maretto; S Lonardi; M L Friso; C Mescoli; V Zagonel; D Nitti; A De Rossi; S Pucciarelli Journal: Br J Cancer Date: 2013-01-15 Impact factor: 7.640