BACKGROUND: Telomerase activation and an alternative lengthening of telomeres (ALT) mechanism are two telomere-lengthening cancer cell survival mechanisms elicited by both chemo- and/or radiotherapy. Telomere lengthening interferes with cell lethality and results in the immortalization of cancer cells. To counteract these mechanisms, we developed a drug delivery system (DDS) consisting of a polymeric implant that is inserted directly into tumors. The DDS releases, continuously and gradually, a cationic porphyrin (PdTMPyP4) for >30 days after a single application, and inhibits telomerase activation. METHODS: The PdTMPyP4 porphyrin is incorporated into a poly(co-glycolic lactic)acid (PLGA) polymer, solidified and cut into small rods. PdTMPyP4 release from the rods was measured spectrophotometrically over time. Uptake of Pd in the DNA of in L428 Hodgkins lymphoma cells was measured by ICP-MS, and telomerase activation by the TRAP assay. The rods were placed into the growth medium of cells whose growth rate was measured for 11 and 19 days. The cylinders were also inserted directly into KHJJ murine mammary tumors borne on the thighs of BALB/c mice and the tumor growth rate measured. RESULTS: In vitro, >10(9)Pd atoms were measured in the DNA of each L428 cell and telomerase activity was reduced by ~15% within 24 h. A one-time application of the rod in the cell medium induced a factor of >5 greater lethality compared to a blank rod or untreated controls. In vivo, a one-time insertion of the rod into tumors resulted in the retardation of the growth rate by factors of 3-5 compared to untreated controls. Systemic uptake after intratumoral insertion of the rod was negligible. CONCLUSION: The results suggest that the direct intratumoral insertion of a PdTMPyP4-containing polymeric rod would be of benefit as an adjuvant treatment for patients undergoing chemo- or radiotherapy. By preventing the lengthening of telomeres and therefore the unrestricted growth of cancer cells, our DDS will provide a significant therapeutic advantage to these treatments without affecting normal tissues.
BACKGROUND: Telomerase activation and an alternative lengthening of telomeres (ALT) mechanism are two telomere-lengthening cancer cell survival mechanisms elicited by both chemo- and/or radiotherapy. Telomere lengthening interferes with cell lethality and results in the immortalization of cancer cells. To counteract these mechanisms, we developed a drug delivery system (DDS) consisting of a polymeric implant that is inserted directly into tumors. The DDS releases, continuously and gradually, a cationic porphyrin (PdTMPyP4) for >30 days after a single application, and inhibits telomerase activation. METHODS: The PdTMPyP4 porphyrin is incorporated into a poly(co-glycolic lactic)acid (PLGA) polymer, solidified and cut into small rods. PdTMPyP4 release from the rods was measured spectrophotometrically over time. Uptake of Pd in the DNA of in L428 Hodgkins lymphoma cells was measured by ICP-MS, and telomerase activation by the TRAP assay. The rods were placed into the growth medium of cells whose growth rate was measured for 11 and 19 days. The cylinders were also inserted directly into KHJJ murine mammary tumors borne on the thighs of BALB/c mice and the tumor growth rate measured. RESULTS: In vitro, >10(9)Pd atoms were measured in the DNA of each L428 cell and telomerase activity was reduced by ~15% within 24 h. A one-time application of the rod in the cell medium induced a factor of >5 greater lethality compared to a blank rod or untreated controls. In vivo, a one-time insertion of the rod into tumors resulted in the retardation of the growth rate by factors of 3-5 compared to untreated controls. Systemic uptake after intratumoral insertion of the rod was negligible. CONCLUSION: The results suggest that the direct intratumoral insertion of a PdTMPyP4-containing polymeric rod would be of benefit as an adjuvant treatment for patients undergoing chemo- or radiotherapy. By preventing the lengthening of telomeres and therefore the unrestricted growth of cancer cells, our DDS will provide a significant therapeutic advantage to these treatments without affecting normal tissues.
Authors: Kerrie L McDonald; Julie McDonnell; Alessandra Muntoni; Jeremy D Henson; Monika E Hegi; Andreas von Deimling; Helen R Wheeler; Ray J Cook; Michael T Biggs; Nicholas S Little; Bruce G Robinson; Roger R Reddel; Janice A Royds Journal: J Neuropathol Exp Neurol Date: 2010-07 Impact factor: 3.685
Authors: Jian Hu; Soyoon Sarah Hwang; Marc Liesa; Boyi Gan; Ergun Sahin; Mariela Jaskelioff; Zhihu Ding; Haoqiang Ying; Adam T Boutin; Hailei Zhang; Shawn Johnson; Elena Ivanova; Maria Kost-Alimova; Alexei Protopopov; Yaoqi Alan Wang; Orian S Shirihai; Lynda Chin; Ronald A DePinho Journal: Cell Date: 2012-02-17 Impact factor: 41.582
Authors: R Lu; J Pal; L Buon; P Nanjappa; J Shi; M Fulciniti; Y-T Tai; L Guo; M Yu; S Gryaznov; N C Munshi; M A Shammas Journal: Oncogene Date: 2013-04-22 Impact factor: 9.867