Telomerase is expressed in the neonatal brain, in distinct regions of adult brain, and was shown to protect developing neurons from apoptosis. Telomerase reactivation by gene manipulation reverses neurodegeneration in aged telomerase-deficient mice. Hence, we and others hypothesized that increasing telomerase expression by pharmaceutical compounds may protect brain cells from death caused by damaging agents. In this study, we demonstrate for the first time that the novel compound AGS-499 increases telomerase activity and expression in the mouse brain and spinal cord (SC). It exerts neuroprotective effects in NMDA-injected CD-1 mice, delays the onset and progression of the amyotrophic lateral sclerosis (ALS) disease in SOD1 transgenic mice, and, after the onset of ALS, it increases the survival of motor neurons in the SC by 60%. The survival of telomerase-expressing cells (i.e. motor neurons), but not telomerase-deficient cells, exposed to oxidative stress was increased by AGS-499 treatment, suggesting that the AGS-499 effects are telomerase-mediated. Therefore, a controlled and transient increase in telomerase expression and activity in the brain by AGS-499 may exert neuroprotective effects.
Human Bone Marrow Mesenchymal Stem cells (hMSC) are a promising candidate for cytotherapy. However, the therapeutic potential is limited since the therapy requires ex-vivo cell culturing in which deterioration in cellular viability and aging is observed with time.Telomerase ribonucleoprotein complex re-elongates telomeres and therefore promotes genomic integrity, proliferation and lifespan. Recently we showed that increasing telomerase reverse transcriptase (TERT) expression by novel compound confers resistance from apoptosis induced by oxidative stress. Here we investigated the possibility that a controlled induction of human TERT (hTERT) levels by chemical compounds (AGS-499 and AGS-500) might improve the functionality of hMSC derived from healthy and neurodegenerative diseased individuals. We demonstrate that AGS treatments of hMSC increased telomerase activity and hTERT levels in a time and dose dependent manner. Prolonged treatments with the compounds increased the average telomeres length, without altering population doublings (PD) or inducing chromosomal aberrations. AGS treatments of hMSC protected the cells from apoptosis and DNA damages induced by H2O2, and from the toxicity induced by long term exposure to DMSO. These AGS effects were shown to be mediated by telomerase since they were not observed when TERT was depleted from hMSC or in mouse embryonic stem cells derived from TERT knockout mice. Furthermore, AGS compounds did not alter the functionality of hMSC as examined by their ability to differentiate into various lineages in the presence of the compounds. These results suggest that pharmaceutical increase of telomerase may confer a beneficial therapeutic advantage in regenerative medicine when hMSC therapy is applied.
Telomerase promotes tissue regeneration by delaying the entrance of cells into senescence. Studies performed on cells or animals overexpressing telomerase reverse transcriptase (TERT), the catalytic subunit of telomerase, have revealed that TERT exhibits antiapoptotic effects in neurons. However, it is not clear whether endogenous TERT possesses these functions as well. Here we demonstrate the presence of active telomerase in the cytoplasm and nucleus of cerebellar Purkinje neurons of adult and old mice. TERT protein levels are reduced with age, whereas in the nucleus TERT activity is increased. These findings suggest that telomerase plays a role in the aging of nondividing cells.
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