Developmentally programmed healing of chromosomes by telomerase in Tetrahymena

Healing of a broken chromosome and in eukaryotes involves acquisition of a telomere. During macronuclear development in ciliated protozoans, germline chromosomes are fragmented into linear subchromosomes, whose ends are healed by de novo addition of telomeres. We showed previously that the ribonucleoprotein enzyme telomerase elongates preexisting telomeres by synthesizing one telomeric DNA strand, using a template sequence in the RNA moiety of the enzyme. By marking telomerase with a mutation in the telomerase RNA template, which causes synthesis of novel telomeric sequences, we now show that in the ciliate Tetrahymena, telomerase directly adds telomeric DNA onto nontelomeric sequences during developmentally controlled chromosome healing. Unexpectedly, one telomerase RNA template mutation converted telomerase from an enzyme that normally synthesizes precisely templated sequences to a less precise polymerase that sometimes synthesizes irregular telomeric repeats in vivo.     

Mutational analysis of the Tetrahymena telomerase RNA: identification of residues affecting telomerase activity in vitro.

Telomere-specific repeat sequences are essential for chromosome end stability. Telomerase maintains telomere length by adding sequences de novo onto chromosome ends. The template domain of the telomerase RNA component dictates synthesis of species-specific telomeric repeats and other regions of the RNA have been suggested to be important for enzyme structure and/or catalysis. Using enzyme reconstituted in vitro with RNAs containing deletions or substitutions we identified nucleotides in the RNA component that are important for telomerase activity. Although many changes to conserved features in the RNA secondary structure did not abolish enzyme activity, levels of activity were often greatly reduced, suggesting that regions other than the template play a role in telomerase function. The template boundary was only altered by changes in stem II that affected the conserved region upstream of the template, not by changes in other regions, such as stems I, III and IV, consistent with a role of the conserved region in defining the 5' boundary of the template. Surprisingly, telomerase RNAs with substitutions or deletion of residues potentially abolishing the conserved pseudoknot structure had wild-type levels of telomerase activity. This suggests that this base pairing interaction may not be required for telomerase activity per se but may be conserved as a regulatory site for the enzyme in vivo.     

以hTR模板区为靶点的抗肿瘤药物设计策略

端粒酶几乎在所有的人类癌细胞中均异常表达,它的持久活性对肿瘤的增殖是必需的。因此,抑制端粒酶活性代表了一种新的癌症治疗机制。端粒酶全酶复合物有多处可以做为抑制剂的靶点,包括hTR、hTERT、引物锚定位点等。本文对以端粒酶RNA模板区为靶点的抗肿瘤药物设计策略进行了综述,包括对该区域进行点突变、使用反义寡核苷酸封闭模板区、改变端粒酶RNA空间构象等,并探讨了目前抑制端粒酶活性研究中存在的一些问题。     

Repair of Chromosome Ends after Telomere Loss in Saccharomyces

Removal of a telomere from yeast chromosome VII in a strain having two copies of this chromosome often results in its loss. Here we show that there are three pathways that can stabilize this broken chromosome: homologous recombination, nonhomologous end joining, and de novo telomere addition. Both in a wild-type and a recombination deficient rad52 strain, most stabilization events were due to homologous recombination, whereas nonhomologous end joining was exceptionally rare. De novo telomere addition was relatively rare, stabilizing <0.1% of broken chromosomes. Telomere addition took place at a very limited number of sites on chromosome VII, most occurring close to a 35-base pair stretch of telomere-like DNA that is normally approximately 50 kb from the left telomere of chromosome VII. In the absence of the Pif1p DNA helicase, telomere addition events were much more frequent and were not concentrated near the 35-base pair tract of telomere-like DNA. We propose that internal tracts of telomere-like sequence recruit telomerase by binding its anchor site and that Pif1p inhibits telomerase by dissociating DNA primer-telomerase RNA interactions. These data also show that telomeric DNA is essential for the stable maintenance of linear chromosomes in yeast.     

Repair of DNA broken ends is similar in embryonic fibroblasts with and without telomerase

Telomeres cap the ends of chromosomes, preventing end-to-end fusions and subsequent chromosome instability. Here we used a telomerase knockout model to investigate whether telomerase participates in the processes of DNA break repair by de novo synthesis of telomere repeats at broken chromosome ends (chromosome healing). Chromosome healing giving rise to new detectable telomeric signals has not been observed in embryonic fibroblasts of telomerase-proficient mice exposed to ionizing radiation. Since the synthesis of telomeric sequences to broken DNA ends would make them refractory to rejoining events, the efficiency of rejoining of broken chromosomes in cell environments with and without telomerase has also been investigated. We conclude that the efficiency of rejoining broken chromosomes is not significantly different in the two cell environments. All together, our results indicate that there is no significant involvement of telomerase in the healing of broken DNA ends by synthesizing new telomeres in mouse embryo fibroblasts after exposure to ionizing radiation.