MOV10 as a novel telomerase-associated protein

A novel telomerase-associated protein was isolated from porcine testis. The 115-kDa protein, purified with telomerase activity, was molecular cloned using human cDNA library, and identified as MOV10. The expression levels of both MOV10 mRNA and MOV10 protein in cancer cells were 2-3 times higher than that of the normal cells, and MOV10 mRNA was highly expressed in human testis and ovary. The anti-MOV10 antibody precipitated the telomerase activity from cancer cell extracts, and inhibited the telomerase activity in vitro. Sf9-expressed MOV10 protein bound to G-rich strand of both single- and double-stranded telomere-sequenced DNA, but not to single C-rich strand. ChIP assay showed the binding of MOV10 to telomere region in vivo. These data suggest that MOV10 is involved in the progression of telomerase-catalyzing reaction via the interaction of telomerase protein and telomere DNA.     

Telomerase Activity Is Sensitive to Subtle Perturbations of the TLC1 Pseudoknot 3′ Stem and Tertiary Structure

Pseudoknot formation in the core region of the telomerase RNA has been demonstrated to be important for telomerase activity in vertebrates, ciliates, and yeast. Characterization of the Saccharomyces cerevisiae telomerase RNA (TLC1) pseudoknot identified tertiary structural interactions that are also important for telomerase activity, as previously observed for the Kluyveromyces lactis and human telomerase RNA pseudoknots. In addition, the contributions of backbone ribose 2′-OH groups in the pseudoknot to telomerase catalysis were investigated previously, using 2′-OH (ribose) to 2′-H (deoxyribose) or 2′-O-methyl substitutions in the stem 2 helix, and it was proposed that one or more 2′-OH groups from the stem 2 sequences at or near the triple helix participate in telomerase catalysis. Based on these studies and investigations of the structural and thermodynamic properties of the TLC1 RNA pseudoknot region, we have examined the structural and thermodynamic perturbations of the 2′-O-methyl and 2′-H substituted pseudoknots, using UV-monitored thermal denaturation, native gel electrophoresis, and circular dichroism spectroscopy. Our results demonstrate the presence of A-form helical geometry perturbations in the backbone sugar substituted pseudoknots, show a correlation between thermodynamic stability and telomerase activity, and are consistent with the identification of the U809 ribose 2′-OH as a potential contributor to telomerase activity.     

端粒酶催化亚基基因在小鼠 胚胎发育早期的转录活性

用 RT-PCR 引物分别扩增成年昆明 (KM) 小鼠睾丸、脾脏、肾脏、肝脏和胸腺组织的总 RNA 发现,端粒酶催化亚基基因 tert 在这些组织中都有转录,目标产物正确组装到 PMD 18-T 载体后测序,结果与已知 cDNA 序列一致 . PMSG/hCG 超数排卵方法获得 KM 小鼠成熟卵母细胞和 CZB 溶液体外培养的胚胎 (KM ♀× KM ♂ ) ,用酸性 Tyrode's 溶液消化透明带后,采用巢式 RT-PCR ,同时分析 tert 基因和持家基因 hprt 的转录发现,对于单个样品来说 , 全部卵母细胞 (15 h-post hCG , 10/10) 都存在 hprt 转录本,其中,只有 40% (4/10) 还同时存在 tert 转录本 . 原核形成初期 (20 h-post hCG , 6/6) 和原核晚期 (30 h post-hCG , 8/8) 的受精卵,以及发育至 2-C 早期的胚胎 (35 h-post hCG , 7/7) 都不转录 tert 基因,只有 hprt mRNA 存在; 2-C 晚期 (50 h-post hCG) 时,两个基因同时转录 (4/8) 和一个基因单独转录 (4/8) 的胚胎各占 50% ;从 4-C 阶段 (65 h-post hCG , 4/4) 开始,包括 8-C 阶段 (75 h-post hCG , 4/4) ,桑椹胚阶段 (93 h-post hCG , 4/4) ,直至囊胚阶段 (118 h-post hCG , 4/4) ,所有的胚胎都同时转录 tert 和 hprt 基因,而且转录水平明显升高 . 以 20 枚胚胎量为模板进行 RT-PCR 发现,原核早期,原核晚期的胚胎中仍然没有 tert 基因转录,只有 hprt mRNA ,但是,在 2-C 早期胚胎中同时检测到了 hprt 和 tert 两种 mRNA. 结果表明,持家基因 hprt 在成熟卵母细胞受精前后,以及胚胎早期发育过程中均存在转录本 . 40% 卵母细胞中存在的 tert mRNA 在受精后很快降解,检测不到;胚胎基因组在 2-C 早期开始转录 tert mRNA ,转录水平逐渐上升 . 结果暗示,小鼠胚胎的基因组 DNA 在 2-C 早期开始启动,功能基因 tert 也在此时开始转录,可能与胚胎发育初期的染色体保护有关 .     

A second essential function of the Est1-binding arm of yeast telomerase RNA

The enzymatic ribonucleoprotein telomerase maintains telomeres in many eukaryotes, including humans, and plays a central role in aging and cancer. Saccharomyces cerevisiae telomerase RNA, TLC1, is a flexible scaffold that tethers telomerase holoenzyme protein subunits to the complex. Here we test the hypothesis that a lengthy conserved region of the Est1-binding TLC1 arm contributes more than simply Est1-binding function. We separated Est1 binding from potential other functions by tethering TLC1 to Est1 via a heterologous RNA-protein binding module. We find that Est1-tethering rescues in vivo function of telomerase RNA alleles missing nucleotides specifically required for Est1 binding, but not those missing the entire conserved region. Notably, however, telomerase function is restored for this condition by expressing the arm of TLC1 in trans. Mutational analysis shows that the Second Essential Est1-arm Domain (SEED) maps to an internal loop of the arm, which SHAPE chemical mapping and 3D modeling suggest could be regulated by conformational change. Finally, we find that the SEED has an essential, Est1-independent role in telomerase function after telomerase recruitment to the telomere. The SEED may be required for establishing telomere extendibility or promoting telomerase RNP holoenzyme activity.