Nonradioactive detection of telomerase activity using the telomeric repeat amplification protocol

The telomeric repeat amplification protocol (TRAP) is a two-step process for analyzing telomerase activity in cell or tissue extracts. Recent modifications of this sensitive assay include elimination of radioactivity by using a fluorescently labeled primer instead of a radiolabeled primer. In addition, the TRAP assay has been modified for real-time, quantitative PCR analysis. Here, we describe cost-effective procedures for detection of telomerase activity using a fluorescent-based assay as well as by using real-time PCR. These modified TRAP assays can be accomplished within 4 h (from lysis of samples to analysis of telomerase products).     

Molecular basis of artifacts in the detection of telomerase activity and a modified primer for a more robust 'TRAP' assay.

Human somatic cells have essentially no telomerase activity. Telomerase is linked to tumor genesis and is a valuable marker for malignant growth. Extreme paucity of the enzyme neccessitated development of a PCR-based assay, 'telomeric repeat amplification protocol' (TRAP). Unfortunately, this method is not without difficulties.Amplification products are not related to the size of the amplified telomerase products. Furthermore, false positive results can occur, and careful control of reaction conditions is crucial. We analyzed in detail the molecular basis of artifacts. Based on these data, reverse PCR primer was changed and both problems in the TRAP assay were eliminated.     

The addition of a spin column step in the telomeric repeat application protocol removes telomerase inhibitors

Telomerase activity in cancer cells is commonly analyzed by a polymerase chain reaction (PCR)-based assay termed the telomeric repeat amplification protocol (TRAP). However, nonspecific inhibition of Taq polymerase during the PCR step is frequently observed in inhibitor analysis or drug screening. Thus, the removal of excess inhibitors prior to PCR is an essential step for the proper evaluation of telomerase inhibitory effects. Here, a size exclusion spin column was applied to remove small molecular weight inhibitors from the telomerase extension products. The spin column-added protocol, termed sTRAP, provides a more reliable estimation of the inhibitory effects of telomerase activity.     

Microarray TRAP--a high-throughput assay to quantitate telomerase activity

Telomeric repeat amplification protocol (TRAP)--a sensitive, PCR-based assay to detect telomerase activity was quintessential to the evaluation of telomerase role in telomere maintenance, cell proliferation, tumour development, and cell immortalization. The assay, however, suffers from many limitations. The most significant are: lack of telomerase activity quantification, changes of the enzyme activity product size and/or ratio, and complex post-amplification procedures which limit the assay throughput. Here we report the development of the microarray TRAP (MTRAP) assay which combines advantages of microarray technology with a modified TRAP assay. The MTRAP was designed and optimized on rice cell suspension telomerase extract to enable telomerase specific, reliable, and linear quantification in high throughput mode, with sensitivity comparable to those of radioisotope-based TRAP assays. The MTRAP has a built-in system guaranteeing the amplification of telomerase activity products unchanged in length and/or ratio and built-in control for false negatives. Thus, our MTRAP assay provides new reliable tool for experiments requiring massive quantitation of telomerase activity.     

Premature termination of telomeric extension-PCR for detection of telomerase activity

In this article, we report a simple, rapid, and efficient method to detect telomerase activity: the premature termination of telomeric extension-PCR (PTEP). Similar to the telomeric repeat amplification protocol (TRAP), this method is based on PCR amplification following the in vitro telomerase reaction, while the in vitro telomerase reaction here is prematurely, rather than randomly, terminated. Apart from this, the telomeric extension products are used as initial primers, instead of as templates, to trigger the amplification with a specially constructed plasmid DNA as the template that cannot be directly amplified with the telomerase primer. The end product is a specific 159-bp DNA fragment that reflects telomerase activity. Because its product can be clearly identified with routine agarose gel electrophoresis and ethidium bromide staining, PTEP allows even lesser-equipped laboratories to easily detect telomerase activity.     

Detection of telomerase activity utilizing energy transfer primers: comparison with gel- and ELISA-based detection

We have developed a closed-tube format telomeric repeat amplification protocol (TRAP) assay for direct quantification of telomerase activity within the PCR vessel. The assay utilizes energy transfer (ET) primers, which emit fluorescence only upon incorporation into PCR products. This novel ET primer system (Amplifluor primers) has major advantages over existing detection methods because it eliminates the need for post-PCR processing and thus reduces greatly the risk of carryover contamination and the time required for the sample analysis. The assay is as sensitive, specific and quantitative as the polyacrylamide gel-based or ELISA-based TRAP assay.     

水稻端粒酶活性定量分析研究

摘要：端粒酶活性直接与细胞的分生能力、生活力、生命力有着密不可分的关系, 因此对其活性测定有着重要意义。本文参照人类端粒酶体外检测的原理和方法,设计了特别的先导引物和反向引物,采用不同的退火温度将PCR循环分成两步进行,再结合DNA凝胶电泳成像定量分析系统,以模式植物水稻为研究对象,对端粒酶活性定量检测方法和反应条件进行了探索。结果显示,水稻端粒酶活性的最佳反应条件为：温度19℃,反应时间13分钟,总蛋白浓度0.28μg/μl,与人端粒酶最佳反应条件有明显差异,建立了一种有效测定植物端粒酶活性的定量检测方法。应用该方法对6个水稻品种的根、幼叶及幼穗三个不同组织器官的端粒酶活性进行了定量测定,结果显示幼穗最高,其次为幼叶,根最弱。说明植物端粒酶活性与细胞、组织的生活力有着密切关系。     

A quantitative method to measure telomerase activity by bioluminescence connected with telomeric repeat amplification protocol.

Telomerase is expected to be a new biomarker for cancer diagnosis. The telomeric repeat amplification protocol (TRAP) is a sensitive method to detect telomerase activity. However, TRAP and its modified protocols are not always suitable for measuring telomerase activity of a large number of clinical samples to diagnosis cancer because these methods generally require a time-consuming detection step such as gel electrophoresis. To improve the procedure for mass diagnosis, we applied bioluminescence to replace the detection step. Telomerase activity is measured by evaluating the amount of inorganic pyrophosphate generated in PCR amplification of telomerase elongation product, with use of the sensitive enzymatic luminometric inorganic pyrophosphate detection assay (ELIDA). TRAP connected with ELIDA (TRAP-ELIDA) can quantitatively detect telomerase activity within linearity from 2 to 1000 cell equivalents. The ELIDA signals accorded with results of TRAP-SYBR green staining, and the results of ELIDA were significantly correlated to those of TRAP connected with an enzyme-linked immunosorbent assay (TRAP-ELISA) (r(2) = 0.992, P < 0.001). TRAP-ELIDA is a simple and sensitive method to quantify telomerase activity without time-consuming gel electrophoresis. Because TRAP-ELIDA measures telomerase activity with a luminometer, it could be applied to a large number of clinical samples at the same time.     

SYBR Green real-time telomeric repeat amplification protocol for the rapid quantification of telomerase activity

The sensitive telomeric repeat amplification protocol (TRAP) permits telomerase detection in mammalian cell and tissue extracts with very low telomerase activity levels. Unfortunately, conventional TRAP assays require complex post-amplification procedures, such as polyacrylamide gel electrophoresis and densitometry, to measure telomerase products. Therefore, a real-time quantitative TRAP assay (RQ-TRAP) was optimized in the present study and evaluated in comparison with a commercially available quantitative TRAP kit and by monitoring telomerase activity in human hepatocyte cultures, human hepatoma cell lines and telomerase reconstitution experiments. The novel real-time telomerase detection method has many advantages. Other than sample extraction and real-time cycling, no additional time-consuming steps have to be performed for telomerase quantification; reliable and linear telomerase quantification is possible down to single-cell dilutions without the interference of primer-dimer artifacts, and the costs are less. Moreover, the precision is similar to other amplification-based telomerase quantification assays and the results are comparable to data obtained with two commercially available assays. The closed-tube system reduces the risk of carryover contamination and supports high throughput. In conclusion, RQ-TRAP provides a new tool for the rapid and reliable quantification of telomerase activity.     

An interference-free fluorescent assay of telomerase for the high-throughput analysis of inhibitors

We have developed a telomerase assay that can quickly and accurately rank the ability of molecules to inhibit telomerase activity. It is based on the method of Orlando and co-workers which utilizes PicoGreen to detect dsDNA formed during the polymerase chain reaction (PCR) amplification of telomerase products. PCR cycles were optimized to give as linear a signal as possible relative to telomerase products; 96-well streptavidin-coated PCR plates were used to isolate the preamplification telomerase products and to wash inhibitors away before the amplification step. The inhibitor removal step is critical to prevent false positives potentially caused by inhibition of Taq polymerase during amplification. Use of the streptavidin-coated PCR plate allows this step to be done much more rapidly than use of the liquid/liquid extraction adopted by others. We have demonstrated that this assay can correctly order the ability of four inhibitors to inhibit telomerase and reproduce within a factor of two the absolute IC(50) values determined by the more time-consuming direct assay. We have shown that the difference in IC(50) values determined in this assay versus the direct assay can be corrected for by using the standard curve appropriately. Using this method 96 compounds can be assessed in 3-5h.     

Detection of telomerase activity in Plasmodium falciparum using a nonradioactive method

A simple, quick and sensitive method was used to detect telomerase activity in Plasmodium falciparum. The telomeric repeat amplification protocol (TRAP assay) was modified using electrophoresis and staining with SYBR-green I to detect telomerase activity in a range of 10 to 10(7) parasites. This might be a useful way to ascertain telomerase activity in different types of nontumor cells.     

Synthesis and evaluation of cationic phthalocyanine derivatives as potential inhibitors of telomerase

A series of water-soluble cationic phthalocyanine derivatives (1-10) were designed and synthesized to develop novel and potent telomerase inhibitors. These phthalocyanine derivatives as inhibitors of telomerase were investigated via modified telomerase repeat amplification protocol (TRAP) assay. The TRAP assay indicates that these cationic compounds had strong telomerase inhibitory activity (IC(50)<1.65 microM). To determine whether the phthalocyanine derivatives binding to G-quadruplex enhance the block to DNA synthesis, primer extension reactions were carried out in the presence of phthalocyanines. The interaction of the G-quadruplex of telomerase DNA with these molecules was examined by CD melting and PCR stop assay. These cationic phthalocyanine derivatives can stabilize G-quadruplex, which is demonstrated by the increased T(m) values. All these results indicate that the phthalocyanine derivatives might be potential lead compounds for the development of new telomerase inhibitor.     

Real-time determination of telomerase activity in cell extracts using an optical biosensor

A biosensoric approach has been developed to determine the activity of telomerase in tumor cell lysates. An optical sensor, the grating coupler, was used to monitor the association and dissociation of unlabeled compounds on the sensor surface in real time, by virtue of an evanescent field. An oligonucleotide was immobilized on the surface of the optical biosensor and linked with two other oligonucleotides by complementary sequences in an overlapping manner. The 3'-end of the last one carried the sequence of the telomeric substrate (TS) primer used for elongation by telomerase in the telomeric repeat amplification protocol (TRAP) assay. This primer sequence was phosphorothioate (PS)-modified, which is known to strongly increase the affinity to the primer binding site of telomerase protein and consequently the velocity of the telomerase reaction. We show that the PS primer binds to the modified biosensor and is elongated effectively by the telomerase from HL-60 cell lysates. A synthesis rate of 1 nucleotide/min was determined. The inhibitory effect of peptide nucleic acid (PNA) was shown by using immobilized TS. The velocity of the telomerase reaction was slowed down and the signal intensity was below the signal-to-noise ratio. Most nucleic acid detection systems use amplification steps such as polymerase chain reaction (PCR) to increase the amount of the probe. Since telomerase is a polymerase itself amplification of DNA by PCR is not required. Furthermore, no purification steps were required since all measurements were performed with crude cell extract.     

Detection and distribution patterns of telomerase activity in insects.

Telomeres of most insects consist of pentanucleotide (TTAGG)n repeats, although the repeats are absent in Diptera and some other insect species, where the telomere regions are perhaps maintained without telomerase. To understand various and unusual telomere formation in insects, we have studied the characteristic features of a putative insect telomerase that has not been previously described. Using a modified telomeric repeat amplification protocol (TRAP), we first detected the telomerase activity in crickets, cockroaches and two Lepidopteran insects. The telomerase from crickets and cockroaches required dATP, dGTP and dTTP but not dCTP as a substrate and sequence analyses of the products of TRAP revealed that the (TTAGG)n repeats are synthesized by telomerase. The cockroach telomerase was detected both in somatic (fat body, muscle and neural tissues) and germ line (testis) cells, suggesting that expression of this enzyme is not regulated in a tissue-specific manner at an adult stage. While we detected high levels of telomerase activity in crickets and cockroaches, we could not detect activity in all tissues and cell cultures of the silkworm, Bombyx mori and in two Drosophila and one Sarcophaga cell lines. This supports the theory that Dipteran insects maintain their telomeres without telomerase.     

银染端粒重复序列检测端粒酶活性方法的研究

为了建立一种便于检测端粒酶活性的方法,在Kim等开发的TRAP法的基础上作了一些改进。即把细胞提取液与TS引物混合,30度保温30min以延伸TS引物之后经过酚／氯仿抽提,乙醇沉淀,再做PCR扩增,PCR产物经12％非变性聚丙烯酰胺凝胶电泳,用银染法来显示电泳结果,结果表明该方法可以有效去除抑制Taq酶活性的因素,得到清晰的6bp阳性条带,具有特异性好,灵敏度高,易操作,无放射性危害等优点。     

Advances in quantification and characterization of telomerase activity by the telomeric repeat amplification protocol (TRAP).

The telomeric repeat amplification protocol (TRAP) assay has been used to test telomerase activity in numerous cancer specimens. We describe primers, controls and quantification methods for the TRAP assay to accurately measure the level of telomerase activity in clinical samples. The assay is reliable and reproducible in routine analyses and can be used to estimate the processivity of telomerase activity.     

A homogeneous time-resolved fluorescence detection of telomerase activity

The homogeneous time-resolved fluorescence (HTRF) technology is an assay developed to study the interaction between biomolecules. This detection system is based on a fluorescence resonance energy transfer (FRET) between a Tris-bipyridine europium cryptate used as a long-lived fluorescent donor and a chemically modified allophycocyanine as acceptor. This technology is characterized by both a spectral selectivity and a temporal selectivity (due to the time-resolved mode), ensuring a highly specific signal. Here a europium-cryptate-labeled deoxyuridine triphosphate analogue (K-11-dUTP) was used to monitor the extension reaction on a biotinylated oligonucleotide used as substrate for telomerase in a telomeric repeat amplification protocol (TRAP). After the addition of an allophycocyanine-streptavidin conjugate, the extension products give rise to a FRET between the incorporated cryptate moieties and the allophycocyanine acceptor that then displays a specific long-lived emission. The TRAP-HTRF format was validated as a screening tool by using a 2,6-diaminoanthraquinone analogue, a known inhibitor of telomerase activity. The IC(50) measured was consistent with the reported values, showing the convenience of the HTRF technology for the study of telomerase activity and inhibitors.     

In vitro and in vivo inhibition of telomerase activity from Chinese hamster V79 cells

While studying the inhibition of telomerase activity in Chinese hamster V79 cells using polymerase chain reaction (PCR) based telomeric repeat amplification protocol (TRAP) assay, we had earlier observed that 7-deaza deoxy guanosine triphosphate (7-deaza dGTP) and oligonucleotide (TTAGGG)4 inhibited telomerase activity in vitro. In the present study, we report inhibition of telomerase activity by modified base 7-deaza deoxy adenosine triphosphate (7-deaza dATP) and phosphorothioate TTAGGG (PS-TTAGGG). Both the compounds inhibited telomerase activity in a concentration dependent manner; 8.5 microM of 7-deaza dATP and 0.1 microM of PS-TTAGGG being the concentration for 50% of the maximum inhibition. This observation supports our earlier hypothesis that incorporation of a modified nucleotide into telomere possibly interferes with the recognition of the telomerase and TTAGGG interferes with the RNA component of telomerase. We have further shown that treatment of cells with nicotinamide (NA) and benzamide (BA), well known inhibitors of poly (ADP-ribose) polymerase, reduced telomerase activity. We speculate that modification of the telomeric binding proteins or other components by poly (ADP-ribosyl)ation may be involved in such inhibition.