Parasite virulence genes are usually associated with telomeres. The clustering of the telomeres, together with their particular spatial distribution in the nucleus of human parasites such as Plasmodium falciparum and Trypanosoma brucei, has been suggested to play a role in facilitating ectopic recombination and in the emergence of new antigenic variants. Leishmania parasites, as well as other trypanosomes, have unusual gene expression characteristics, such as polycistronic and constitutive transcription of protein-coding genes. Leishmania subtelomeric regions are even more unique because unlike these regions in other trypanosomes they are devoid of virulence genes. Given these peculiarities of Leishmania, we sought to investigate how telomeres are organized in the nucleus of Leishmania major parasites at both the human and insect stages of their life cycle. We developed a new automated and precise method for identifying telomere position in the three-dimensional space of the nucleus, and we found that the telomeres are organized in clusters present in similar numbers in both the human and insect stages. While the number of clusters remained the same, their distribution differed between the two stages. The telomeric clusters were found more concentrated near the center of the nucleus in the human stage than in the insect stage suggesting reorganization during the parasite's differentiation process between the two hosts. These data provide the first 3D analysis of Leishmania telomere organization. The possible biological implications of these findings are discussed.
Citation: Dossin FdM, Dufour A, Dusch E, Siqueira-Neto JL, Moraes CB, Yang GS, et al. (2008) Automated Nuclear Analysis of Leishmania major Telomeric Clusters Reveals Changes in Their Organization during the Parasite's Life Cycle. PLoS ONE 3(6): e2313. doi:10.1371/journal.pone.0002313
Editor: Matthew Baylis, University of Liverpool, United Kingdom
Received: March 9, 2008; Accepted: April 20, 2008; Published: June 11, 2008
Copyright: © 2008 Dossin et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was funded by Institut Pasteur Korea.
Competing interests: The authors have declared that no competing interests exist.
The study of nuclear organization is essential to understanding the way genomes function. Spatial localization of a gene within the nucleus can modulate its expression, leading either to its activation or repression . Chromosomes were first shown to be organized and later shown to occupy particular territories in the nucleus; chromosome properties such as size and gene density were found to be important in the nuclear positioning of the chromosome. In fact, a correlation between transcriptional silencing and localization to the nuclear periphery has been suggested. Gene-rich chromosomes have been observed to occupy the interior of the nucleus, while gene-poor chromosomes have been seen to localize at the nuclear periphery (for review see  and ).
In yeast, the interaction between the chromosome and nuclear periphery can be mediated by telomeres . Telomeres are DNA-protein complexes at the physical ends of the chromosomes that function to protect chromosomal extremities against end-to-end fusions and degradation by nucleases. They are also important for the replication of chromosomal ends.
Telomeres show a conserved structure of G-rich tandemly repeated DNA sequences extending toward the chromosome extremities and ending in a 3′ overhang. The telomere repeat sequence 5′-TTAGGG-3′ is shared between phylogenetically unrelated organisms, such as vertebrates, and early diverging eukaryotes, such as the trypanosomatids .
Trypanosomatids are flagellated protozoa of medical importance as the causes of parasitic diseases such as leishmaniasis, Chagas' disease, and African trypanosomiasis. Of these three diseases, leishmaniasis is the most geographically widespread: it is present in over 80 countries and puts around 350 million people worldwide at risk of infection (WHO/TDR). There are over 20 Leishmania species pathogenic to humans, and no vaccines exist against any of them. The available treatments frequently show low efficacy and considerable toxicity.
Trypanosomes have peculiar biological features such as polycistronic transcription and trans-splicing. In the trans-splicing reaction, long polycistronic messages are processed by addition of a 30–40 nucleotides RNA derived from the spliced leader gene at the 5′ end of each cistron, followed by addition of a poly(A) tail at the 3′ end. Transcription is constitutive for almost all genes characterized to date and overall transcription rates vary according to the parasite developmental stages . Thus, most regulation of gene expression in trypanosomes seems to occur posttranscriptionally, either by modulation of the stability of the processed mRNAs or by translational control (reviewed in ).
The life cycle of the Leishmania parasite comprises two stages: amastigote, the intracellular stage found in mammalian cells (human stage); and promastigote, the extracellular stage found in the insect vector (insect stage). The most studied species, Leishmania major, has a 32-megabase genome and 8200 protein-coding genes distributed on 36 chromosomes .
Telomeres in Leishmania are known to be heterogeneous in structure  and unlike what is found in other pathogenic protozoa, Leishmania major subtelomeric regions do not contain genes coding for the surface molecules frequently associated with parasite virulence . Instead, L. major contains clusters of housekeeping genes extending up to 5 kb away from the telomeres .
The telomeric localization of virulence genes could provide increased opportunities to generate variability, as it is suspected of enhancing recombination creating new antigenic variants in Trypanosoma brucei and Plasmodium , , , . In this process, the nuclear architecture may play a role in increasing the emergence of new antigenic and adhesive variants, in the same way that has been suggested for P. falciparum. The telomeres of P. falciparum lie in clusters of 4–7 chromosome ends in the nuclear periphery, and this clustering is thought to enhance recombination of subtelomeric genes like those of the var gene family .
Little is known about nuclear organization in Leishmania parasites. Given that these parasites are devoid of antigenic variation and their subtelomeric regions do not harbor virulence genes as seen for other protozoan parasites, we wanted to know whether Leishmania telomeres are organized in clusters. In addition, given that transcription in these parasites is polycistronic and constitutive, we wanted to know the distribution of the Leishmania telomeres in the nucleus, since in other models telomeres are often seen at the nuclear periphery associated with transcriptional silencing. To answer these questions we investigated the spatial organization of Leishmania major telomeres in the insect stage, and we extended this analysis to the intracellular human stage. The small-sized nucleus and complex telomere hybridization patterns in this organism made it impossible to study telomere dynamics using available methods. In order to have more accurate measures and obtain robust statistics on telomere localization within the nucleus, we developed a fully automated 3D image processing system to extract nuclei and detect telomere.
In this paper we describe the telomere organization found in Leishmania parasites, we compare the organization/distribution found in nuclei in the human stage and the insect stage, and we discuss the possible implications of these findings for understanding the biology of the parasite.
Materials and Methods
Leishmania major MHOM/IL/81/Friedlin promastigotes (insect stage) were cultivated in M199 (Sigma) with 40 µM HEPES (pH 7.5), 20 µg/ml gentamicin, and 10% heat-inactivated fetal bovine serum at 28 °C.
Amastigote preparation (human stage)
Mouse macrophage cell line J774A.1 was maintained in RPMI 1640 with l-glutamine (300 mg/L), 25 mM HEPES (pH 7.5) (GIBCO), 100 units/ml penicillin, 100 µg/ml streptomycin, and 10% heat-inactivated fetal bovine serum at 37 °C and 5% CO2. Macrophages were infected with exponentially growing promastigotes diluted to 2×105 cells/ml and cultured 5 days prior to infection to allow them to reach stationary phase. The cells were then harvested and washed with RPMI 1640 medium before infection. In a 24-well plate, macrophages were added at 1×105 cells/ml and incubated for one day prior to infection. On the day of infection, cells were washed once with medium and infected at a ratio of 1:10 (host cell:parasite) for 48 h at 37 °C and 5% CO2. After this period, cells were washed 3 times with PBS and processed for telomere detection as follows.
Fluorescence in situ hybridization (FISH)
Leishmania major telomeres were detected by FISH using a telomere PNA probe (Telomere PNA FISH kit/FITC, DakoCytomation) according to the manufacturer's protocol except for the fixation step, which was performed with 3.7% formaldehyde (Sigma) for 15 minutes. In addition, the manufacturer's pre-treatment step was omitted.
To dissociate telomeric clusters, cells were treated with 0.05% proteinase K for 10 s prior to fixation , then submitted to FISH with the telomere PNA probe. Z-series images covering the whole nucleus were taken at distance intervals of 0.1 µm by exceeding the DAPI signal in a Nikon Eclipse 90i microscope using a 100×/1.4 Plan ApoVC lens and a Nikon DS-QiMc camera or a Zeiss LSM5 Line Scanning Confocal Microscope.
Automated Image analysis
A. Nuclei detection and segmentation.
First, all the parasites were automatically cropped from the 3D images by isolating each nucleus-kinetoplast pair. Then, a novel 3D analysis framework based on deformable models called “active meshes” was employed . For each parasite, a mesh was used to detect the boundary of the kinetoplast, while another mesh was simultaneously used to detect the boundary of the nucleus. The mesh representation allowed the measurement of distances relative to the nuclear membrane and a 3D visualization that was fast and accurate.
B. Telomere cluster localization.
Telomere clusters are small compared to the resolution limit of current optical microscopes. Therefore they appear on the images as the representation of the microscope's point spread function (PSF) . This phenomenon is taken into account during the detection process, which consists of two steps. First, the image voxels with high curvature values are extracted. Then, a Gaussian approximation of the PSF is fitted to each pre-localized cluster to refine its localization in real space coordinates . The intensity of each cluster is given by the estimated intensity value at cluster localization. For a proper comparison of the data from populations in the human or insect stages, the measured cluster intensities of each population were standardized by subtracting their respective population mean value, and dividing by their respective population standard deviation.
To compare the relationship between intensity and cluster position, a relative intensity value was calculated for each cluster. This relative intensity was calculated by dividing the cluster intensity value by the sum of all cluster intensity values from the same nucleus, thereby converting the intensity to a fraction of the whole cell intensity. This step made it possible to compare cluster intensities between different cells.
To study the spatial organization of the clusters in each population and across all nuclei, we computed a relative location of each cluster along the nuclear radius as shown in Figure 1.
Each cluster location T was projected on the detected membrane (mesh) using the vector formed by the center C of the nucleus and the cluster location T. This projected point E was then used to compute the ratio CT/CE, there normalizing all the relative cluster locations across all experiments to a ratio between 0 and 1.
Telomeres are clustered in Leishmania parasites
In FISH, hybridization of probe to target DNA is obtained through somewhat harsh fixation steps, high denaturation temperatures, and stringent washing conditions, sometimes leading to disruption of nuclear ultrastructure  . We hypothesized that by using lower hybridization temperatures, we could better conserve this ultrastructure. Compared to DNA probes, peptide nucleic acid (PNA) probes show improved hybridization characteristics: they hybridize efficiently at low ionic strength, and their hybridization is more specific and faster (30–45 min), allowing milder hybridization protocols and resulting in lower background. Furthermore, PNAs are resistant to both protease and nuclease degradation (reviewed by  and ).
Therefore, we decided to take advantage of PNA probes in order to study the 3D distribution of telomeres in Leishmania parasites. We performed FISH experiments in both L. major insect and human intracellular stages using a PNA probe complementary to the telomeric repeat of Leishmania parasites. As shown in Figure 2A, L. major telomeres were found in a speckled pattern, dispersed throughout the nucleus in both human and insect stages of the parasite.
(A) Cells were analyzed by FISH using a fluorescent telomere PNA probe as described in Methods. DNA was stained with DAPI. 2D maximum intensity projection of Z-series showing telomeric clusters found in nuclei in the human stage (left column) and insect stage (middle column). Nuclei in the insect stage were treated with Proteinase K (right column) prior to fixation to examine whether telomeres are found in clusters. (B) Table showing the quantification of telomeric FISH foci as shown in (A). Bar, 1 µm.
Telomeres cluster with one another to form discrete foci tethered to the nuclear periphery, and this peripheral localization can modulate gene expression (reviewed by ). In order to verify whether L. major telomeres are organized in clusters, we performed proteinase K digestion of nuclei prior to cell fixation . As expected, proteinase K treatment disrupted the overall nuclear structure. After this treatment, the number of telomere spots increased, indicating that telomeres were indeed associated in clusters, and that the clusters might have been disrupted by digestion.
The localization of telomeres was then assessed by automated image analysis of 3D series of L. major nuclei from insect and human stages. Determination of nuclear volume was carried out using the active mesh framework method (as described previously). One advantage of using this framework is that the Z-series are processed as a full volume, in contrast to methods in which each Z-slice is processed independently. Another advantage of our approach is that the meshes are permanently rendered during the detection process; thus there is no difference between what is seen on the screen and the model processing the data.
Interestingly, the observed average number of clusters in both stages is 16, suggesting that the number of clusters may be important for the parasite (Fig. 2B). Given that L. major has 36 chromosomes, an average of 4–5 chromosome ends are associated in each cluster. When we treated the cells with proteinase K before fixation, we obtained an average of 30 telomere spots per nuclei (Fig. 2B). These results provide evidence that L. major telomeres are in clusters brought together through protein interactions. Moreover, since L. major has 72 chromosome ends, our findings suggest that even after physical disruption of the clusters, telomeres may remain in close association. It is important to note that Leishmania chromosomes have never been observed in condensed states and thus the PNA-FISH system cannot be tested on L. major metaphase plates. Therefore, it is not possible to know precisely the resolution limit of this technique for detecting L. major telomeres. Nevertheless, it has been shown to detect more than 90% of telomeres in metaphase plates preparations from mammals , .
Differences in telomere cluster location unveiled through precise automated assignment of cluster nuclear position
After measuring the positions of hundreds of clusters in the nuclei of both L. major stages, we decided to analyze the distribution of the clusters. Nuclei from human and insect stages were identified based on DAPI signal and segmented as described in the Methods section. Each telomeric cluster was assigned a relative location along the nuclear radius. Even though telomere clusters are widespread throughout the nucleus during both stages, they concentrate in central areas more frequently than would be expected for random distribution, as shown in Figure 3. Moreover, the position of the telomere clusters differs between the two stages: clusters are more concentrated near the center of the nucleus in the human stage than in the insect stage. Another way of looking at these data is to divide the nucleus in two parts of identical volume, one being internal and the other external (Figures 4B and 4C, dotted vertical lines). This procedure reveals that ~85% of clusters in the human stage, but ~50% of clusters in the insect stage, are distributed in the internal half of the nuclear volume. Thus, transition to the human stage reduces the fraction of clusters in the external half of the nuclear volume to 15%, which means that the telomeres are repositioned to the center of the nucleus.
Comparison of the spatial distribution of telomeric clusters in nuclei in the human stage (gray bars, n = 952) and insect stage (black bars, n = 879) relative to the center of the nucleus (defined as position zero). The red lines show the values expected for random distribution. Below, the arrow illustrates the clusters distribution towards the nuclei.
(A) Standardized intensity comparison of telomeric clusters between human stage (gray bars) and insect stage (black bars). (B and C) Correlation between the cluster intensity (intensity percentage relative to each cell) and relative cluster position in nuclei at the human stage (B) and insect stage (C). The values in the abscissa represent the relative distance of the clusters in relation to the center of the nucleus, defined as position zero. The trend lines are adjusted to linear regressions, and the dotted lines define the radius used to divide the nucleus in two parts of identical volume, one being internal and the other external.
This suggests a spatial reorganization of L. major telomere clusters upon transition between stages of the parasite life cycle.
Analysis of telomeric cluster intensity suggests reorganization between human and insect stages
The observed spatial reorganization of telomeric clusters between insect and human stages prompted us to investigate whether the composition of clusters also changed between the two stages.
The intensity of a telomeric cluster depends on the number of telomeric repeats present on each cluster. The number of repeats, however, can be attributed to the number of repeats within a single chromosome extremity as well as to the number of extremities present in each cluster. To our knowledge, there is no evidence so far that the repeat number within the chromosomes changes between insect and human stages. We therefore assume that the intensity of telomeric clusters depends solely on the number of chromosomes associated in each telomeric cluster.
For proper comparison of the data from human and insect stages, the measured cluster intensities of each population were standardized by subtracting their respective population mean value, then dividing by their respective population standard deviation. Figure 4A shows a comparison of the standardized cluster intensity distribution between human and insect stages. Surprisingly, the overall pattern of clusters intensity changes from one stage to the other, suggesting that chromosomal distribution in telomeric clusters changes upon L. major cellular differentiation.
To further gain insights into telomere distribution among the clusters, we correlated the intensity of clusters to their nuclear position. In both insect and human stages, the most intense clusters tend to be centrally located (Figures 4B and 4C). At present it is not known whether this differential distribution is biologically relevant, and whether it is due to differences in the distribution of chromosomes according to telomere size, or to a different number of chromosomes per telomeric cluster.
In order to facilitate the visualization of spatial distribution of telomeres in Leishmania parasites, 3D models were produced for both the human and insect stages (Figure 5A and 5B, respectively, and supplemental movies S1 and S2).
Nucleus and kinetoplast are shown in blue and telomeric clusters in red. Differences in cluster intensity reflect differences in cluster size. The views are rotated clockwise with the angles indicated at the top of each panel. (A) Human stage nucleus. (B) Insect stage nucleus. Bar, 1 µm.
Here we have shown that Leishmania major telomeres are organized in clusters in both stages of the parasite life cycle. We have also observed that the number of clusters per cell does not change between the different life stages, suggesting that it may be important for parasite nuclear biology. Interestingly, the positioning of these clusters in the nucleus changes from one stage of the life cycle to the other. In the human stage, the clusters are more concentrated in the nucleus center, although in both stages clusters are found throughout the whole nuclear space. A comparison of cluster intensities shows that there is a reorganization of the nucleus when the parasites differentiate from one stage to the other, with cluster intensities being more homogeneous in the human stage. In both stages, however, we show that the clusters with the highest intensities are kept at more internal positions in the nucleus, while clusters of lower intensities localize towards the periphery.
The organization of Leishmania telomeres in clusters is comparable to the situation observed in other eukaryotic cells. In yeast, telomeres are clustered and tethered to the nuclear periphery. Association with the nuclear periphery correlates with gene silencing at the telomeres, where genes are closer to the pools of silencing proteins such as the Sir proteins. This transcriptional inhibition due to the telomeric localization of a gene is called the telomere position effect (TPE), and association of the telomeres with the periphery is thought to be necessary for TPE to occur (reviewed in ). For example, telomeric repression in trypanosomes has been demonstrated for genes encoding variant surface molecules (VSG) in T. brucei . However, the importance of the nuclear localization in this process remains unclear. It has been suggested that perinuclear localization facilitates transcriptional repression in the stage of the parasite that does not express the VSG genes and that in order to be expressed, the VSG gene moves away from the periphery towards the center of the nucleus ( and for review see ).
We have observed that Leishmania major telomere clusters are not concentrated at the nuclear periphery but instead are distributed throughout the nucleus. Unlike what is seen for Trypanosoma brucei, L. major subtelomeric regions do not contain genes coding for surface molecules  . The presence of housekeeping genes at the subtelomeric regions of Leishmania may explain the distribution of the telomeres throughout the nucleus.
Besides the lack of perinuclear localization of the telomeres, we have also observed that Leishmania major telomeres are reorganized in the nucleus during the life cycle. In T. cruzi, an extensive redistribution of the heterochromatic regions occurs during the life cycle and is associated with changes in the transcriptional status of the cell . We have shown that in both stages of the parasite life cycle the more intense clusters are found in central positions and clusters of lower intensity localize towards the periphery. The role of chromatin in this organization was not examined and therefore cannot be ruled out. It is possible that the decrease in cluster intensity reflects a difference in probe accessibility due to more compact heterochromatin in the periphery compared to more relaxed and accessible euchromatin in central regions. Whether the reorganization of Leishmania telomeres reflects a more extensive and general reorganization of the chromatin remains to be elucidated, as does the functional importance of the telomere reorganization itself.
Three-dimensional reconstruction of an L. major nucleus showing the spatial distribution of telomeric clusters in L. major human stage. Nucleus and kinetoplast are shown in blue and telomeric clusters in red. Differences in cluster intensity reflect differences in cluster size. This reconstruction was based in 3D images from a single parasite.
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Three-dimensional reconstruction of an L. major nucleus showing the spatial distribution of telomeric clusters in L. major insect stage. Nucleus and kinetoplast are shown in blue and telomeric clusters in red. Differences in cluster intensity reflect differences in cluster size. This reconstruction was based in 3D images from a single parasite.
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Conceived and designed the experiments: AG LF FD JS MC. Performed the experiments: FD AD ED CM GY. Analyzed the data: LF FD AD ED JS CM. Contributed reagents/materials/analysis tools: LF. Wrote the paper: LF FD AD JS CM.
- 1. Cabal GG, Genovesio A, Rodriguez-Navarro S, Zimmer C, Gadal O, et al. (2006) SAGA interacting factors confine sub-diffusion of transcribed genes to the nuclear envelope. Nature 441: 770–773.
- 2. Spector DL (2003) The dynamics of chromosome organization and gene regulation. Annu Rev Biochem 72: 573–608.
- 3. Pombo A, Branco MR (2007) Functional organisation of the genome during interphase. Curr Opin Genet Dev 17: 451–455.
- 4. Hediger F, Gasser SM (2002) Nuclear organization and silencing: putting things in their place. Nat Cell Biol 4: E53–55.
- 5. Blackburn EH (1990) Telomeres: structure and synthesis. J Biol Chem 265: 5919–5921.
- 6. Elias MC, Marques-Porto R, Freymuller E, Schenkman S (2001) Transcription rate modulation through the Trypanosoma cruzi life cycle occurs in parallel with changes in nuclear organisation. Mol Biochem Parasitol 112: 79–90.
- 7. Campbell DA, Thomas S, Sturm NR (2003) Transcription in kinetoplastid protozoa: why be normal? Microbes Infect 5: 1231–1240.
- 8. Ivens AC, Peacock CS, Worthey EA, Murphy L, Aggarwal G, et al. (2005) The genome of the kinetoplastid parasite, Leishmania major. Science 309: 436–442.
- 9. Conte FF, Cano MI (2005) Genomic organization of telomeric and subtelomeric sequences of Leishmania (Leishmania) amazonensis. Int J Parasitol 35: 1435–1443.
- 10. Peacock CS, Seeger K, Harris D, Murphy L, Ruiz JC, et al. (2007) Comparative genomic analysis of three Leishmania species that cause diverse human disease. Nat Genet 39: 839–847.
- 11. Corcoran LM, Thompson JK, Walliker D, Kemp DJ (1988) Homologous recombination within subtelomeric repeat sequences generates chromosome size polymorphisms in P. falciparum. Cell 53: 807–813.
- 12. Ravel C, Wincker P, Bastien P, Blaineau C, Pages M (1995) A polymorphic minisatellite sequence in the subtelomeric regions of chromosomes I and V in Leishmania infantum. Mol Biochem Parasitol 74: 31–41.
- 13. Taylor HM, Kyes SA, Newbold CI (2000) Var gene diversity in Plasmodium falciparum is generated by frequent recombination events. Mol Biochem Parasitol 110: 391–397.
- 14. Freitas-Junior LH, Bottius E, Pirrit LA, Deitsch KW, Scheidig C, et al. (2000) Frequent ectopic recombination of virulence factor genes in telomeric chromosome clusters of P. falciparum. Nature 407: 1018–1022.
- 15. Marty AJ, Thompson JK, Duffy MF, Voss TS, Cowman AF, et al. (2006) Evidence that Plasmodium falciparum chromosome end clusters are cross-linked by protein and are the sites of both virulence gene silencing and activation. Mol Microbiol 62: 72–83.
- 16. Dufour A, Lee LH, Vincent N, Grailhe R, Genovesio A (2007) 3D automated nuclar morphometric analysis using Active Meshes. Singapore: Springer. pp. 356–367.
- 17. Dusch E, Dorval T, Vincent N, Wachsmuth M, Genovesio A (2007) Three-dimensional point spread function model for line-scanning confocal microscope with high-aperture objective. J Microsc 228: 132–138.
- 18. Thompson RE, Larson DR, Webb WW (2002) Precise nanometer localization analysis for individual fluorescent probes. Biophys J 82: 2775–2783.
- 19. Kozubek S, Lukasova E, Amrichova J, Kozubek M, Liskova A, et al. (2000) Influence of cell fixation on chromatin topography. Anal Biochem 282: 29–38.
- 20. Solovei I, Cavallo A, Schermelleh L, Jaunin F, Scasselati C, et al. (2002) Spatial preservation of nuclear chromatin architecture during three-dimensional fluorescence in situ hybridization (3D-FISH). Exp Cell Res 276: 10–23.
- 21. Ray A, Norden B (2000) Peptide nucleic acid (PNA): its medical and biotechnical applications and promise for the future. Faseb J 14: 1041–1060.
- 22. Summerton J (2003) Morpholinos and PNAs compared. International Journal of Peptide Research and Therapeutics 10: 215–236.
- 23. Taddei A, Gasser SM (2004) Multiple pathways for telomere tethering: functional implications of subnuclear position for heterochromatin formation. Biochim Biophys Acta 1677: 120–128.
- 24. Lansdorp PM, Verwoerd NP, van de Rijke FM, Dragowska V, Little MT, et al. (1996) Heterogeneity in telomere length of human chromosomes. Hum Mol Genet 5: 685–691.
- 25. Chuang TC, Moshir S, Garini Y, Chuang AY, Young IT, et al. (2004) The three-dimensional organization of telomeres in the nucleus of mammalian cells. BMC Biol 2: 12.
- 26. Tham WH, Zakian VA (2002) Transcriptional silencing at Saccharomyces telomeres: implications for other organisms. Oncogene 21: 512–521.
- 27. Glover L, Horn D (2006) Repression of polymerase I-mediated gene expression at Trypanosoma brucei telomeres. EMBO Rep 7: 93–99.
- 28. Perez-Morga D, Amiguet-Vercher A, Vermijlen D, Pays E (2001) Organization of telomeres during the cell and life cycles of Trypanosoma brucei. J Eukaryot Microbiol 48: 221–226.
- 29. Navarro M, Penate X, Landeira D (2007) Nuclear architecture underlying gene expression in Trypanosoma brucei. Trends Microbiol 15: 263–270.