Biochemical and molecular characterization of the Leishmania spp. telomerase reverse transcriptase component

Telomeres are protein-DNA complexes that protect linear chromosomes from degradation, providing genomic stability. The telomeric sequences are G-rich and contain a 3¿ single-stranded region that protrudes toward the chromosome end. In Leishmania, the telomeric DNA is composed by the conserved 5¿-TTAGGG-3¿ repeated sequence and it is replicated by telomerase. Telomerase is responsible for maintaining chromosome ends in most eucaryotes by adding new telomeric sequences to the G-rich strand. Besides replicating telomeres, the telomerase holoenzyme complex, composed by the reverse transcriptase component (TERT), the telomerase RNA (TER) and associated proteins, also works as part of the higher order complex that protects telomeric ends. Understanding the regulation of the telomeric maintainance mechanism may allow the discovery of potential targets to the development of new antileishmania drugs. Therefore, we identified, cloned and characterized the TERT gene in Leishmania spp.. A ClustalW multiple-sequence alignment demonstrated that the Leishmania telomerases show greater homology with each other than with the proteins of other kinetoplastids and eukaryotes. Characterization experiments indicated that the putative Leishmania TERT gene was probably located in single copy at the largest chromosomes. A single messenger RNA transcript was found in promastigotes. Phylogenetic analysis suggested that Leishmania telomerase might represent a liaison between the oldest and the newest branches of telomerases. Besides that, recombinant proteins were expressed in bacterial system, allowing production of anti-LaTERT polyclonal serum in rabbits. Western blotting and chromatin immunoprecipitation assays indicated that the anti-LaTERT serum was able to recognize a native protein in nuclear and total extracts of the parasite and that L. amazonensis telomerase interacts in vivo with the G-richtelomeric sequence. We have also purified the L. amazonensis telomerase activity in order to better understand its biochemical features. Protein extracts of L. amazonensis containing telomerase activity were purified using combined chromatographic columns. Enzyme activity was tested in each purification step using the ¿Two-tube TRAP¿ assay. The results showed that enzyme activity is found in fractions purified by ion exchange (DEAE), Heparin affinity and gel filtration chromatographic methods. The activity was greatly enriched after affinity purification using a G rich telomeric DNA oligonucleotide as the ligand. When a 2¿O-methyl oligoribonucleotide complementary to the putative L. amazonensis TER template was used as a ligand in the affinity purification, little or no enzyme activity was eluted from resin, suggesting that the interaction between L. amazonensis telomerase and this oligoribonucleotide is too strong that disables its dissociation under the gentle elution conditions necessary to maintain enzyme activity. In order to identify the telomerase holoenzyme components, procyclic forms of Trypanosoma brucei were used to construct the PTP-tagging system. ¿Primer extension¿ reactions were also done in order to isolate and sequence an RNA candidate for the telomerase RNA gene in T. brucei. In addition, we have cloned a L. amazonensis homologue of the human PinX1 protein, previously known as a hTERT-interacting factor and as a potent telomerase inhibitor (AU)