Genome-wide screens identify specific drivers of mutant hTERT promoters

Cancer-specific hTERT promoter mutations reported in 19% of cancers result in enhanced telomerase activity. Understanding the distinctions between transcriptional regulation of wild-type (WT) and mutant (Mut) hTERT promoters may open up avenues for development of inhibitors which specially block hTERT expression in cancer cells. To comprehensively identify physiological regulators of WT- or Mut-hTERT promoters, we generated several isogenic reporter cells driven by endogenous hTERT loci. Genome-wide CRISPR-Cas9 and small interfering RNA screens using these isogenic reporter lines identified specific regulators of Mut-hTERT promoters. We validate and characterize one of these hits, namely, MED12, a kinase subunit of mediator complex. We demonstrate that MED12 specifically drives expression of hTERT from the Mut-hTERT promoter by mediating long-range chromatin interaction between the proximal Mut-hTERT promoter and T-INT1 distal regulatory region 260 kb upstream. Several hits identified in our screens could serve as potential therapeutic targets, inhibition of which may specifically block Mut-hTERT promoter driven telomerase reactivation in cancers.

Telomere elongation in the gut extends zebrafish lifespan

Telomere shortening is a hallmark of aging and is counteracted by telomerase. The gut is one of the earliest organs to exhibit short telomeres and tissue dysfunction during normal zebrafish aging. This is recapitulated in prematurely aged telomerase mutants (tert-/-). Here, we show that gut-specific telomerase activity in tert-/- zebrafish prevents premature aging. Induction of telomerase rescues gut senescence and low cell proliferation to wild-type levels, while restoring gut tissue integrity, inflammation, and age-dependent gut microbiota dysbiosis. Remarkably, averting gut dysfunction results in a systemic beneficial impact. Gut-specific telomerase activity rescues premature aging markers in remote organs, such as the reproductive (testes) and hematopoietic (kidney marrow) systems. Functionally, it also rescues age-dependent loss of male fertility and testes atrophy. Finally, we show that gut-specific telomerase activity increases the lifespan of telomerase mutants. Our work demonstrates that delaying telomere shortening in the gut is sufficient to systemically counteract aging in zebrafish.

In Silico Design, Synthesis, and Biological Evaluation of Anticancer Arylsulfonamide Endowed with Anti-Telomerase Activity

Telomerase, a reverse transcriptase enzyme involved in DNA synthesis, has a tangible role in tumor progression. Several studies have evidenced telomerase as a promising target for developing cancer therapeutics. The main reason is due to the overexpression of telomerase in cancer cells (85–90%) compared with normal cells where it is almost unexpressed. In this paper, we used a structure-based approach to design potential inhibitors of the telomerase active site. The MYSHAPE (Molecular dYnamics SHared PharmacophorE) approach and docking were used to screen an in-house library of 126 arylsulfonamide derivatives. Promising compounds were synthesized using classical and green methods. Compound 2C revealed an interesting IC50 (33 ± 4 µM) against the K-562 cell line compared with the known telomerase inhibitor BIBR1532 IC50 (208 ± 11 µM) with an SI ~10 compared to the BALB/3-T3 cell line. A 100 ns MD simulation of 2C in the telomerase active site evidenced Phe494 as the key residue as well as in BIBR1532. Each moiety of compound 2C was involved in key interactions with some residues of the active site: Arg557, Ile550, and Gly553. Compound 2C, as an arylsulfonamide derivative, is an interesting hit compound that deserves further investigation in terms of optimization of its structure to obtain more active telomerase inhibitors

Telomerase as a possible key to bypass the cost of reproduction effect

Telomerase activity and telomere restoration in certain somatic cells of human adults maintain the proliferative capacity of these cells and contribute to their regenerative potential, and telomerase activity and telomere length are commonly considered lifespan predictors. Eusocial insects provide excellent model systems for aging research based on their extraordinary caste-related lifespan differences that contradict the typical fecundity/lifespan trade-off. In agreement with the common presumption, telomerase activity is upregulated in the reproductive, long-lived individuals of eusocial insects such as queens and kings, proposing that telomerase activity acts as a key factor in their extended longevity. But, as documented by the presence of telomerase in somatic tissues of numerous invertebrate and vertebrate species, the connection between telomerase activity and the predicted lifespan is not clear. Here, I ask whether somatic telomerase activity in eusocial reproductives may serve its non-canonical function to protect its individuals against the exacerbated metabolic stress upon reproduction and be a reflection of a more common phenomenon among species. I propose a hypothesis that the presence of telomerase activity in somatic cells reflects a different reproduction strategy of the species.

The Use of Ruthenium Complexes as Molecular Probes for Non-Canonical DNA

This study considered the preparation of a new DNA binding Ruthenium polypyridyl complex possessing an infrared active nitrile group. The binding abilities of a novel Ruthenium complex, [Ru(TMP)2DPPZ-10-CN], to various forms of DNA—both canonical and non-canonical—were examined by performing multiple DNA titrations. DNA is of great interest as it is the carrier of genetic information for all living things. Damage to DNA can have drastically detrimental effects, so the study of its structure and replication is of great importance. Two non-canonical structures that are important are the G-quadruplex and i-motif which form at the telomeric and regulatory regions of genes, respectively, and have the ability to block telomerase activity and influence transcription. The complex was synthesized by microwave irradiation and purified using a silica column and an ion exchange with Amberlite 402. Six titrations were, then, performed with salmon sperm dsDNA, guanine monophosphate (GMP), G4T4G4, human telomere G-quadruplex, i-motif C5T3, and i-motif C30. The complex was found to favor non-canonical structures, particularly the G-quadruplex structure, because of its high [bp]/[Ru] concentrations. The higher concentration of base pairs or structures per Ruthenium molecule indicated that the complex had a high binding affinity for that particular DNA structure. These results support the notion that Ruthenium metal complexes can be used for theragnostic purposes and can be used to target the telomeric region of genes where G-quadruplex structures can be found and influence transcription initiation and inhibit telomerase activity.

The Use of Ruthenium Complexes as Molecular Probes for Non-Canonical DNA” by Eleni Sullivan

This study considered the preparation of a new DNA binding Ruthenium polypyridyl complex possessing an infrared active nitrile group. The binding abilities of a novel Ruthenium complex, [Ru(TMP)2DPPZ-10-CN], to various forms of DNA—both canonical and non-canonical—were examined by performing multiple DNA titrations. DNA is of great interest as it is the carrier of genetic information for all living things. Damage to DNA can have drastically detrimental effects, so the study of its structure and replication is of great importance. Two non-canonical structures that are important are the G-quadruplex and i-motif which form at the telomeric and regulatory regions of genes, respectively, and have the ability to block telomerase activity and influence transcription. The complex was synthesized by microwave irradiation and purified using a silica column and an ion exchange with Amberlite 402. Six titrations were, then, performed with salmon sperm dsDNA, guanine monophosphate (GMP), G4T4G4, human telomere G-quadruplex, i-motif C5T3, and i-motif C30. The complex was found to favor non-canonical structures, particularly the G-quadruplex structure, because of its high [bp]/[Ru] concentrations. The higher concentration of base pairs or structures per Ruthenium molecule indicated that the complex had a high binding affinity for that particular DNA structure. These results support the notion that Ruthenium metal complexes can be used for theragnostic purposes and can be used to target the telomeric region of genes where G-quadruplex structures can be found and influence transcription initiation and inhibit telomerase activity.