Targeting Tankyrase 1 as a therapeutic strategy for BRCA-associated cancer.

The BRCA1 and BRCA2 proteins are involved in the maintenance of genome stability and germ-line loss-of-function mutations in either BRCA1 or BRCA2 strongly predispose carriers to cancers of the breast and other organs. It has been demonstrated previously that inhibiting elements of the cellular DNA maintenance pathways represents a novel therapeutic approach to treating tumors in these individuals. Here, we show that inhibition of the telomere-associated protein, Tankyrase 1, is also selectively lethal with BRCA deficiency. We also demonstrate that the selectivity caused by inhibition of Tankyrase 1 is associated with an exacerbation of the centrosome amplification phenotype associated with BRCA deficiency. We propose that inhibition of Tankyrase 1 could be therapeutically exploited in BRCA-associated cancers.

Mutated telomeres sensitize tumor cells to anticancer drugs independently of telomere shortening and mechanisms of telomere maintenance.

Telomerase is a ribonucleoprotein complex that maintains the stability of chromosome ends and regulates replicative potential. Telomerase is upregulated in over 85% of human tumors, but not in adjacent normal tissues and represents a promising target for anticancer therapy. Most telomerase-based therapies rely on the inhibition of telomerase activity and require extensive telomere shortening before inducing any antiproliferative effect. Disturbances of telomere structure rather than length may be more effective in inducing cell death. Telomerase RNA subunits (hTRs) with mutations in the template region reconstitute active holoenzymes that incorporate mutated telomeric sequences. Here, we analysed the feasibility of an anticancer approach based on the combination of telomere destabilization and conventional chemotherapeutic drugs. We show that a mutant template hTR dictates the synthesis of mutated telomeric repeats in telomerase-positive cancer cells, without significantly affecting their viability and proliferative ability. Nevertheless, the mutant hTR increased sensitivity to anticancer drugs in cells with different initial telomere lengths and mechanisms of telomere maintenance and without requiring overall telomere shortening. This report is the first to show that interfering with telomere structure maintenance in a telomerase-dependent manner may be used to increase the susceptibility of tumor cells to anticancer drugs and may lead to the development of a general therapy for the treatment of human cancers.

Telomere maintenance by telomerase and by recombination can coexist in human cells.

Immortal human cells maintain their telomeres by two independent mechanisms, a prevalent one dependent on de novo synthesis of telomeric DNA by telomerase, and a rarer one based on telomere recombination [alternative lengthening of telomeres (ALT)]. Studies with yeast have indicated that expression of telomerase inhibits telomere recombination. In the present study, we have investigated whether expression of telomerase in cells that use ALT would similarly reveal dominance of telomere elongation by telomerase over telomere recombination. Telomerase-negative WI38 VA13/2RA ALT cells were reconstituted for telomerase activity through ectopic expression of the enzyme subunits, hTERT and hTR, and the presence and function of telomerase and ALT were monitored during long term cell growth by enzymatic assays, detection of the ALT-associated PML bodies (APBs) and analysis of telomere dynamics. Our results indicate that telomerase activity and APBs persisted in the cells over at least 90 population doublings. The activity of both pathways on telomeres was determined by analysis of telomere length versus time by gel electrophoresis and in situ hybridization. ALT cells are characterized by very heterogeneous telomeres with a much longer average size than the telomeres of telomerase-positive cells. Telomere dynamics in our cells were compatible with both ALT and telomerase being biologically active since the long telomeres typical of ALT were maintained, while short telomeres, thought to be the preferential substrate of telomerase, were elongated. These findings, indicating that human cells may be capable of concomitantly utilizing both mechanisms of telomere maintenance without effects on their growth and viability, have implications for cancer therapy.

Expression of mutant telomerase in immortal telomerase-negative human cells results in cell cycle deregulation, nuclear and chromosomal abnormalities and rapid loss of viability.

We have reconstituted wild type or mutant telomerase activity in two human cell lines that lack constitutive expression of both core subunits of the enzyme and maintain telomeres by a telomerase-independent mechanism (ALT cells). Wild type telomerase RNA and four telomerase RNAs with single point mutations in their template domain were used to express enzymes specifying different telomeric DNA sequences. Expression of wild type telomerase for up to 32 days had no detectable effect on cell growth or viability. In contrast, cells expressing mutant telomerases had slower growth rate, abnormal cell cycle and reduced viability. Dramatically aberrant nuclei, typical of cells undergoing mitotic catastrophe, and large numbers of fused chromosomes were also characteristic of these populations. Notably, all phenotypes were apparent within the first few cell divisions after expression of the enzymes. Unlike wild type, mutant telomerase activity was progressively selected against with cell culturing, and this correlated with the disappearance of cells with aberrant phenotypes. Our results suggest that even very limited synthesis of mutated sequences can affect telomere structure in human cells, and that the toxicity of mutant telomerases is due to telomere malfunction.

p53 regulates myogenesis by triggering the differentiation activity of pRb.

The p53 oncosuppressor protein regulates cell cycle checkpoints and apoptosis, but increasing evidence also indicates its involvement in differentiation and development. We had previously demonstrated that in the presence of differentiation-promoting stimuli, p53-defective myoblasts exit from the cell cycle but do not differentiate into myocytes and myotubes. To identify the pathways through which p53 contributes to skeletal muscle differentiation, we have analyzed the expression of a series of genes regulated during myogenesis in parental and dominant-negative p53 (dnp53)-expressing C2C12 myoblasts. We found that in dnp53-expressing C2C12 cells, as well as in p53(-/-) primary myoblasts, pRb is hypophosphorylated and proliferation stops. However, these cells do not upregulate pRb and have reduced MyoD activity. The transduction of exogenous TP53 or Rb genes in p53-defective myoblasts rescues MyoD activity and differentiation potential. Additionally, in vivo studies on the Rb promoter demonstrate that p53 regulates the Rb gene expression at transcriptional level through a p53-binding site. Therefore, here we show that p53 regulates myoblast differentiation by means of pRb without affecting its cell cycle-related functions.

In vitro low propensity to form nucleosomes of four telomeric sequences.

The structural aspects of nucleosome assembly on telomeres are largely unknown. We analyzed by competitive reconstitution the affinities for the histone octamer of telomeric sequences from four different eukaryotic groups, Arabidopsis thaliana, mammals, Tetrahymena, and Saccharomyces cerevisiae. All telomeres reconstitute in nucleosomes with lower association constants than average nucleosomal DNA. DNase I digestion analysis suggests a multiple translational positioning and the lack of rotational positioning, probably due to telomeric repeats length (in most cases 6-8 bp), out of phase with the DNA helical repeat on the nucleosome (10.2 bp). These results could partly explain the lack of nucleosomes on lower eukaryote telomeres, and suggest a high in vivo mobility of telomeric nucleosomes.

Superstructural features of the upstream regulatory regions of two pea rbcS genes and nucleosomes positioning: theoretical prediction and experimental evaluation.

Nucleosome positioning on two 384 bp DNA fragments, obtained from the upstream regulatory region of two pea rbcS genes, relevant in photoregulated transcription, was predicted using our theoretical method, based on the evaluation of the sequence dependent DNA bending energy. The theoretical prediction was checked by experimental evaluation of nucleosome positions after in vitro reconstitution, by mapping Exonuclease III-resistant borders and by digesting monomeric sequences with various restriction enzymes. Both approaches satisfactorily confirmed the theoretical predictions, showing that the nucleotide sequence intrinsic bendability has a dominant role in nucleosome positioning.